http://makerspace.tulane.edu/api.php?action=feedcontributions&feedformat=atom&user=Cschobermakerspace.tulane.edu - User contributions [en]2026-05-03T11:41:29ZUser contributionsMediaWiki 1.41.0http://makerspace.tulane.edu/index.php?title=Tormach_CNC_Milling_Machine&diff=197453Tormach CNC Milling Machine2018-03-24T03:06:11Z<p>Cschober: </p>
<hr />
<div>{| class="wikitable" style="text-align:center"<br />
|-<br />
! '''Required [[Badge]]''' !! '''Required [[PPE]]'''<br />
|-<br />
| [[File: CNC.png|100px]] || [[File: Safety_Eye.png|100px]] || [[File: Safety_Pants.png|100px]] || [[File: Safety_Hair.png|100px]] || [[File: Safety_Shoes.png|100px]] || [[File: Safety_Jewelry.png|100px]]<br />
|-<br />
|}<br />
<br />
Job Hazard Analysis (JHA) documents, Personal Protective Equipment (PPE) information, and Operator's Manuals can be found in the [[Safety and Manuals]] section.<br />
<br />
This machine is covered under the '''CNC''' training. Users who have not completed this training cannot use this machine.<br />
<br />
CNC:<br />
#When facing with a superfly on aluminum, use 1500 RPM, 9% velocity slider (~10 ipm)<br />
#When performing cuts on a thin sheet of aluminum, stabilize it on either side with 1-2-3 blocks. Also, to reduce chatter, face with an 1/2" endmill using 1500 RPM and 9% velocity slider (~10 ipm)<br />
#When cutting a thin plate of aluminum stock, tools like the 1/2" and the shear hog will induce too much pressure and cause chatter. This can be prevented by performing your adaptive and contour operations with a small bit such as a 3/16".<br />
#Always reference Z first<br />
#Max grip on the vise is 5.3"<br />
#If the safety enclosure is not properly closed, the spindle velocity will drop to 1000 RPM provided the machine is running.<br />
#Because of the tram on the mill, the superfly will face better when cutting from right to left. <br />
#Careful when re-installing the vice to not install it too far in the Y direction that it crashes into the accordion material at the back of the machine when reaching its limit switch in the positive Y direction. <br />
<br />
<br />
CAM Videos<br />
#https://www.youtube.com/watch?v=Do_C_NLH5sw</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Digital-1_Training&diff=197425Digital-1 Training2018-02-16T20:49:52Z<p>Cschober: </p>
<hr />
<div>[[File: Digital_1.png|200px|right]] <br />
This is the basic training for use of the simpler digital rapid prototyping tools. Completion of the Digital-1 training allows access to<br />
<br />
*[[3D Printing|3d Filament Printers]]<br />
<br />
*[[Laser Cutting|Laser Cutters]]<br />
<br />
*[[Glass Bead Abrasive Blast Cabinet|Abrasive Blast Cabinet]]<br />
<br />
*[[Wet Sander]]<br />
<br />
===Step One===<br />
Read through the presentation linked below and complete the quiz at the end.<br />
<br />
'''[https://tulane.box.com/s/8b09xps2ma8gp5tnnh0a884vzq81gcx6 Digital-1 Presentation]'''<br />
<br />
===Step Two===<br />
Complete the following designs to demonstrate your ability to use the machines.<br />
<br />
<!--[[File:Digital_1_Tinkercad.JPG|150 px|thumb|frame|right|Tinkercad Design]]<br />
'''a)''' 3d Printer: Click the Tinkercad link below, it should open up a design for you to edit. Click on the text/name on the model and a small box should appear on the screen. Change the text to your name, then click "Export" and save everything in your design as an ".stl" file. Bring it in to the MakerSpace and successfully print it on any of the 3D printers. Fell free to paint it as you wish (I'd recommend metallic spray paint).<br />
<br />
'''[https://www.tinkercad.com/things/iISnNhGY8y9-fabulous-trug/editv2?sharecode=9-ik8d4Q1bo1-gpS4qquTQOOBgDkZw3Kc03RTXwxI0A= Tinkercad Link]'''<br />
<br />
<br clear=all>--><br />
[[File:Walker_Tag.JPG|200 px|right|thumb|frame|Backpack Tag]]<br />
'''a)''' Laser cutter: Select a piece of thin plywood from the bin labelled "Digital 1," and design and make a backpack tag for that size piece of wood like the one in the picture. Use a vector graphics software package (Illustrator, Corel Draw, Inkscape) to lay out the tag and then use the laser cutter to fabricate it from a small piece of scrap plywood. The slot for the plastic loop should have inside dimensions of 5mm x 15mm. When your tag is complete, ask the Ninja for a plastic loop.<br />
<br />
*[[Tinkercad]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197416Chase Schober2018-02-12T23:06:31Z<p>Cschober: </p>
<hr />
<div> [[File:Chase Tormach.jpg|600px]] [[File:Chase_1.jpg|400px]] <br />
<br />
'''''Machining Supervisor'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (985) 326-1792<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
During the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate the powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other seamlessly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|500px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
'''Tulane University Femtosecond & Terahertz Spectroscopy Laboratory'''<br />
<br />
[[File:Schober Jimmy 1.jpeg|350px]]<br />
[[File:Chase Jimmy 2.jpeg|350px]]<br />
[[File:Chase Jimmy 3.jpeg|350px]]<br />
<br />
<br />
'''Tulane University Reed Macromolecular Research Group:'''<br />
<br />
I was approached by a graduate student in Professor Reed's lab and asked to manufacture specialized aluminum cuvette caps. Proteins in solution (intended for pharmaceutical development) tend to adsorb to the walls of the cuvette or to the stir bar and aggregate upon agitation. These caps allow the researchers to suspend a stir bar above the bottom of the cuvette to remove the solid-solid interfacial contact while monitoring aggregation caused by agitation via light scattering. We milled nine caps out of a .75" of aluminum plate and hit our tolerance of ± .002". <br />
<br />
[[File:Chase Reed 2.jpeg|Center|400px]] [[File:Chase Reed 1.jpeg|600px]]<br />
<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
<br />
A large portion of my recent work on the lathe has been to compile a comprehensive training document. In this 37-page step-by-step manual, I thoroughly explain the operations of the lathe through detailed diagrams and user instruction. By the end of the training, the user will have made the widget shown below out of 1" aluminum stock using the Conversational mode of the Tormach lathe. <br />
<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''<br />
<br />
[[File:Lathe Training Part.jpeg|500px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Scot_Ackerman_MakerSpace_at_Tulane_University_Wiki&diff=197404Scot Ackerman MakerSpace at Tulane University Wiki2018-02-09T17:47:53Z<p>Cschober: </p>
<hr />
<div>'''Mardi Gras Schedule: Open normally Wednesday 2/14. Closed Mardi Gras day. Open 10AM-noon on Lundi Gras.'''<br />
<br />
----<br />
<br />
[[File:MakerSpace_pano.jpg.JPG|1200px]]<br />
<br />
A MakerSpace has been [https://placesjournal.org/article/makerspace-towards-a-new-civic-infrastructure/ described]<br />
as new amalgam of art, craft, and technology. Our goal is to serve all makers, and potential makers, in the Tulane Community. We do so by providing tools, assistance, and ideas. '''Commercial use of the MakerSpace is not allowed.''' If in doubt, questions about interpretation should be directed to the [https://makerspace.tulane.edu/index.php/People#MakerSpace_Director Director] before a project is started.<br />
<br />
{| class="wikitable" align="right" style="text-align:center"<br />
|-<br />
!Connect!<br />
|-<br />
|[[File:Facebook.png|85px|link=https://www.facebook.com/MakerSpace.Tulane]]<br />
[https://www.facebook.com/MakerSpace.Tulane Facebook]<br />
|-<br />
|[[File:LinkedIn.jpg|100px|link=https://www.linkedin.com/groups/Tulane-MakerSpace-8483294/about]]<br />
[https://www.linkedin.com/groups/Tulane-MakerSpace-8483294/about LinkedIn]<br />
|-<br />
|[[File:Slack_Icon.png|100px|link=https://join.slack.com/tulanemakerspace/signup]]<br />
[https://join.slack.com/tulanemakerspace/signup Slack]<br />
|-<br />
|[[File:Instagram.png|100px|link=https://www.instagram.com/tulane_makerspace/]]<br />
[https://www.instagram.com/tulane_makerspace/ Instagram]<br />
|}<br />
<br />
==[[Software#Getting_Started|Just Getting Started?]]==<br />
<br />
==Where are we?==<br />
[[https://goo.gl/maps/tNEXdiFUhAS2 Google Map]] <br />
[[https://makerspace.tulane.edu/index.php/MakerSpace_Access Aerial view]]<br />
<br />
==When are we open?==<br />
'''Click on "[[MakerSpace Access]]" to see our hours of operation.'''<br />
<br />
==News and Updates==<br />
===News===<br />
*We have yet another new 3D printer. This one's a Monoprice IIIP Mini Delta. For $160, the print quality is quite good. It uses a special version of Cura, available on the computer next to the Carvey. Here's the [https://makerspace.tulane.edu/index.php/Equipment_Manuals#3d_Printers manual]<br />
<br />
*Our new 3D printer, a [https://www.googleadservices.com/pagead/aclk?sa=L&ai=DChcSEwjLj_uDntDYAhUL22QKHeAdBIQYABAAGgJwag&ohost=www.google.com&cid=CAESEeD2VRq-mX2ONKQl7prYQRA4&sig=AOD64_3Qx4gw3o-PUrLkQF2r1BZkwcr-kw&q=&ved=0ahUKEwjWrvWDntDYAhULxGMKHas_AxAQ0QwIJw&adurl= Prusa MK3] has arrived and it's set up to run. Instead of Cura, use PrusaControl on the PC next to the Carvey. Build volume is z=9.84" x=8.3" y=8.3" and the manual is [https://makerspace.tulane.edu/index.php/Equipment_Manuals#3d_Printers here]<br />
<br />
*The MakerSpace is featured in the launch for Tulane's $1.3B fund raising campaign. Chase Schober, one of our Ninjas, is seen in the [http://audacious.tulane.edu/ video] and the [http://audacious.tulane.edu/stories/all-the-ingenuity-under-the-sun/ web site] mentions the NASA team in the MakerSpace. <br />
<br />
*A new [https://www.youtube.com/watch?v=L9qS76U4Z1k&authuser=0 video], featuring Maker Ninja Antonius Prader, was produced by the Office of Admission. Shout-out to Justin Baris for organizing this.<br />
<br />
*We have purchased a Carvey and a Formlabs SLA printer. Both are available to users with '''[[Digital-2_Training]]''' credentials.<br />
<br />
*A 30-second [https://www.dropbox.com/s/2diar4rvr7i3p46/TU-2017-PSA-30.mov?dl=0 video], featuring the NASA team, was filmed in the MakerSpace. <br />
<br />
*We have started a [https://tulanemakerspace.slack.com/ Slack channel] for the Tulane MakerSpace to post micro-updates and discussions. You can join by clicking [https://join.slack.com/tulanemakerspace/signup here] or the button at the right of the page.<br />
<br />
*The Tulane MakerSpace was recently featured as part of a tour for the Board of Tulane. The tour was well-received and many board members enjoyed discussing projects and tools with '''Chase Schober''' and '''Olivia Michael'''.<br />
<br />
*We have upgraded our 3d printing equipment and filaments, and can now report that (almost) all of our 3d printers are reliably creating beautiful prints and we haven't had a failed print in well over a month of heavy use.<br />
<br />
*The 2017 '''Maker of the Year''' Awards were announced on April 18. The winners of cash prizes are '''Chase Schober''' and '''Rae Mills'''. Scroll down to see their winning submissions.<br />
<br />
*On April 12, 2017 Tulane's PR Office sent out a press release featuring a photo of [http://news.tulane.edu/news/campus-workspace-helps-students-bring-their-ideas-life '''Cody O'Cain's 3-d cosine map'''] <br />
<br />
*The March '17 '''TULANIAN''' magazine features the MakerSpace on [http://www.pageturnpro.com/Progress-Printing/77574-Tulane-March-2017/index.html#1 pages 5, 7, and 11] of the print edition (pages 7, 9, and 13 in the electronic version). <br />
<br />
*'''[[MakerSpace Digital Library]]''' is now available in the mezzanine area of the MakerSpace.<br />
<br />
*'''The Hullabaloo (2/9/2017) '''reports on the MakerSpace as a place for [http://tulanehullabaloo.com/17405/news/makerspace-promotes-technology-design/ collaboration]<br />
<br />
*'''Please watch our new (1/24/2017) [https://youtu.be/oWzSFK_JPI8 video],''' featuring Maker Ninjas Afsheen, Ben, and Elise. <br />
<br />
*And while you have a YouTube window open, check out the [https://youtu.be/joVTsoJ4z14 video] of Tulane University's '''2016/17 ''grand prize winning team submission'' to [http://bigidea.nianet.org/ NASA's BIG Idea Challenge]''' MakerSpace users designed and built a scale prototype for a modular spacecraft intended to ferry cargo spacecraft from Low Earth Orbit (LEO) To Lunar-Distant Retrograde Orbit (LDRO). MakerSpace Advisor Prof. Schuler was the team's mentor.<br />
<br />
===Upcoming Events===<br />
<br />
===Maker of the Year===<br />
The 2017 Maker of the Year Award, funded by [http://tulane.edu/sse/news/alumnus-connects-tulane-to-microscopes-history.cfm a generous gift from Lary Walker (G ’76, ’79)] are Chase Schober (Engineering Physics) and Rae Mills (Computer Science and Studio Art). <br />
<div><ul> <br />
<li style="display: inline-block;"> [[File:Chase_MOTY.JPG|400px|thumb|none|Chase Schober: 3D scanned hand in a living hinge acrylic box]] </li><br />
<li style="display: inline-block;"> [[File:Rae_MOTY.JPG|400px|thumb|none|Rae Mills: Brass cast necktie, lost wax method casting from PLA printed segments]] </li><br />
<br />
</ul><br />
</div><br />
<br />
===Architecture Laser Cutter===<br />
The School of Architecture's large format laser cutters are available to MakerSpace users. Currently they charge $10/hour ($3 minimum) for machine time; payable with Splash card or check. They have extended operating hours. Go to http://architecture.tulane.edu/dol/reserve-laser to schedule time on one of their three 36"x18" laser cutters. File formats are PDF or Illustrator. As with our Epilog laser cutters, use a line width of 0.001" to vector cut. Be sure to set your document size to their bed size of 36"x18" which is different from the bed size of the Epilogs. Bring your material and files (on a USB drive) to room 104 of Richardson Memorial Hall; student workers are there to help you get set up.<br />
<br />
==Links on this Wiki==<br />
[[MakerSpace Access]]<br />
:Hours, location, and contact information.<br />
[[Contracted Projects]]<br />
:Policy on fabrication projects for Tulane clients<br />
[[Available Tools]]<br />
:Links and information concerning the tools we have in the MakerSpace, grouped by category.<br />
[[Safety and Manuals]]<br />
:Information on safety procedures and training, plus links to instruction manuals for equipment.<br />
[[Software]]<br />
:A list of software programs that are available to students, with notes on their use.<br />
[[Supplies]]<br />
:Supplies on hand at the MakerSpace, and where to find them.<br />
[[Other Resources]]<br />
:Information about suppliers and other online resources.<br />
[[Project Guides and Tutorials]]<br />
:Samples of projects and instructions for doing them yourself.<br />
[[MakerSpace Digital Library]]<br />
:Access the digital library for MakerSpace books and resources<br />
[[Gallery]]<br />
:Examples of projects built in the Tulane MakerSpace.<br />
[[People]]<br />
:Information on those involved in building, managing, and improving the Tulane MakerSpace.<br />
[[MARS (Makers And Robotics Society)]]<br />
:Connect with the Tulane Makers and Robotics Society.<br />
[[Support & Contribute]]<br />
:Methods for supporting the Tulane MakerSpace<br />
<br />
== The New Orleans Maker Community ==<br />
New Orleans has a long history of artistic creation, and that creativity is now expressed in a vibrant maker community. The Tulane MakerSpace is proud to be a part of this community. Other members include<br />
*[[image:Fablab.JPG|75px]][http://www.dcc.edu/student-services/studentaffairs/fablab.aspx FabLab NOLA, at Delgado Community College, open to the community]<br> <br><br />
*[[image:Entrescan.png|50px]][https://entrescan.com/ Entrescan, professional advanced manufacturing services.]<br><br> <br />
*[[image: logo RDP.jpg|50px]][http://www.realized-designs.com/ Realized Designs, professional design and production studio]<br> <br><br />
*[[image:makersofno.png|50px]][https://www.facebook.com/groups/makersofno/ Makers of N.O., local Makers group]<br><br> <br />
*[[image:minimaker.bmp]][http://nolamakerfaire.com/ The New Orleans Mini Maker Faire]<br><br><br />
*[[image:mystic.bmp]][http://mystickrewe.com/ The Mystic Krewe of the Silver Ball]<br />
<br />
==Wiki==<br />
*[[Wiki Access]]<br />
*[[Basic Editing Instructions]]<br />
* [//meta.wikimedia.org/wiki/Help:Contents User's Guide] <br />
* [//www.mediawiki.org/wiki/Special:MyLanguage/Manual:Configuration_settings Configuration settings list]<br />
* [//www.mediawiki.org/wiki/Special:MyLanguage/Manual:FAQ MediaWiki FAQ]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197394Chase Schober2018-02-04T16:42:11Z<p>Cschober: </p>
<hr />
<div> [[File:Chase Tormach.jpg|600px]] [[File:Chase_1.jpg|400px]] <br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (985) 326-1792<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other seamlessly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|500px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
'''Tulane University Femtosecond & Terahertz Spectroscopy Laboratory'''<br />
<br />
[[File:Schober Jimmy 1.jpeg|350px]]<br />
[[File:Chase Jimmy 2.jpeg|350px]]<br />
[[File:Chase Jimmy 3.jpeg|350px]]<br />
<br />
<br />
'''Tulane University Reed Macromolecular Research Group:'''<br />
<br />
I was approached by a graduate student in Professor Reed's lab and asked to manufacture specialized aluminum cuvette caps. Proteins in solution (intended for pharmaceutical development) tend to adsorb to the walls of the cuvette or to the stir bar and aggregate upon agitation. These caps allow the researchers to suspend a stir bar above the bottom of the cuvette to remove the solid-solid interfacial contact while monitoring aggregation caused by agitation via light scattering. We milled nine caps out of a .75" of aluminum plate and hit our tolerance of ± .002". <br />
<br />
[[File:Chase Reed 2.jpeg|Center|400px]] [[File:Chase Reed 1.jpeg|600px]]<br />
<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
<br />
A large portion of my recent work on the lathe has been to compile a comprehensive training document. In this 37-page step-by-step manual, I thoroughly explain the operations of the lathe through detailed diagrams and user instruction. By the end of the training, the user will have made the widget shown below out of 1" aluminum stock using the Conversational mode of the Tormach lathe. <br />
<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''<br />
<br />
[[File:Lathe Training Part.jpeg|500px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Project_Guides_and_Tutorials&diff=197392Project Guides and Tutorials2018-02-02T18:59:16Z<p>Cschober: </p>
<hr />
<div>==[[Using the Laser Cutter]]==<br />
[[File:Epilog Helix.jpg|125px|top|right]]<br />
The laser cutters can be used to either cut specific paths or engrave images. This tutorial will show you how to use a laser cutter once you have designed your image.<br />
<br />
Instructions for [[Using the Laser Cutter]]<br />
<br />
Download [[Inkscape]]<br />
<br />
==[[Using the 3d Printers]]==<br />
[[File:TAZ_5.jpg|125px|top|right]]<br />
A 3d printer will build your 3d model layer-by-layer. This tutorial will show you the basics on how to set up your model to be run on one of the 3d printers.<br />
<br />
Instructions for [[Using the 3d Printers]]<br />
<br />
Download [[Cura]] for Taz 5 or Ultimaker 2<br />
<br />
==[http://www.instructables.com Instructables]==<br />
There are thousands of free projects and plans available on the [http://www.instructables.com Instructables] website for just about any kind of idea, you can simply browse through their main sections or search for a specific type of project to find plans, schematics, videos, and instructions to build or modify their projects yourself.<br />
<br />
==[[Making a Tabbed Box using the Laser Cutter]]==<br />
[[File:Canister3.JPG|100px|right]]<br />
The tabbed box is one of the simplest and most useful things to design for the [[Laser Cutting|laser cutter]]. There are several online applications that will take your input and allow you to download an [[vector graphics|.svg]] file that can be incorporated into [[Inkscape]], [[CorelDraw]], or [[Adobe Illustrator|Illustrator]]. In my view, using an [[Inkscape Extensions|Inkscape extension]] is by far the easiest way to design your box and make adjustments right in Inkscape itself.<br />
<br />
Instructions for [[Making a Tabbed Box using the Laser Cutter]]<br />
<br />
Download [http://www.inkscapeforum.com/viewtopic.php?t=18315 BoxMaker for Inkscape 0.91.zip]<br />
<br />
Online service: [http://www.festi.info/boxes.py/ Boxes.py]<br />
<br />
==[[Creating Stacked 3d Models using the Laser Cutter]]==<br />
[[File:Picture_32.jpg|150px|right]]<br />
The [[Laser Cutting|laser cutter]] can be used to create 3d models by cutting individual thin layers and then stacking them together to create a full size object. This is useful for creating prototypes that may be too large to be [[3D Printing|3d printed]].<br />
<br />
Instructions for [[Creating Stacked 3d Models using the Laser Cutter]]<br />
<br />
Download [[AutoDesk 123D Make]]<br />
<br />
==[http://makerspace.tulane.edu/Uploads/RotaryAttachment.pdf Etching Glasses on the Laser Cutter (.pdf)]==<br />
<br />
The Rotary Attachment allows you to mark, engrave or cut cylindrical objects, including pint gloasses and mugs. Follow the instructions attached to install and use the Rotary Attachment.<br />
<br />
==[http://makerspace.tulane.edu/Uploads/SolidWorks_to_Laser_Cutter.pdf Transferring SolidWorks Drawings to the Laser Cutter (.pdf)]==<br />
<br />
If you have designed an object for the [[Laser Cutting|laser cutter]] (such as a box) using [[Solidworks]], this will show you how to transfer your Solidworks models into [[Inkscape]] files to be sent to the laser cutter.<br />
<br />
Instructions for [http://makerspace.tulane.edu/Uploads/SolidWorks_to_Laser_Cutter.pdf Transferring SolidWorks Drawings to the Laser Cutter (.pdf)]<br />
<br />
==[[Preparing an Image for Rastering on the Laser Cutter]]==<br />
<br />
http://support.epiloglaser.com/article/8205/50104/photo-laser-engraving-on-wood-with-CorelDRAW<br />
<br />
==[[Finishing effects|Finishing a 3d Printed Object]]==<br />
Often 3d printed objects may not be in the correct color or may have a rough texture (especially with quicker prints). There are a number of methods for finishing 3d printed objects, included here are simply a few suggestions.<br />
<br />
<br />
Instructions for [[Finishing effects|Finishing a 3d Printed Object]]<br />
<br />
==[[Welding Acrylic]]==<br />
Acrylic is one of the best materials to use on a [[Laser Cutting|laser cutter]] because of its versatility, transparency, and ease of cutting/etching. However, acrylic is notoriously difficult to bond with glues and other adhesives in a clean fashion and scratches easily when trying to remove unsightly residue. Welding acrylic is easy to do with the right materials and can create incredibly strong bonds with little to no residue left over.<br />
<br />
Instructions for [[Welding Acrylic]]<br />
<br />
==[[Create Your Own Maker Profile/Portfolio]]==<br />
Add to your resume with a simple profile of your Maker skills and a portfolio of your projects.<br />
<br />
Instructions for [[Create Your Own Maker Profile/Portfolio]]<br />
<br />
==[[Tulane MakerSpace Image Files]]==<br />
Go ahead and play with our logo, feel free to incorporate it into whatever you want. A bunch of downloadable files [[Tulane MakerSpace Image Files|here]], please add to the collection if you create something cool.<br />
<br />
Downloads for [[Tulane MakerSpace Image Files]]<br />
<br />
==Make Magazine Skill Builders==<br />
Each of these external links to the Make Magazine web site covers a very specific skill. If you're unfamiliar with a tool, material or process, these are the best way to get the background you need.<br />
<br />
[http://makezine.com/2016/01/04/top-skill-builders-on-make-in-2015/ List of Popular Skill Builder Topics]<br />
<br />
[http://makezine.com/tag/skill-builder/ Full list of all Skill Builder Topics]<br />
<br />
[http://makezine.com/2015/11/13/how-to-use-your-digital-calipers-7-tips/ Measuring with Digital Calipers]<br />
<br />
[http://makezine.com/2015/11/02/5-cool-things-you-may-not-know-about-your-tape-measure/ Tape measure tricks and features]<br />
<br />
[http://makezine.com/2015/11/03/types-of-bearings-and-what-to-use-them-for/ Types of bearings and how to use them]<br />
<br />
[http://makezine.com/2015/06/24/skill-builder-working-with-sheet-metal/ Elementary sheet metal work]<br />
<br />
[http://makezine.com/2015/03/24/skill-builder-4-useful-metal-working-techniques/ Introduction to metal working]<br />
<br />
[http://makezine.com/2015/10/15/how-and-when-to-use-protoboard/ Soldered protoboards for electronics projects]<br />
<br />
[http://makezine.com/2015/11/07/essential-woodworking-skills-with-projects/ Elementary woodworking skills]<br />
<br />
[http://makezine.com/2015/09/03/skill-builder-use-speed-square/ Using a carpentry speed-square]<br />
<br />
[http://makezine.com/2015/10/29/skill-builder-acrylic/ Cutting and bending Plexiglass sheets]<br />
<br />
[http://makezine.com/projects/make-38-cameras-and-av/foam-sculpting-surfacing-skinning/ Carving and smoothing structural styrofoam]<br />
<br />
[http://makezine.com/2015/06/17/skill-builder-anatomy-cnc-router/ Introduction to CNC routers]<br />
<br />
[http://makezine.com/projects/skill-builder-finding-the-center/ Workpiece layout - finding the center]<br />
<br />
[http://makezine.com/2015/06/09/hot-glue-rescues-failing-3d-print/ Repairing failed 3d prints with hot melt glue]<br />
<br />
[http://makezine.com/projects/make-40/working-with-bondo/ Sculpting and smoothing with Bondo auto body filler]<br />
<br />
[http://makezine.com/projects/skill-builder-soldering-iron-tips/ Choosing the right tip for a soldering iron]<br />
<br />
[http://makezine.com/projects/skill-builder-wire-strippers/ Choosing the right wire strippers]<br />
<br />
[http://makezine.com/projects/make-38-cameras-and-av/macroplatt/ Taking photos of small objects]<br />
<br />
[http://makezine.com/2014/03/24/skill-builder-arduino-101-arduinod14/ First intro to Arduino - make a light blink]<br />
<br />
[http://makezine.com/projects/make-33/cnc-panel-joinery-2/ Design tools for joining laser-cut parts - also works for CNC]<br />
<br />
[http://makezine.com/projects/make-35/advanced-arduino-sound-synthesis/ Arduino sound synthesis]<br />
<br />
[http://makezine.com/projects/make-34/skill-builder-finishing-and-post-processing-your-3d-printed-objects/ Welding smoothing riveting and painting 3d printed objects]<br />
<br />
[http://makezine.com/2015/06/24/skill-builder-know-your-rivets/ Rivets and how to use them]<br />
<br />
[http://makezine.com/projects/skill-builder-designing-dual-extrusion-3d-printed-parts/ Dual extruder 3d printing - getting started]<br />
<br />
[http://makezine.com/2015/06/29/skill-builder-personal-eye-protection-basics/ Eye protection options]<br />
<br />
[http://makezine.com/2015/06/08/skill-builder-introduction-pvc-pipe-sizing/ PVC pipe dimensions and uses]<br />
<br />
[http://makezine.com/projects/skill-builder-pvc-pipe/ How to cut, glue and drill PVC pipe]<br />
<br />
[http://makezine.com/projects/skill-builder-convert-stl-file-laser-cutting/ Using .stl files on the laser cutter]<br />
<br />
[http://makezine.com/?s=skill+builder]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Project_Guides_and_Tutorials&diff=197391Project Guides and Tutorials2018-02-02T18:57:40Z<p>Cschober: </p>
<hr />
<div>==[[Using the Laser Cutter]]==<br />
[[File:Epilog Helix.jpg|125px|top|right]]<br />
The laser cutters can be used to either cut specific paths or engrave images. This tutorial will show you how to use a laser cutter once you have designed your image.<br />
<br />
Instructions for [[Using the Laser Cutter]]<br />
<br />
Download [[Inkscape]]<br />
<br />
==[[Using the 3d Printers]]==<br />
[[File:TAZ_5.jpg|125px|top|right]]<br />
A 3d printer will build your 3d model layer-by-layer. This tutorial will show you the basics on how to set up your model to be run on one of the 3d printers.<br />
<br />
Instructions for [[Using the 3d Printers]]<br />
<br />
Download [[Cura]] for Taz 5 or Ultimaker 2<br />
<br />
==[http://www.instructables.com Instructables]==<br />
There are thousands of free projects and plans available on the [http://www.instructables.com Instructables] website for just about any kind of idea, you can simply browse through their main sections or search for a specific type of project to find plans, schematics, videos, and instructions to build or modify their projects yourself.<br />
<br />
==[[Making a Tabbed Box using the Laser Cutter]]==<br />
[[File:Canister3.JPG|100px|right]]<br />
The tabbed box is one of the simplest and most useful things to design for the [[Laser Cutting|laser cutter]]. There are several online applications that will take your input and allow you to download an [[vector graphics|.svg]] file that can be incorporated into [[Inkscape]], [[CorelDraw]], or [[Adobe Illustrator|Illustrator]]. In my view, using an [[Inkscape Extensions|Inkscape extension]] is by far the easiest way to design your box and make adjustments right in Inkscape itself.<br />
<br />
Instructions for [[Making a Tabbed Box using the Laser Cutter]]<br />
<br />
Download [http://www.inkscapeforum.com/viewtopic.php?t=18315 BoxMaker for Inkscape 0.91.zip]<br />
<br />
Online service: [http://www.festi.info/boxes.py/ Boxes.py]<br />
<br />
==[[Creating Stacked 3d Models using the Laser Cutter]]==<br />
[[File:Picture_32.jpg|150px|right]]<br />
The [[Laser Cutting|laser cutter]] can be used to create 3d models by cutting individual thin layers and then stacking them together to create a full size object. This is useful for creating prototypes that may be too large to be [[3D Printing|3d printed]].<br />
<br />
Instructions for [[Creating Stacked 3d Models using the Laser Cutter]]<br />
<br />
Download [[AutoDesk 123D Make]]<br />
<br />
==[http://makerspace.tulane.edu/Uploads/RotaryAttachment.pdf Etching Glasses on the Laser Cutter (.pdf)]==<br />
<br />
The Rotary Attachment allows you to mark, engrave or cut cylindrical objects, including pint gloasses and mugs. Follow the instructions attached to install and use the Rotary Attachment.<br />
<br />
==[http://makerspace.tulane.edu/Uploads/SolidWorks_to_Laser_Cutter.pdf Transferring SolidWorks Drawings to the Laser Cutter (.pdf)]==<br />
<br />
If you have designed an object for the [[Laser Cutting|laser cutter]] (such as a box) using [[Solidworks]], this will show you how to transfer your Solidworks models into [[Inkscape]] files to be sent to the laser cutter.<br />
<br />
Instructions for [http://makerspace.tulane.edu/Uploads/SolidWorks_to_Laser_Cutter.pdf Transferring SolidWorks Drawings to the Laser Cutter (.pdf)]<br />
<br />
==[[Finishing effects|Finishing a 3d Printed Object]]==<br />
Often 3d printed objects may not be in the correct color or may have a rough texture (especially with quicker prints). There are a number of methods for finishing 3d printed objects, included here are simply a few suggestions.<br />
<br />
Instructions for [[Rastering an Image on the Laser Cutter]]<br />
<br />
http://support.epiloglaser.com/article/8205/50104/photo-laser-engraving-on-wood-with-CorelDRAW<br />
<br />
Instructions for [[Finishing effects|Finishing a 3d Printed Object]]<br />
<br />
==[[Welding Acrylic]]==<br />
Acrylic is one of the best materials to use on a [[Laser Cutting|laser cutter]] because of its versatility, transparency, and ease of cutting/etching. However, acrylic is notoriously difficult to bond with glues and other adhesives in a clean fashion and scratches easily when trying to remove unsightly residue. Welding acrylic is easy to do with the right materials and can create incredibly strong bonds with little to no residue left over.<br />
<br />
Instructions for [[Welding Acrylic]]<br />
<br />
==[[Create Your Own Maker Profile/Portfolio]]==<br />
Add to your resume with a simple profile of your Maker skills and a portfolio of your projects.<br />
<br />
Instructions for [[Create Your Own Maker Profile/Portfolio]]<br />
<br />
==[[Tulane MakerSpace Image Files]]==<br />
Go ahead and play with our logo, feel free to incorporate it into whatever you want. A bunch of downloadable files [[Tulane MakerSpace Image Files|here]], please add to the collection if you create something cool.<br />
<br />
Downloads for [[Tulane MakerSpace Image Files]]<br />
<br />
==Make Magazine Skill Builders==<br />
Each of these external links to the Make Magazine web site covers a very specific skill. If you're unfamiliar with a tool, material or process, these are the best way to get the background you need.<br />
<br />
[http://makezine.com/2016/01/04/top-skill-builders-on-make-in-2015/ List of Popular Skill Builder Topics]<br />
<br />
[http://makezine.com/tag/skill-builder/ Full list of all Skill Builder Topics]<br />
<br />
[http://makezine.com/2015/11/13/how-to-use-your-digital-calipers-7-tips/ Measuring with Digital Calipers]<br />
<br />
[http://makezine.com/2015/11/02/5-cool-things-you-may-not-know-about-your-tape-measure/ Tape measure tricks and features]<br />
<br />
[http://makezine.com/2015/11/03/types-of-bearings-and-what-to-use-them-for/ Types of bearings and how to use them]<br />
<br />
[http://makezine.com/2015/06/24/skill-builder-working-with-sheet-metal/ Elementary sheet metal work]<br />
<br />
[http://makezine.com/2015/03/24/skill-builder-4-useful-metal-working-techniques/ Introduction to metal working]<br />
<br />
[http://makezine.com/2015/10/15/how-and-when-to-use-protoboard/ Soldered protoboards for electronics projects]<br />
<br />
[http://makezine.com/2015/11/07/essential-woodworking-skills-with-projects/ Elementary woodworking skills]<br />
<br />
[http://makezine.com/2015/09/03/skill-builder-use-speed-square/ Using a carpentry speed-square]<br />
<br />
[http://makezine.com/2015/10/29/skill-builder-acrylic/ Cutting and bending Plexiglass sheets]<br />
<br />
[http://makezine.com/projects/make-38-cameras-and-av/foam-sculpting-surfacing-skinning/ Carving and smoothing structural styrofoam]<br />
<br />
[http://makezine.com/2015/06/17/skill-builder-anatomy-cnc-router/ Introduction to CNC routers]<br />
<br />
[http://makezine.com/projects/skill-builder-finding-the-center/ Workpiece layout - finding the center]<br />
<br />
[http://makezine.com/2015/06/09/hot-glue-rescues-failing-3d-print/ Repairing failed 3d prints with hot melt glue]<br />
<br />
[http://makezine.com/projects/make-40/working-with-bondo/ Sculpting and smoothing with Bondo auto body filler]<br />
<br />
[http://makezine.com/projects/skill-builder-soldering-iron-tips/ Choosing the right tip for a soldering iron]<br />
<br />
[http://makezine.com/projects/skill-builder-wire-strippers/ Choosing the right wire strippers]<br />
<br />
[http://makezine.com/projects/make-38-cameras-and-av/macroplatt/ Taking photos of small objects]<br />
<br />
[http://makezine.com/2014/03/24/skill-builder-arduino-101-arduinod14/ First intro to Arduino - make a light blink]<br />
<br />
[http://makezine.com/projects/make-33/cnc-panel-joinery-2/ Design tools for joining laser-cut parts - also works for CNC]<br />
<br />
[http://makezine.com/projects/make-35/advanced-arduino-sound-synthesis/ Arduino sound synthesis]<br />
<br />
[http://makezine.com/projects/make-34/skill-builder-finishing-and-post-processing-your-3d-printed-objects/ Welding smoothing riveting and painting 3d printed objects]<br />
<br />
[http://makezine.com/2015/06/24/skill-builder-know-your-rivets/ Rivets and how to use them]<br />
<br />
[http://makezine.com/projects/skill-builder-designing-dual-extrusion-3d-printed-parts/ Dual extruder 3d printing - getting started]<br />
<br />
[http://makezine.com/2015/06/29/skill-builder-personal-eye-protection-basics/ Eye protection options]<br />
<br />
[http://makezine.com/2015/06/08/skill-builder-introduction-pvc-pipe-sizing/ PVC pipe dimensions and uses]<br />
<br />
[http://makezine.com/projects/skill-builder-pvc-pipe/ How to cut, glue and drill PVC pipe]<br />
<br />
[http://makezine.com/projects/skill-builder-convert-stl-file-laser-cutting/ Using .stl files on the laser cutter]<br />
<br />
[http://makezine.com/?s=skill+builder]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Tormach_CNC_Milling_Machine&diff=197230Tormach CNC Milling Machine2018-01-10T16:34:38Z<p>Cschober: </p>
<hr />
<div>{| class="wikitable" style="text-align:center"<br />
|-<br />
! '''Required [[Badge]]''' !! '''Required [[PPE]]'''<br />
|-<br />
| [[File: CNC.png|100px]] || [[File: Safety_Eye.png|100px]] || [[File: Safety_Pants.png|100px]] || [[File: Safety_Hair.png|100px]] || [[File: Safety_Shoes.png|100px]] || [[File: Safety_Jewelry.png|100px]]<br />
|-<br />
|}<br />
<br />
Job Hazard Analysis (JHA) documents, Personal Protective Equipment (PPE) information, and Operator's Manuals can be found in the [[Safety and Manuals]] section.<br />
<br />
This machine is covered under the '''CNC''' training. Users who have not completed this training cannot use this machine.<br />
<br />
CNC:<br />
#When facing with a superfly on aluminum, use 1500 RPM, 9% velocity slider (~10 ipm)<br />
#When performing cuts on a thin sheet of aluminum, stabilize it on either side with 1-2-3 blocks. Also, to reduce chatter, face with an 1/2" endmill using 1500 RPM and 9% velocity slider (~10 ipm)<br />
#When cutting a thin plate of aluminum stock, tools like the 1/2" and the shear hog will induce too much pressure and cause chatter. This can be prevented by performing your adaptive and contour operations with a small bit such as a 3/16".<br />
#Always reference Z first<br />
#Max grip on the vise is 5.3"<br />
#If the safety enclosure is not properly closed, the spindle velocity will drop to 1000 RPM provided the machine is running.<br />
#Because of the tram on the mill, the superfly will face better when cutting from right to left. <br />
#Careful when re-installing the vice to not install it too far in the Y direction that it crashes into the accordion material at the back of the machine when reaching its limit switch in the positive Y direction. <br />
<br />
CNC 101: Turning on the mill<br />
#Open the mill enclosure door by sliding the two silver handles apart. Open them to their full capability. <br />
#In the back-right of the mill enclosure, to the right of the Series 3 text, there is a yellow and red power switch. You may need to stick your head in the enclosure to see it. When in the “Off” position, the red switch will be pointed in the 12:00 position. To turn on the power, one needs to rotate the red switch 90 degrees clockwise to the 3:00 position.<br />
#Flipping this switch will cause the computer monitor to boot up. It will take about 30 seconds for the screen to display its various start-up screens before settling into the display screen shown below. Note the flashing red Reset button indicating that the system has not been initiated. <br />
#Whenever the CNC mill is turned off, it must be E-stopped first. E-stop stands for Emergency stop and is the button responsible for cutting power to the machine in case of an emergency. On this CNC mill, the E-stop is the red button to the right of the enclosure doors. To reset the machine, the E-stop needs to be released. Do this by rotating the red button clockwise about 90 degrees. At the 3:00 position, the button will release and spring out. Once this has occurred, press the green button to the right of the E-stop. You should see the enclosure lights flicker as power is returned to the machine. <br />
#On the computer monitor, click the flashing red "reset" button. You should hear an audible click. <br />
#Now that the machine has been reset, the next step is to reference its axes. For this CNC mill in its particular arrangement, there are three axes, the X, Y, and Z. The X and Y axis are in the plane of the ground, with X referring to left-right movement and Y referring to the front-back movement. The Z axis moves the spindle up and down. For the mill to know where it is in space, we need to reference the machine. This occurs by moving the machine as far as is allowed in one direction until it encounters a limit switch. When the mill strikes this limit switch, it knows where the spindle is in relation to the enclosure bed. <br />
#ALWAYS REFERENCE THE Z AXIS FIRST! It is very important to do so because there will never be any obstacles in the positive Z direction. If you had a workpiece loaded into the machine and erroneously chose to reference the X or Y axis first, you could crash the machine. Click the "REF Z" button in the middle of the computer screen. This will cause the machine to travel in the positive Z direction until it encounters the limit switch. Once it stops, notice that the circle to the top right of the “REF Z” button is filled with green. This indicates that the Z-axis has been properly referenced. <br />
#Once the green LED next to “REF Z” is visible, click "REF X" and watch as the machine travels to its X-axis limit switch. <br />
#Once the green LED next to “REF X” is visible, click "REF Y" and watch as the machine travels to its Y-axis limit switch. <br />
#Verify that there are green circles above each of the REF buttons before continuing. Note that there is a forth letter displayed on the screen, “A”. This is used for when the CNC Mill is in its four-axis arrangement. It can be ignored for the purposes of this tutorial. <br />
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Moving the mill <br />
#Now we will get familiar with how to move the CNC mill. To the left of the keyboard, there is a black device known as a jog shuttle. This is the main method of moving the CNC between operations. You’ll notice that each of the four axes are represented on the jog shuttle as buttons. In the middle of your computer display, to the left of the coordinates, notice that there is a green circle to the top right of one of the four axes. By clicking an axis on the jog shuttle, this green circle illuminates in the corresponding axis on the monitor. This is how we know which axis the jog shuttle will move. <br />
#Press the “Y” button on the jog shuttle. Check the computer monitor to verify that a green circle is illuminated to the top-right of the ‘Y” button. <br />
#In the center of the jog shuttle, is a rotatable wheel known as the shuttle ring. One can move the mill along the chosen axis in the positive or negative direction by rotating the shuttle ring clockwise or counterclockwise respectively. As shown on the jog shuttle, clockwise rotation means positive movement, counterclockwise rotation means negative movement. Right now, the Y-axis is at its maximum positive position. Therefore, it can only be moved in the negative direction. Gently rotate the shuttle ring in the counterclockwise direction and then release it. Notice the speed at which the bed adjusts. A more pronounced rotation means faster bed movement. <br />
#Move the mill to its opposite Y-axis limit switch. You can do this rotating the shuttle ring in the counterclockwise direction (either slowly or quickly) until the machine prevents any further movement. <br />
#Travel back and forth between the Y-axis limit switches to get comfortable driving the jog shuttle.<br />
#Once you feel comfortable, we will move to the X-axis between its limit switches. Click the “X” on the jog shuttle and verify that the green circle illuminates on the computer display to the top right of the “X” button. Just like the Y-axis, the mill is at its maximum positive X-axis position. Decide which action is needed to move the mill to its opposite limit switch and perform it. <br />
#Travel back and forth between the X-axis limit switches to understand the mill’s directions and limitations. <br />
#Now we will move the mill along the Z-axis. Unlike the X and Y movement, the mill will not stop you from crashing in the Z direction. Therefore, we need to be careful as we move the Z axis towards the bed. As you can see, there is currently a tool loaded into the mill. We do not want to crash this tool into the vice or bed. <br />
#Press the Z button on the jog shuttle to inform the mill which axis will be moved. Once the green circle next to the “Z” button on the display has been illuminated, cautiously move the mill in the negative Z direction until the tool is roughly 3” above the vice. After this is accomplished, move the mill to its Z-axis positive limit switch. <br />
#There is one other way to move the mill using the jog shuttle. In the center of the jog shuttle is a dimpled circle. This is known as the jog wheel. By rotating the jog wheel, one can move the mill in specific increments. The four possible increments are .0001”, .001”, .01”, .1”. To avoid crashes, we recommend that the step size be .0001”. This allows for precise movement and prevents the machine from lurching into a workpiece when working at close quarters. The step size can be cycled by pressing the “STEP” button on the jog shuttle. As this button is pressed, a green circle will illuminate to the top right of the specific increment on the right of the computer display. Press the “STEP” button until a green circle illuminates to the top-right of the “.0001” button. <br />
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<br />
Loading the stock<br />
#For this tutorial, we will be milling a 6” long piece of 2x4 wood stock. We will secure the stock by holding it with the vice. Securing stock while milling is an underappreciated difficulty while working with a CNC mill. <br />
#Ask the Training Ninja to provide you with your piece of wood stock. <br />
#Approach the mill enclosure and inspect the vice that is secured to the mill bed. The vice can be opened or closed by rotating its handle. Counter-clockwise rotation opens the vice and clockwise rotation closes the vice. Open the vice to its full extent.<br />
#Each time stock is to be loaded into the vice, care needs to be taken to wipe the vice clean of chips and debris. Using a rag provided by the training Ninja, comprehensively wipe the inside of the vice clean. <br />
#Place your stock in the vice as shown below. Notice how only a ¼” of the stock just above the vice. It would be very difficult to perform an operation to trim the stock without risking a crash into the vice. Therefore, we will use parallels to raise the height of the stock in the vice. Parallels are thin, flat pieces of metal with parallel sides that come in exact pairs. They are used extensively while working with this CNC mill. <br />
#On the shelf behind the CNC mill, to the left of the wooden structure holding tools, there is a blue box. In it are a set of parallels that range in height from ½” to 1 5/8”. Grab the 7/8” pair from the set (fourth pair). <br />
#Remove your wooden stock from the vice. Place one parallel against the back face of the vice, and one against the front face as shown below. Make sure that the parallels aren’t resting on any chips or debris in the vice. <br />
#Rest your wooden stock on top of the back parallel and close the vice until the wood is sitting on each parallel. Once the wood is in the correct position, place your palm on top of the wood and apply pressure to ensure that the wood is resting flatly on the parallels. Rotate the vice until you feel resistance, then rotate a quarter turn farther to make sure that the stock is secure in the vice. In general, it is better to lean on the side of overtightening as this reduces the chance that your stock will loosen while milling. However, in the case of softer materials such as wood or aluminum, overtightening can cause deformation and decreased accuracy. <br />
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Changing the tool<br />
#The tool currently loaded into the spindle is a ½” flat end mill. For this mill, individual tool numbers are assigned to each tool so that they can be referenced by the machine and other computer programs. This is tool number 11. You will notice that the tools for this mill are kept in the wooden structure on the shelf behind the mill. Each tool position is labeled with its classification, and each tool is labeled with its number. For our purposes, we will swap Tool 1, the Offset Tool, into the spindle. <br />
#Remove Tool 1 from the tool-holding structure and place it on the bench across from the CNC mill. <br />
#The current tool is removed from the spindle by accessing the motor cover. On the right side of the motor cover, there is a black clasp that secures the door. Undo this clasp by lifting the near side with your thumb and using your middle finger to pull the clasp free. Swing the door open once the clasp has been released. <br />
#Once the door has been opened, you can see the drawbar. This is connected to the spindle and translates the rotation of the belts to the tool. Notice how spinning the drawbar spins the tool. In order to loosen the tool, we will need to prevent the rotation of the spindle. Spin the drawbar until the flat side of its mounting cylinder is parallel to the enclosure doors. This will allow the spindle lock to engage. Pivot the black spindle lock from its resting position onto the drawbar mount to prevent spindle rotation. <br />
#Take the golden-headed hammer from beside the keyboard. It’s cavernous side fits onto the top of the drawbar and is used to loosen it from the spindle. Keep a hold of the tool as you loosen the spindle! When the spindle is fully loosened the tool could drop, damaging the tool or your stock. <br />
#Push the handle of the hammer in the counterclockwise direction while holding onto the tool. After rotating it ¼” turn, reposition the hammer and perform another ¼ turn. This should sufficiently loosen the tool in the spindle. Flip the hammer and use the gold side to rap the top of the drawbar WHILE HOLDING THE TOOL. The tool should release into your hand. Take Tool 11 and place it in its designated toolholding spot. <br />
#Now we will place Tool 1 into the spindle. With your left hand, press Tool 1 firmly into the spindle and hold it there as you rotate the drawbar clockwise with the hammer. Perform two ¼ turns and lean on the side of overtightening in this case. <br />
#Once Tool 1 is secured, release the spindle lock by pivoting it back into its vertical resting position. Then, swing the motor cover closed and secure its black clasp.<br />
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Referencing the stock<br />
# As mentioned previously, each tool in the tool library is assigned a designated number. This is important because each tool has a different length when measured from top to bottom. In the computer, the height of each tool is recorded so that the mill can perfectly know the coordinate of the tool tip. Each time there is a tool change, it is vitally important to tell the mill this information. NOT UPDATING YOUR TOOL NUMBER CAUSES THE MAJORITY OF CRASHES. <br />
#In the bottom-right corner of the screen, there is a text box to the right of a “T”. The number displayed in this text box is the tool that the mill thinks it is equipped with. Currently, the text box should display “0” because the mill was just reset and didn’t retain this information. To update this, highlight the “0”, type “1” since we just equipped Tool 1, and HIT ENTER on the keyboard. Notice that the Z coordinate text box updated to reflect the height of the new tool. <br />
#Now, we want to inform the machine the coordinates of our stock. To do this, we will use the offset tool to “touch off” on the stock. <br />
#Use the jog shuttle to move the X and Y axis so that the offset tool is roughly centered over the stock. <br />
#Carefully lower the offset tool in the negative Z direction until the top of the tool is about 2” above the stock top. Re-center the stock in the X and Y direction if necessary. <br />
#Above the keyboard is a clear piece of plastic known as a feeler gauge. This piece of plastic is 0.0094” thick. To reference the stock, place this gauge between the stock and the offset tool. We will slowly lower the offset tool until it is exactly the width of the plastic distance away from the stock. <br />
#Begin SLOWLY lowering the offset tool in the Z direction while performing a sawing motion with the gauge. The idea is that as soon as you can no longer easily move the gauge back and forth, the offset tool is the width of the gauge (0.0094”) away from the top of the stock. Be careful not to crash the tool by moving too quickly. As you begin to feel slight resistance, it is useful to use the jog wheel to make fine increments. Before you do, check to make sure that the step size is “.0001”. <br />
#Adjust the height until you can barely move the gauge back and forth.<br />
#Highlight the text box to the right of the “Z” button. Type “.0094” and HIT ENTER on your keyboard. The mill now correctly thinks it is positioned .0094” above the top of the stock. <br />
#Raise the Z height until the Z-coordinate value is exactly 0.5000. This is a good chance to practice using the jog wheel to make precision adjustments. <br />
#Now, we want to reference the X and Y axes. In almost all instances, we want to set X and Y equal to zero at the exact center of the stock. To achieve this, we will use a trick to find the total length and width of the part and then divide that value by two. <br />
#Drive the offset tool to the left of the stock until the metal cylinder can lower without crashing into the stock.<br />
#Lower the Z height until the coordinate value is -0.2500. <br />
#Now, we will perform the same gauge sawing action as we did when referencing the Z height. Move the tool in the positive X direction while sawing the gauge back and forth. Adjust until you can barely move the gauge back and forth. <br />
#In this tutorial, we will simplify the math involved in this process. Typically, we would want to set the left side of the stock face equal to zero, measure the coordinate at the right face of the stock, and know the exact length of our stock. For our purposes, we can get away with setting this exact point as zero, and repeating the same procedure on the other side. If both measurements are consistent in their positions relative to the stock face, the center of each method will be the same. Highlight the text box to the right of the “X” button, type “0”, and HIT ENTER on the keyboard. <br />
#Now, we will move the offset tool over to the right face of the stock. Move in the negative X direction until the X-coordinate is -0.1000. Raise the Z height of the tool until the value is 0.5000. Whenever you plan to travel over the top of a stock, take care to ensure that the tool tip is at least ½” above the stock top. Travel in the positive X direction until the offset tool can be lowered without crashing into the stock. Lower the Z height of the tool to -0.2500. <br />
#Hold the gauge in between the stock and the tool. Perform a sawing action with the gauge while simultaneously moving the tool in the negative X direction. Adjust until you can barely move the gauge back and forth. <br />
#Now, the center of the stock is exactly in the middle of these two points. Since we set the left face to be zero, all we need to do is divide the current coordinate by two. The machine makes this easy, as it can perform simple mathematical operations. Highlight the text box to the right of the “X” button, type “/2”, and HIT ENTER on the keyboard. The X=0 coordinate is now directly in the center of your stock. <br />
#Now, we will perform the same operation to reference the Y axis. There are no instructions for this portion of the tutorial as it is important to practice this type of problem solving on your own. However, the training Ninja is available to answer any questions you have. <br />
#Once all axes have been referenced, move the mill to the X=0”, Y=0”, Z=0.1” position. The tool should appear to be directly in the center of the stock, and .1” above the stock face. If this is not the case, consult your training Ninja to determine where the error occurred. If the tool looks centered, the stock is completely referenced! Raise the tool to the positive Z limit switch. <br />
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Setting up your first operation<br />
#Now that the stock has been referenced, it’s time for the fun part! On the computer monitor, in the center of the screen, click on the tab labeled “Conversational”. This is one of the ways that we can write operations for the mill to perform. <br />
#At the top of the screen, click the tab labeled “Face”. A facing operation cuts away the top part of the stock. It is almost always the precursor to any other milling operation, and is used to flatten and smooth the top surface. <br />
#There is a lot of information to cover in this section and so each text box on the screen will be broken down and explained individually. <br />
#The “Title” box is arbitrary and usually we don’t bother to change the text (you can save the file as a custom name later). <br />
#The “Work Offset” box should be filled as “G54”. The mill has several work coordinate offsets that can be used and all of the information in its current arrangement is stored in G54. <br />
#The “Tool” box should be filled with “3”. Tool 3 is known as the shear hog and is our go-to tool for removing large amounts of material. We will be using this tool to face the stock. <br />
#The “Spindle RPM” box should be filled with “6000”. This value tells the tool how fast to spin while cutting through the material. The spin rates of each tool can be explained in-depth outside of this tutorial. Presently, all you need to know is the rotation per minute (RPM) values for each tool which will be provided.<br />
#The “Feedrate” box should be filled with “40.0”. This value tells the tool how fast to move while cutting through the material. The unit for this value is inches per minute (IPM).As wood is a softer material, we can move more quickly while cutting. A harder material such as steel would need a slower federate.<br />
#The “Z Feedrate” box should be filled with “10.0”. This value tells the tool how fast to move when moving along the Z-axis. 10 is the standard value for this as this tool can cut faster laterally rather than downwards. <br />
#The “Z Clear” box should be filled with “0.2000”. This value tells the tool how high above the stock to move between operations. We want to give the tool a little clearance for peace of mind. <br />
#The “X START” box should be filled with “-3.1000”. This value corresponds to the left face’s coordinate. As our stock is roughly 6” long, a little cushion is added to be sure. <br />
#The “X END” box should be filled with “3.1000”. <br />
#The “Y START” box should be filled with “1.8500”. A 2x4 is 3.5” wide and so an extra .1” was added as a cushion.<br />
#The “STEPOVER” box should be filled with “0.7”. This value refers to how much of the tool is cutting with each pass. A value of 1.0 would mean the entire tool is cutting. Since wood is a soft material, we can be more aggressive in our stepover. The value for steel would be much less. <br />
#The “Y END” box should be filled with “-1.8500”. <br />
#The “Z START” box should be filled with “0.0000”. We want to start cutting at the plane of the top face. <br />
#The “DEPTH OF CUT” box should be filled with “0.1000”. This value refers to how deep the tool cuts with each pass. This value will vary based on the material and on the tool. Because the shear hog is very powerful, it can handle cutting this impressive depth of cut. Again, the value for steel would be significantly lower. <br />
#The Z END” box should be filled with “-0.1000”. This is because we only want to remove 0.1” of material from the top of our stock. <br />
#In the top right corner, toggle the “SPIRAL/RECT” button so that the green circle to the top right of RECT is illuminated. This is a more efficient pattern for facing operations. <br />
#Double-check through your values to make sure that the negative signs are correctly placed. This is a common mistake. <br />
#Click “POST TO FILE”. A pop-up window will appear in the center of your screen. Click the “HOME” button in the top left of the pop-up window. Double click the “CNC 101” folder. In the text box to the right of “NAME”, type 1.lastname (with lastname meaning your last name). Then click “SAVE”. <br />
#The operation will automatically load onto your screen. Congratulations, you just wrote the code for you first operation! <br />
Performing your first operation.</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Tormach_CNC_Milling_Machine&diff=197223Tormach CNC Milling Machine2018-01-10T04:13:26Z<p>Cschober: </p>
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! '''Required [[Badge]]''' !! '''Required [[PPE]]'''<br />
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| [[File: CNC.png|100px]] || [[File: Safety_Eye.png|100px]] || [[File: Safety_Pants.png|100px]] || [[File: Safety_Hair.png|100px]] || [[File: Safety_Shoes.png|100px]] || [[File: Safety_Jewelry.png|100px]]<br />
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Job Hazard Analysis (JHA) documents, Personal Protective Equipment (PPE) information, and Operator's Manuals can be found in the [[Safety and Manuals]] section.<br />
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This machine is covered under the '''CNC''' training. Users who have not completed this training cannot use this machine.<br />
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CNC:<br />
#When facing with a superfly on aluminum, use 1500 RPM, 9% velocity slider (~10 ipm)<br />
#When performing cuts on a thin sheet of aluminum, stabilize it on either side with 1-2-3 blocks. Also, to reduce chatter, face with an 1/2" endmill using 1500 RPM and 9% velocity slider (~10 ipm)<br />
#When cutting a thin plate of aluminum stock, tools like the 1/2" and the shear hog will induce too much pressure and cause chatter. This can be prevented by performing your adaptive and contour operations with a small bit such as a 3/16".<br />
#Always reference Z first<br />
#Max grip on the vise is 5.3"<br />
#If the safety enclosure is not properly closed, the spindle velocity will drop to 1000 RPM provided the machine is running.<br />
#Because of the tram on the mill, the superfly will face better when cutting from right to left. <br />
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CNC 101: Turning on the mill<br />
#Open the mill enclosure door by sliding the two silver handles apart. Open them to their full capability. <br />
#In the back-right of the mill enclosure, to the right of the Series 3 text, there is a yellow and red power switch. You may need to stick your head in the enclosure to see it. When in the “Off” position, the red switch will be pointed in the 12:00 position. To turn on the power, one needs to rotate the red switch 90 degrees clockwise to the 3:00 position.<br />
#Flipping this switch will cause the computer monitor to boot up. It will take about 30 seconds for the screen to display its various start-up screens before settling into the display screen shown below. Note the flashing red Reset button indicating that the system has not been initiated. <br />
#Whenever the CNC mill is turned off, it must be E-stopped first. E-stop stands for Emergency stop and is the button responsible for cutting power to the machine in case of an emergency. On this CNC mill, the E-stop is the red button to the right of the enclosure doors. To reset the machine, the E-stop needs to be released. Do this by rotating the red button clockwise about 90 degrees. At the 3:00 position, the button will release and spring out. Once this has occurred, press the green button to the right of the E-stop. You should see the enclosure lights flicker as power is returned to the machine. <br />
#On the computer monitor, click the flashing red "reset" button. You should hear an audible click. <br />
#Now that the machine has been reset, the next step is to reference its axes. For this CNC mill in its particular arrangement, there are three axes, the X, Y, and Z. The X and Y axis are in the plane of the ground, with X referring to left-right movement and Y referring to the front-back movement. The Z axis moves the spindle up and down. For the mill to know where it is in space, we need to reference the machine. This occurs by moving the machine as far as is allowed in one direction until it encounters a limit switch. When the mill strikes this limit switch, it knows where the spindle is in relation to the enclosure bed. <br />
#ALWAYS REFERENCE THE Z AXIS FIRST! It is very important to do so because there will never be any obstacles in the positive Z direction. If you had a workpiece loaded into the machine and erroneously chose to reference the X or Y axis first, you could crash the machine. Click the "REF Z" button in the middle of the computer screen. This will cause the machine to travel in the positive Z direction until it encounters the limit switch. Once it stops, notice that the circle to the top right of the “REF Z” button is filled with green. This indicates that the Z-axis has been properly referenced. <br />
#Once the green LED next to “REF Z” is visible, click "REF X" and watch as the machine travels to its X-axis limit switch. <br />
#Once the green LED next to “REF X” is visible, click "REF Y" and watch as the machine travels to its Y-axis limit switch. <br />
#Verify that there are green circles above each of the REF buttons before continuing. Note that there is a forth letter displayed on the screen, “A”. This is used for when the CNC Mill is in its four-axis arrangement. It can be ignored for the purposes of this tutorial. <br />
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Moving the mill <br />
#Now we will get familiar with how to move the CNC mill. To the left of the keyboard, there is a black device known as a jog shuttle. This is the main method of moving the CNC between operations. You’ll notice that each of the four axes are represented on the jog shuttle as buttons. In the middle of your computer display, to the left of the coordinates, notice that there is a green circle to the top right of one of the four axes. By clicking an axis on the jog shuttle, this green circle illuminates in the corresponding axis on the monitor. This is how we know which axis the jog shuttle will move. <br />
#Press the “Y” button on the jog shuttle. Check the computer monitor to verify that a green circle is illuminated to the top-right of the ‘Y” button. <br />
#In the center of the jog shuttle, is a rotatable wheel known as the shuttle ring. One can move the mill along the chosen axis in the positive or negative direction by rotating the shuttle ring clockwise or counterclockwise respectively. As shown on the jog shuttle, clockwise rotation means positive movement, counterclockwise rotation means negative movement. Right now, the Y-axis is at its maximum positive position. Therefore, it can only be moved in the negative direction. Gently rotate the shuttle ring in the counterclockwise direction and then release it. Notice the speed at which the bed adjusts. A more pronounced rotation means faster bed movement. <br />
#Move the mill to its opposite Y-axis limit switch. You can do this rotating the shuttle ring in the counterclockwise direction (either slowly or quickly) until the machine prevents any further movement. <br />
#Travel back and forth between the Y-axis limit switches to get comfortable driving the jog shuttle.<br />
#Once you feel comfortable, we will move to the X-axis between its limit switches. Click the “X” on the jog shuttle and verify that the green circle illuminates on the computer display to the top right of the “X” button. Just like the Y-axis, the mill is at its maximum positive X-axis position. Decide which action is needed to move the mill to its opposite limit switch and perform it. <br />
#Travel back and forth between the X-axis limit switches to understand the mill’s directions and limitations. <br />
#Now we will move the mill along the Z-axis. Unlike the X and Y movement, the mill will not stop you from crashing in the Z direction. Therefore, we need to be careful as we move the Z axis towards the bed. As you can see, there is currently a tool loaded into the mill. We do not want to crash this tool into the vice or bed. <br />
#Press the Z button on the jog shuttle to inform the mill which axis will be moved. Once the green circle next to the “Z” button on the display has been illuminated, cautiously move the mill in the negative Z direction until the tool is roughly 3” above the vice. After this is accomplished, move the mill to its Z-axis positive limit switch. <br />
#There is one other way to move the mill using the jog shuttle. In the center of the jog shuttle is a dimpled circle. This is known as the jog wheel. By rotating the jog wheel, one can move the mill in specific increments. The four possible increments are .0001”, .001”, .01”, .1”. To avoid crashes, we recommend that the step size be .0001”. This allows for precise movement and prevents the machine from lurching into a workpiece when working at close quarters. The step size can be cycled by pressing the “STEP” button on the jog shuttle. As this button is pressed, a green circle will illuminate to the top right of the specific increment on the right of the computer display. Press the “STEP” button until a green circle illuminates to the top-right of the “.0001” button. <br />
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<br />
Loading the stock<br />
#For this tutorial, we will be milling a 6” long piece of 2x4 wood stock. We will secure the stock by holding it with the vice. Securing stock while milling is an underappreciated difficulty while working with a CNC mill. <br />
#Ask the Training Ninja to provide you with your piece of wood stock. <br />
#Approach the mill enclosure and inspect the vice that is secured to the mill bed. The vice can be opened or closed by rotating its handle. Counter-clockwise rotation opens the vice and clockwise rotation closes the vice. Open the vice to its full extent.<br />
#Each time stock is to be loaded into the vice, care needs to be taken to wipe the vice clean of chips and debris. Using a rag provided by the training Ninja, comprehensively wipe the inside of the vice clean. <br />
#Place your stock in the vice as shown below. Notice how only a ¼” of the stock just above the vice. It would be very difficult to perform an operation to trim the stock without risking a crash into the vice. Therefore, we will use parallels to raise the height of the stock in the vice. Parallels are thin, flat pieces of metal with parallel sides that come in exact pairs. They are used extensively while working with this CNC mill. <br />
#On the shelf behind the CNC mill, to the left of the wooden structure holding tools, there is a blue box. In it are a set of parallels that range in height from ½” to 1 5/8”. Grab the 7/8” pair from the set (fourth pair). <br />
#Remove your wooden stock from the vice. Place one parallel against the back face of the vice, and one against the front face as shown below. Make sure that the parallels aren’t resting on any chips or debris in the vice. <br />
#Rest your wooden stock on top of the back parallel and close the vice until the wood is sitting on each parallel. Once the wood is in the correct position, place your palm on top of the wood and apply pressure to ensure that the wood is resting flatly on the parallels. Rotate the vice until you feel resistance, then rotate a quarter turn farther to make sure that the stock is secure in the vice. In general, it is better to lean on the side of overtightening as this reduces the chance that your stock will loosen while milling. However, in the case of softer materials such as wood or aluminum, overtightening can cause deformation and decreased accuracy. <br />
<br />
Changing the tool<br />
#The tool currently loaded into the spindle is a ½” flat end mill. For this mill, individual tool numbers are assigned to each tool so that they can be referenced by the machine and other computer programs. This is tool number 11. You will notice that the tools for this mill are kept in the wooden structure on the shelf behind the mill. Each tool position is labeled with its classification, and each tool is labeled with its number. For our purposes, we will swap Tool 1, the Offset Tool, into the spindle. <br />
#Remove Tool 1 from the tool-holding structure and place it on the bench across from the CNC mill. <br />
#The current tool is removed from the spindle by accessing the motor cover. On the right side of the motor cover, there is a black clasp that secures the door. Undo this clasp by lifting the near side with your thumb and using your middle finger to pull the clasp free. Swing the door open once the clasp has been released. <br />
#Once the door has been opened, you can see the drawbar. This is connected to the spindle and translates the rotation of the belts to the tool. Notice how spinning the drawbar spins the tool. In order to loosen the tool, we will need to prevent the rotation of the spindle. Spin the drawbar until the flat side of its mounting cylinder is parallel to the enclosure doors. This will allow the spindle lock to engage. Pivot the black spindle lock from its resting position onto the drawbar mount to prevent spindle rotation. <br />
#Take the golden-headed hammer from beside the keyboard. It’s cavernous side fits onto the top of the drawbar and is used to loosen it from the spindle. Keep a hold of the tool as you loosen the spindle! When the spindle is fully loosened the tool could drop, damaging the tool or your stock. <br />
#Push the handle of the hammer in the counterclockwise direction while holding onto the tool. After rotating it ¼” turn, reposition the hammer and perform another ¼ turn. This should sufficiently loosen the tool in the spindle. Flip the hammer and use the gold side to rap the top of the drawbar WHILE HOLDING THE TOOL. The tool should release into your hand. Take Tool 11 and place it in its designated toolholding spot. <br />
#Now we will place Tool 1 into the spindle. With your left hand, press Tool 1 firmly into the spindle and hold it there as you rotate the drawbar clockwise with the hammer. Perform two ¼ turns and lean on the side of overtightening in this case. <br />
#Once Tool 1 is secured, release the spindle lock by pivoting it back into its vertical resting position. Then, swing the motor cover closed and secure its black clasp.<br />
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Referencing the stock<br />
# As mentioned previously, each tool in the tool library is assigned a designated number. This is important because each tool has a different length when measured from top to bottom. In the computer, the height of each tool is recorded so that the mill can perfectly know the coordinate of the tool tip. Each time there is a tool change, it is vitally important to tell the mill this information. NOT UPDATING YOUR TOOL NUMBER CAUSES THE MAJORITY OF CRASHES. <br />
#In the bottom-right corner of the screen, there is a text box to the right of a “T”. The number displayed in this text box is the tool that the mill thinks it is equipped with. Currently, the text box should display “0” because the mill was just reset and didn’t retain this information. To update this, highlight the “0”, type “1” since we just equipped Tool 1, and HIT ENTER on the keyboard. Notice that the Z coordinate text box updated to reflect the height of the new tool. <br />
#Now, we want to inform the machine the coordinates of our stock. To do this, we will use the offset tool to “touch off” on the stock. <br />
#Use the jog shuttle to move the X and Y axis so that the offset tool is roughly centered over the stock. <br />
#Carefully lower the offset tool in the negative Z direction until the top of the tool is about 2” above the stock top. Re-center the stock in the X and Y direction if necessary. <br />
#Above the keyboard is a clear piece of plastic known as a feeler gauge. This piece of plastic is 0.0094” thick. To reference the stock, place this gauge between the stock and the offset tool. We will slowly lower the offset tool until it is exactly the width of the plastic distance away from the stock. <br />
#Begin SLOWLY lowering the offset tool in the Z direction while performing a sawing motion with the gauge. The idea is that as soon as you can no longer easily move the gauge back and forth, the offset tool is the width of the gauge (0.0094”) away from the top of the stock. Be careful not to crash the tool by moving too quickly. As you begin to feel slight resistance, it is useful to use the jog wheel to make fine increments. Before you do, check to make sure that the step size is “.0001”. <br />
#Adjust the height until you can barely move the gauge back and forth.<br />
#Highlight the text box to the right of the “Z” button. Type “.0094” and HIT ENTER on your keyboard. The mill now correctly thinks it is positioned .0094” above the top of the stock. <br />
#Raise the Z height until the Z-coordinate value is exactly 0.5000. This is a good chance to practice using the jog wheel to make precision adjustments. <br />
#Now, we want to reference the X and Y axes. In almost all instances, we want to set X and Y equal to zero at the exact center of the stock. To achieve this, we will use a trick to find the total length and width of the part and then divide that value by two. <br />
#Drive the offset tool to the left of the stock until the metal cylinder can lower without crashing into the stock.<br />
#Lower the Z height until the coordinate value is -0.2500. <br />
#Now, we will perform the same gauge sawing action as we did when referencing the Z height. Move the tool in the positive X direction while sawing the gauge back and forth. Adjust until you can barely move the gauge back and forth. <br />
#In this tutorial, we will simplify the math involved in this process. Typically, we would want to set the left side of the stock face equal to zero, measure the coordinate at the right face of the stock, and know the exact length of our stock. For our purposes, we can get away with setting this exact point as zero, and repeating the same procedure on the other side. If both measurements are consistent in their positions relative to the stock face, the center of each method will be the same. Highlight the text box to the right of the “X” button, type “0”, and HIT ENTER on the keyboard. <br />
#Now, we will move the offset tool over to the right face of the stock. Move in the negative X direction until the X-coordinate is -0.1000. Raise the Z height of the tool until the value is 0.5000. Whenever you plan to travel over the top of a stock, take care to ensure that the tool tip is at least ½” above the stock top. Travel in the positive X direction until the offset tool can be lowered without crashing into the stock. Lower the Z height of the tool to -0.2500. <br />
#Hold the gauge in between the stock and the tool. Perform a sawing action with the gauge while simultaneously moving the tool in the negative X direction. Adjust until you can barely move the gauge back and forth. <br />
#Now, the center of the stock is exactly in the middle of these two points. Since we set the left face to be zero, all we need to do is divide the current coordinate by two. The machine makes this easy, as it can perform simple mathematical operations. Highlight the text box to the right of the “X” button, type “/2”, and HIT ENTER on the keyboard. The X=0 coordinate is now directly in the center of your stock. <br />
#Now, we will perform the same operation to reference the Y axis. There are no instructions for this portion of the tutorial as it is important to practice this type of problem solving on your own. However, the training Ninja is available to answer any questions you have. <br />
#Once all axes have been referenced, move the mill to the X=0”, Y=0”, Z=0.1” position. The tool should appear to be directly in the center of the stock, and .1” above the stock face. If this is not the case, consult your training Ninja to determine where the error occurred. If the tool looks centered, the stock is completely referenced! Raise the tool to the positive Z limit switch. <br />
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Setting up your first operation<br />
#Now that the stock has been referenced, it’s time for the fun part! On the computer monitor, in the center of the screen, click on the tab labeled “Conversational”. This is one of the ways that we can write operations for the mill to perform. <br />
#At the top of the screen, click the tab labeled “Face”. A facing operation cuts away the top part of the stock. It is almost always the precursor to any other milling operation, and is used to flatten and smooth the top surface. <br />
#There is a lot of information to cover in this section and so each text box on the screen will be broken down and explained individually. <br />
#The “Title” box is arbitrary and usually we don’t bother to change the text (you can save the file as a custom name later). <br />
#The “Work Offset” box should be filled as “G54”. The mill has several work coordinate offsets that can be used and all of the information in its current arrangement is stored in G54. <br />
#The “Tool” box should be filled with “3”. Tool 3 is known as the shear hog and is our go-to tool for removing large amounts of material. We will be using this tool to face the stock. <br />
#The “Spindle RPM” box should be filled with “6000”. This value tells the tool how fast to spin while cutting through the material. The spin rates of each tool can be explained in-depth outside of this tutorial. Presently, all you need to know is the rotation per minute (RPM) values for each tool which will be provided.<br />
#The “Feedrate” box should be filled with “40.0”. This value tells the tool how fast to move while cutting through the material. The unit for this value is inches per minute (IPM).As wood is a softer material, we can move more quickly while cutting. A harder material such as steel would need a slower federate.<br />
#The “Z Feedrate” box should be filled with “10.0”. This value tells the tool how fast to move when moving along the Z-axis. 10 is the standard value for this as this tool can cut faster laterally rather than downwards. <br />
#The “Z Clear” box should be filled with “0.2000”. This value tells the tool how high above the stock to move between operations. We want to give the tool a little clearance for peace of mind. <br />
#The “X START” box should be filled with “-3.1000”. This value corresponds to the left face’s coordinate. As our stock is roughly 6” long, a little cushion is added to be sure. <br />
#The “X END” box should be filled with “3.1000”. <br />
#The “Y START” box should be filled with “1.8500”. A 2x4 is 3.5” wide and so an extra .1” was added as a cushion.<br />
#The “STEPOVER” box should be filled with “0.7”. This value refers to how much of the tool is cutting with each pass. A value of 1.0 would mean the entire tool is cutting. Since wood is a soft material, we can be more aggressive in our stepover. The value for steel would be much less. <br />
#The “Y END” box should be filled with “-1.8500”. <br />
#The “Z START” box should be filled with “0.0000”. We want to start cutting at the plane of the top face. <br />
#The “DEPTH OF CUT” box should be filled with “0.1000”. This value refers to how deep the tool cuts with each pass. This value will vary based on the material and on the tool. Because the shear hog is very powerful, it can handle cutting this impressive depth of cut. Again, the value for steel would be significantly lower. <br />
#The Z END” box should be filled with “-0.1000”. This is because we only want to remove 0.1” of material from the top of our stock. <br />
#In the top right corner, toggle the “SPIRAL/RECT” button so that the green circle to the top right of RECT is illuminated. This is a more efficient pattern for facing operations. <br />
#Double-check through your values to make sure that the negative signs are correctly placed. This is a common mistake. <br />
#Click “POST TO FILE”. A pop-up window will appear in the center of your screen. Click the “HOME” button in the top left of the pop-up window. Double click the “CNC 101” folder. In the text box to the right of “NAME”, type 1.lastname (with lastname meaning your last name). Then click “SAVE”. <br />
#The operation will automatically load onto your screen. Congratulations, you just wrote the code for you first operation! <br />
Performing your first operation.</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Tormach_CNC_Milling_Machine&diff=197222Tormach CNC Milling Machine2018-01-10T03:37:45Z<p>Cschober: </p>
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! '''Required [[Badge]]''' !! '''Required [[PPE]]'''<br />
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Job Hazard Analysis (JHA) documents, Personal Protective Equipment (PPE) information, and Operator's Manuals can be found in the [[Safety and Manuals]] section.<br />
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This machine is covered under the '''CNC''' training. Users who have not completed this training cannot use this machine.<br />
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CNC:<br />
#When facing with a superfly on aluminum, use 1500 RPM, 9% velocity slider (~10 ipm)<br />
#When performing cuts on a thin sheet of aluminum, stabilize it on either side with 1-2-3 blocks. Also, to reduce chatter, face with an 1/2" endmill using 1500 RPM and 9% velocity slider (~10 ipm)<br />
#When cutting a thin plate of aluminum stock, tools like the 1/2" and the shear hog will induce too much pressure and cause chatter. This can be prevented by performing your adaptive and contour operations with a small bit such as a 3/16".<br />
#Always reference Z first<br />
#Max grip on the vise is 5.3"<br />
#If the safety enclosure is not properly closed, the spindle velocity will drop to 1000 RPM provided the machine is running.<br />
#Because of the tram on the mill, the superfly will face better when cutting from right to left. <br />
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CNC 101: Turning on the mill<br />
#Open the mill enclosure door by sliding the two silver handles apart. Open them to their full capability. <br />
#In the back-right of the mill enclosure, to the right of the Series 3 text, there is a yellow and red power switch. You may need to stick your head in the enclosure to see it. When in the “Off” position, the red switch will be pointed in the 12:00 position. To turn on the power, one needs to rotate the red switch 90 degrees clockwise to the 3:00 position.<br />
#Flipping this switch will cause the computer monitor to boot up. It will take about 30 seconds for the screen to display its various start-up screens before settling into the display screen shown below. Note the flashing red Reset button indicating that the system has not been initiated. <br />
#Whenever the CNC mill is turned off, it must be E-stopped first. E-stop stands for Emergency stop and is the button responsible for cutting power to the machine in case of an emergency. On this CNC mill, the E-stop is the red button to the right of the enclosure doors. To reset the machine, the E-stop needs to be released. Do this by rotating the red button clockwise about 90 degrees. At the 3:00 position, the button will release and spring out. Once this has occurred, press the green button to the right of the E-stop. You should see the enclosure lights flicker as power is returned to the machine. <br />
#On the computer monitor, click the flashing red "reset" button. You should hear an audible click. <br />
#Now that the machine has been reset, the next step is to reference its axes. For this CNC mill in its particular arrangement, there are three axes, the X, Y, and Z. The X and Y axis are in the plane of the ground, with X referring to left-right movement and Y referring to the front-back movement. The Z axis moves the spindle up and down. For the mill to know where it is in space, we need to reference the machine. This occurs by moving the machine as far as is allowed in one direction until it encounters a limit switch. When the mill strikes this limit switch, it knows where the spindle is in relation to the enclosure bed. <br />
#ALWAYS REFERENCE THE Z AXIS FIRST! It is very important to do so because there will never be any obstacles in the positive Z direction. If you had a workpiece loaded into the machine and erroneously chose to reference the X or Y axis first, you could crash the machine. Click the "REF Z" button in the middle of the computer screen. This will cause the machine to travel in the positive Z direction until it encounters the limit switch. Once it stops, notice that the circle to the top right of the “REF Z” button is filled with green. This indicates that the Z-axis has been properly referenced. <br />
#Once the green LED next to “REF Z” is visible, click "REF X" and watch as the machine travels to its X-axis limit switch. <br />
#Once the green LED next to “REF X” is visible, click "REF Y" and watch as the machine travels to its Y-axis limit switch. <br />
#Verify that there are green circles above each of the REF buttons before continuing. Note that there is a forth letter displayed on the screen, “A”. This is used for when the CNC Mill is in its four-axis arrangement. It can be ignored for the purposes of this tutorial. <br />
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Moving the mill <br />
#Now we will get familiar with how to move the CNC mill. To the left of the keyboard, there is a black device known as a jog shuttle. This is the main method of moving the CNC between operations. You’ll notice that each of the four axes are represented on the jog shuttle as buttons. In the middle of your computer display, to the left of the coordinates, notice that there is a green circle to the top right of one of the four axes. By clicking an axis on the jog shuttle, this green circle illuminates in the corresponding axis on the monitor. This is how we know which axis the jog shuttle will move. <br />
#Press the “Y” button on the jog shuttle. Check the computer monitor to verify that a green circle is illuminated to the top-right of the ‘Y” button. <br />
#In the center of the jog shuttle, is a rotatable wheel known as the shuttle ring. One can move the mill along the chosen axis in the positive or negative direction by rotating the shuttle ring clockwise or counterclockwise respectively. As shown on the jog shuttle, clockwise rotation means positive movement, counterclockwise rotation means negative movement. Right now, the Y-axis is at its maximum positive position. Therefore, it can only be moved in the negative direction. Gently rotate the shuttle ring in the counterclockwise direction and then release it. Notice the speed at which the bed adjusts. A more pronounced rotation means faster bed movement. <br />
#Move the mill to its opposite Y-axis limit switch. You can do this rotating the shuttle ring in the counterclockwise direction (either slowly or quickly) until the machine prevents any further movement. <br />
#Travel back and forth between the Y-axis limit switches to get comfortable driving the jog shuttle.<br />
#Once you feel comfortable, we will move to the X-axis between its limit switches. Click the “X” on the jog shuttle and verify that the green circle illuminates on the computer display to the top right of the “X” button. Just like the Y-axis, the mill is at its maximum positive X-axis position. Decide which action is needed to move the mill to its opposite limit switch and perform it. <br />
#Travel back and forth between the X-axis limit switches to understand the mill’s directions and limitations. <br />
#Now we will move the mill along the Z-axis. Unlike the X and Y movement, the mill will not stop you from crashing in the Z direction. Therefore, we need to be careful as we move the Z axis towards the bed. As you can see, there is currently a tool loaded into the mill. We do not want to crash this tool into the vice or bed. <br />
#Press the Z button on the jog shuttle to inform the mill which axis will be moved. Once the green circle next to the “Z” button on the display has been illuminated, cautiously move the mill in the negative Z direction until the tool is roughly 3” above the vice. After this is accomplished, move the mill to its Z-axis positive limit switch. <br />
#There is one other way to move the mill using the jog shuttle. In the center of the jog shuttle is a dimpled circle. This is known as the jog wheel. By rotating the jog wheel, one can move the mill in specific increments. The four possible increments are .0001”, .001”, .01”, .1”. To avoid crashes, we recommend that the step size be .0001”. This allows for precise movement and prevents the machine from lurching into a workpiece when working at close quarters. The step size can be cycled by pressing the “STEP” button on the jog shuttle. As this button is pressed, a green circle will illuminate to the top right of the specific increment on the right of the computer display. Press the “STEP” button until a green circle illuminates to the top-right of the “.0001” button. <br />
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Loading the stock<br />
#For this tutorial, we will be milling a 6” long piece of 2x4 wood stock. We will secure the stock by holding it with the vice. Securing stock while milling is an underappreciated difficulty while working with a CNC mill. <br />
#Ask the Training Ninja to provide you with your piece of wood stock. <br />
#Approach the mill enclosure and inspect the vice that is secured to the mill bed. The vice can be opened or closed by rotating its handle. Counter-clockwise rotation opens the vice and clockwise rotation closes the vice. Open the vice to its full extent.<br />
#Each time stock is to be loaded into the vice, care needs to be taken to wipe the vice clean of chips and debris. Using a rag provided by the training Ninja, comprehensively wipe the inside of the vice clean. <br />
#Place your stock in the vice as shown below. Notice how only a ¼” of the stock just above the vice. It would be very difficult to perform an operation to trim the stock without risking a crash into the vice. Therefore, we will use parallels to raise the height of the stock in the vice. Parallels are thin, flat pieces of metal with parallel sides that come in exact pairs. They are used extensively while working with this CNC mill. <br />
#On the shelf behind the CNC mill, to the left of the wooden structure holding tools, there is a blue box. In it are a set of parallels that range in height from ½” to 1 5/8”. Grab the 7/8” pair from the set (fourth pair). <br />
#Remove your wooden stock from the vice. Place one parallel against the back face of the vice, and one against the front face as shown below. Make sure that the parallels aren’t resting on any chips or debris in the vice. <br />
#Rest your wooden stock on top of the back parallel and close the vice until the wood is sitting on each parallel. Once the wood is in the correct position, place your palm on top of the wood and apply pressure to ensure that the wood is resting flatly on the parallels. Rotate the vice until you feel resistance, then rotate a quarter turn farther to make sure that the stock is secure in the vice. In general, it is better to lean on the side of overtightening as this reduces the chance that your stock will loosen while milling. However, in the case of softer materials such as wood or aluminum, overtightening can cause deformation and decreased accuracy. <br />
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Changing the tool<br />
#The tool currently loaded into the spindle is a ½” flat end mill. For this mill, individual tool numbers are assigned to each tool so that they can be referenced by the machine and other computer programs. This is tool number 11. You will notice that the tools for this mill are kept in the wooden structure on the shelf behind the mill. Each tool position is labeled with its classification, and each tool is labeled with its number. For our purposes, we will swap Tool 1, the Offset Tool, into the spindle. <br />
#Remove Tool 1 from the tool-holding structure and place it on the bench across from the CNC mill. <br />
#The current tool is removed from the spindle by accessing the motor cover. On the right side of the motor cover, there is a black clasp that secures the door. Undo this clasp by lifting the near side with your thumb and using your middle finger to pull the clasp free. Swing the door open once the clasp has been released. <br />
#Once the door has been opened, you can see the drawbar. This is connected to the spindle and translates the rotation of the belts to the tool. Notice how spinning the drawbar spins the tool. In order to loosen the tool, we will need to prevent the rotation of the spindle. Spin the drawbar until the flat side of its mounting cylinder is parallel to the enclosure doors. This will allow the spindle lock to engage. Pivot the black spindle lock from its resting position onto the drawbar mount to prevent spindle rotation. <br />
#Take the golden-headed hammer from beside the keyboard. It’s cavernous side fits onto the top of the drawbar and is used to loosen it from the spindle. Keep a hold of the tool as you loosen the spindle! When the spindle is fully loosened the tool could drop, damaging the tool or your stock. <br />
#Push the handle of the hammer in the counterclockwise direction while holding onto the tool. After rotating it ¼” turn, reposition the hammer and perform another ¼ turn. This should sufficiently loosen the tool in the spindle. Flip the hammer and use the gold side to rap the top of the drawbar WHILE HOLDING THE TOOL. The tool should release into your hand. Take Tool 11 and place it in its designated toolholding spot. <br />
#Now we will place Tool 1 into the spindle. With your left hand, press Tool 1 firmly into the spindle and hold it there as you rotate the drawbar clockwise with the hammer. Perform two ¼ turns and lean on the side of overtightening in this case. <br />
#Once Tool 1 is secured, release the spindle lock by pivoting it back into its vertical resting position. Then, swing the motor cover closed and secure its black clasp.<br />
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Referencing the stock<br />
# As mentioned previously, each tool in the tool library is assigned a designated number. This is important because each tool has a different length when measured from top to bottom. In the computer, the height of each tool is recorded so that the mill can perfectly know the coordinate of the tool tip. Each time there is a tool change, it is vitally important to tell the mill this information. NOT UPDATING YOUR TOOL NUMBER CAUSES THE MAJORITY OF CRASHES. <br />
#In the bottom-right corner of the screen, there is a text box to the right of a “T”. The number displayed in this text box is the tool that the mill thinks it is equipped with. Currently, the text box should display “0” because the mill was just reset and didn’t retain this information. To update this, highlight the “0”, type “1” since we just equipped Tool 1, and HIT ENTER on the keyboard. Notice that the Z coordinate text box updated to reflect the height of the new tool. <br />
#Now, we want to inform the machine the coordinates of our stock. To do this, we will use the offset tool to “touch off” on the stock. <br />
#Use the jog shuttle to move the X and Y axis so that the offset tool is roughly centered over the stock. <br />
#Carefully lower the offset tool in the negative Z direction until the top of the tool is about 2” above the stock top. Re-center the stock in the X and Y direction if necessary. <br />
#Above the keyboard is a clear piece of plastic known as a feeler gauge. This piece of plastic is 0.0094” thick. To reference the stock, place this gauge between the stock and the offset tool. We will slowly lower the offset tool until it is exactly the width of the plastic distance away from the stock. <br />
#Begin SLOWLY lowering the offset tool in the Z direction while performing a sawing motion with the gauge. The idea is that as soon as you can no longer easily move the gauge back and forth, the offset tool is the width of the gauge (0.0094”) away from the top of the stock. Be careful not to crash the tool by moving too quickly. As you begin to feel slight resistance, it is useful to use the jog wheel to make fine increments. Before you do, check to make sure that the step size is “.0001”. <br />
#Adjust the height until you can barely move the gauge back and forth.<br />
#Highlight the text box to the right of the “Z” button. Type “.0094” and HIT ENTER on your keyboard. The mill now correctly thinks it is positioned .0094” above the top of the stock. <br />
#Raise the Z height until the Z-coordinate value is exactly 0.5000. This is a good chance to practice using the jog wheel to make precision adjustments. <br />
#Now, we want to reference the X and Y axes. In almost all instances, we want to set X and Y equal to zero at the exact center of the stock. To achieve this, we will use a trick to find the total length and width of the part and then divide that value by two. <br />
#Drive the offset tool to the left of the stock until the metal cylinder can lower without crashing into the stock.<br />
#Lower the Z height until the coordinate value is -0.2500. <br />
#Now, we will perform the same gauge sawing action as we did when referencing the Z height. Move the tool in the positive X direction while sawing the gauge back and forth. Adjust until you can barely move the gauge back and forth. <br />
#In this tutorial, we will simplify the math involved in this process. Typically, we would want to set the left side of the stock face equal to zero, measure the coordinate at the right face of the stock, and know the exact length of our stock. For our purposes, we can get away with setting this exact point as zero, and repeating the same procedure on the other side. If both measurements are consistent in their positions relative to the stock face, the center of each method will be the same. Highlight the text box to the right of the “X” button, type “0”, and HIT ENTER on the keyboard. <br />
#Now, we will move the offset tool over to the right face of the stock. Move in the negative X direction until the X-coordinate is -0.1000. Raise the Z height of the tool until the value is 0.5000. Whenever you plan to travel over the top of a stock, take care to ensure that the tool tip is at least ½” above the stock top. Travel in the positive X direction until the offset tool can be lowered without crashing into the stock. Lower the Z height of the tool to -0.2500. <br />
#Hold the gauge in between the stock and the tool. Perform a sawing action with the gauge while simultaneously moving the tool in the negative X direction. Adjust until you can barely move the gauge back and forth. <br />
#Now, the center of the stock is exactly in the middle of these two points. Since we set the left face to be zero, all we need to do is divide the current coordinate by two. The machine makes this easy, as it can perform simple mathematical operations. Highlight the text box to the right of the “X” button, type “/2”, and HIT ENTER on the keyboard. The X=0 coordinate is now directly in the center of your stock. <br />
#Now, we will perform the same operation to reference the Y axis. There are no instructions for this portion of the tutorial as it is important to practice this type of problem solving on your own. However, the training Ninja is available to answer any questions you have. <br />
#Once all axes have been referenced, move the mill to the X=0”, Y=0”, Z=0.1” position. The tool should appear to be directly in the center of the stock, and .1” above the stock face. If this is not the case, consult your training Ninja to determine where the error occurred. If the tool looks centered, the stock is completely referenced! Raise the tool to the positive Z limit switch. <br />
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Setting up your first operation<br />
#Now that the stock has been referenced, it’s time for the fun part! On the computer monitor, in the center of the screen, click on the tab labeled “Conversational”. This is one of the ways that we can write operations for the mill to perform. <br />
#At the top of the screen, click the tab labeled “Face”. A facing operation cuts away the top part of the stock. It is almost always the precursor to any other milling operation, and is used to flatten and smooth the top surface. <br />
#There is a lot of information to cover in this section and so each text box on the screen will be broken down and explained individually. <br />
#The “Title” box is arbitrary and usually we don’t bother to change the text (you can save the file as a custom name later). <br />
#The “Work Offset” box should be filled as “G54”. The mill has several work coordinate offsets that can be used and all of the information in its current arrangement is stored in G54. <br />
#The “Tool” box should be filled with “3”. Tool 3 is known as the shear hog and is our go-to tool for removing large amounts of material. We will be using this tool to face the stock. <br />
#The “Spindle RPM” box should be filled with “6000”. This value tells the tool how fast to spin while cutting through the material. The spin rates of each tool can be explained in-depth outside of this tutorial. Presently, all you need to know is the rotation per minute (RPM) values for each tool which will be provided.<br />
# The “Feedrate” box should be filled with “40.0”. This value tells the tool how fast to move while cutting through the material. The unit for this value is inches per minute (IPM).</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Tormach_CNC_Milling_Machine&diff=197221Tormach CNC Milling Machine2018-01-09T21:39:59Z<p>Cschober: </p>
<hr />
<div>{| class="wikitable" style="text-align:center"<br />
|-<br />
! '''Required [[Badge]]''' !! '''Required [[PPE]]'''<br />
|-<br />
| [[File: CNC.png|100px]] || [[File: Safety_Eye.png|100px]] || [[File: Safety_Pants.png|100px]] || [[File: Safety_Hair.png|100px]] || [[File: Safety_Shoes.png|100px]] || [[File: Safety_Jewelry.png|100px]]<br />
|-<br />
|}<br />
<br />
Job Hazard Analysis (JHA) documents, Personal Protective Equipment (PPE) information, and Operator's Manuals can be found in the [[Safety and Manuals]] section.<br />
<br />
This machine is covered under the '''CNC''' training. Users who have not completed this training cannot use this machine.<br />
<br />
CNC:<br />
#When facing with a superfly on aluminum, use 1500 RPM, 9% velocity slider (~10 ipm)<br />
#When performing cuts on a thin sheet of aluminum, stabilize it on either side with 1-2-3 blocks. Also, to reduce chatter, face with an 1/2" endmill using 1500 RPM and 9% velocity slider (~10 ipm)<br />
#When cutting a thin plate of aluminum stock, tools like the 1/2" and the shear hog will induce too much pressure and cause chatter. This can be prevented by performing your adaptive and contour operations with a small bit such as a 3/16".<br />
#Always reference Z first<br />
#Max grip on the vise is 5.3"<br />
#If the safety enclosure is not properly closed, the spindle velocity will drop to 1000 RPM provided the machine is running.<br />
#Because of the tram on the mill, the superfly will face better when cutting from right to left. <br />
<br />
CNC 101: Turning on the mill<br />
#Open the mill enclosure door by sliding the two silver handles apart. Open them to their full capability. <br />
#In the back-right of the mill enclosure, to the right of the Series 3 text, there is a yellow and red power switch. You may need to stick your head in the enclosure to see it. When in the “Off” position, the red switch will be pointed in the 12:00 position. To turn on the power, one needs to rotate the red switch 90 degrees clockwise to the 3:00 position.<br />
#Flipping this switch will cause the computer monitor to boot up. It will take about 30 seconds for the screen to display its various start-up screens before settling into the display screen shown below. Note the flashing red Reset button indicating that the system has not been initiated. <br />
#Whenever the CNC mill is turned off, it must be E-stopped first. E-stop stands for Emergency stop and is the button responsible for cutting power to the machine in case of an emergency. On this CNC mill, the E-stop is the red button to the right of the enclosure doors. To reset the machine, the E-stop needs to be released. Do this by rotating the red button clockwise about 90 degrees. At the 3:00 position, the button will release and spring out. Once this has occurred, press the green button to the right of the E-stop. You should see the enclosure lights flicker as power is returned to the machine. <br />
#On the computer monitor, click the flashing red "reset" button. You should hear an audible click. <br />
#Now that the machine has been reset, the next step is to reference its axes. For this CNC mill in its particular arrangement, there are three axes, the X, Y, and Z. The X and Y axis are in the plane of the ground, with X referring to left-right movement and Y referring to the front-back movement. The Z axis moves the spindle up and down. For the mill to know where it is in space, we need to reference the machine. This occurs by moving the machine as far as is allowed in one direction until it encounters a limit switch. When the mill strikes this limit switch, it knows where the spindle is in relation to the enclosure bed. <br />
#ALWAYS REFERENCE THE Z AXIS FIRST! It is very important to do so because there will never be any obstacles in the positive Z direction. If you had a workpiece loaded into the machine and erroneously chose to reference the X or Y axis first, you could crash the machine. Click the "REF Z" button in the middle of the computer screen. This will cause the machine to travel in the positive Z direction until it encounters the limit switch. Once it stops, notice that the circle to the top right of the “REF Z” button is filled with green. This indicates that the Z-axis has been properly referenced. <br />
#Once the green LED next to “REF Z” is visible, click "REF X" and watch as the machine travels to its X-axis limit switch. <br />
#Once the green LED next to “REF X” is visible, click "REF Y" and watch as the machine travels to its Y-axis limit switch. <br />
#Verify that there are green circles above each of the REF buttons before continuing. Note that there is a forth letter displayed on the screen, “A”. This is used for when the CNC Mill is in its four-axis arrangement. It can be ignored for the purposes of this tutorial. <br />
<br />
<br />
Moving the mill <br />
#Now we will get familiar with how to move the CNC mill. To the left of the keyboard, there is a black device known as a jog shuttle. This is the main method of moving the CNC between operations. You’ll notice that each of the four axes are represented on the jog shuttle as buttons. In the middle of your computer display, to the left of the coordinates, notice that there is a green circle to the top right of one of the four axes. By clicking an axis on the jog shuttle, this green circle illuminates in the corresponding axis on the monitor. This is how we know which axis the jog shuttle will move. <br />
#Press the “Y” button on the jog shuttle. Check the computer monitor to verify that a green circle is illuminated to the top-right of the ‘Y” button. <br />
#In the center of the jog shuttle, is a rotatable wheel known as the shuttle ring. One can move the mill along the chosen axis in the positive or negative direction by rotating the shuttle ring clockwise or counterclockwise respectively. As shown on the jog shuttle, clockwise rotation means positive movement, counterclockwise rotation means negative movement. Right now, the Y-axis is at its maximum positive position. Therefore, it can only be moved in the negative direction. Gently rotate the shuttle ring in the counterclockwise direction and then release it. Notice the speed at which the bed adjusts. A more pronounced rotation means faster bed movement. <br />
#Move the mill to its opposite Y-axis limit switch. You can do this rotating the shuttle ring in the counterclockwise direction (either slowly or quickly) until the machine prevents any further movement. <br />
#Travel back and forth between the Y-axis limit switches to get comfortable driving the jog shuttle.<br />
#Once you feel comfortable, we will move to the X-axis between its limit switches. Click the “X” on the jog shuttle and verify that the green circle illuminates on the computer display to the top right of the “X” button. Just like the Y-axis, the mill is at its maximum positive X-axis position. Decide which action is needed to move the mill to its opposite limit switch and perform it. <br />
#Travel back and forth between the X-axis limit switches to understand the mill’s directions and limitations. <br />
#Now we will move the mill along the Z-axis. Unlike the X and Y movement, the mill will not stop you from crashing in the Z direction. Therefore, we need to be careful as we move the Z axis towards the bed. As you can see, there is currently a tool loaded into the mill. We do not want to crash this tool into the vice or bed. <br />
#Press the Z button on the jog shuttle to inform the mill which axis will be moved. Once the green circle next to the “Z” button on the display has been illuminated, cautiously move the mill in the negative Z direction until the tool is roughly 3” above the vice. After this is accomplished, move the mill to its Z-axis positive limit switch. <br />
#There is one other way to move the mill using the jog shuttle. In the center of the jog shuttle is a dimpled circle. This is known as the jog wheel. By rotating the jog wheel, one can move the mill in specific increments. The four possible increments are .0001”, .001”, .01”, .1”. To avoid crashes, we recommend that the step size be .0001”. This allows for precise movement and prevents the machine from lurching into a workpiece when working at close quarters. The step size can be cycled by pressing the “STEP” button on the jog shuttle. As this button is pressed, a green circle will illuminate to the top right of the specific increment on the right of the computer display. Press the “STEP” button until a green circle illuminates to the top-right of the “.0001” button. <br />
<br />
<br />
<br />
<br />
<br />
<br />
Loading the stock<br />
#For this tutorial, we will be milling a 6” long piece of 2x4 wood stock. We will secure the stock by holding it with the vice. Securing stock while milling is an underappreciated difficulty while working with a CNC mill. <br />
#Ask the Training Ninja to provide you with your piece of wood stock. <br />
#Approach the mill enclosure and inspect the vice that is secured to the mill bed. The vice can be opened or closed by rotating its handle. Counter-clockwise rotation opens the vice and clockwise rotation closes the vice. Open the vice to its full extent.<br />
#Each time stock is to be loaded into the vice, care needs to be taken to wipe the vice clean of chips and debris. Using a rag provided by the training Ninja, comprehensively wipe the inside of the vice clean. <br />
#Place your stock in the vice as shown below. Notice how only a ¼” of the stock just above the vice. It would be very difficult to perform an operation to trim the stock without risking a crash into the vice. Therefore, we will use parallels to raise the height of the stock in the vice. Parallels are thin, flat pieces of metal with parallel sides that come in exact pairs. They are used extensively while working with this CNC mill. <br />
#On the shelf behind the CNC mill, to the left of the wooden structure holding tools, there is a blue box. In it are a set of parallels that range in height from ½” to 1 5/8”. Grab the 7/8” pair from the set (fourth pair). <br />
#Remove your wooden stock from the vice. Place one parallel against the back face of the vice, and one against the front face as shown below. Make sure that the parallels aren’t resting on any chips or debris in the vice. <br />
#Rest your wooden stock on top of the back parallel and close the vice until the wood is sitting on each parallel. Once the wood is in the correct position, place your palm on top of the wood and apply pressure to ensure that the wood is resting flatly on the parallels. Rotate the vice until you feel resistance, then rotate a quarter turn farther to make sure that the stock is secure in the vice. In general, it is better to lean on the side of overtightening as this reduces the chance that your stock will loosen while milling. However, in the case of softer materials such as wood or aluminum, overtightening can cause deformation and decreased accuracy. <br />
<br />
Changing the tool<br />
#The tool currently loaded into the spindle is a ½” flat end mill. For this mill, individual tool numbers are assigned to each tool so that they can be referenced by the machine and other computer programs. This is tool number 11. You will notice that the tools for this mill are kept in the wooden structure on the shelf behind the mill. Each tool position is labeled with its classification, and each tool is labeled with its number. For our purposes, we will swap Tool 1, the Offset Tool, into the spindle. <br />
#Remove Tool 1 from the tool-holding structure and place it on the bench across from the CNC mill. <br />
#The current tool is removed from the spindle by accessing the motor cover. On the right side of the motor cover, there is a black clasp that secures the door. Undo this clasp by lifting the near side with your thumb and using your middle finger to pull the clasp free. Swing the door open once the clasp has been released. <br />
#Once the door has been opened, you can see the drawbar. This is connected to the spindle and translates the rotation of the belts to the tool. Notice how spinning the drawbar spins the tool. In order to loosen the tool, we will need to prevent the rotation of the spindle. Spin the drawbar until the flat side of its mounting cylinder is parallel to the enclosure doors. This will allow the spindle lock to engage. Pivot the black spindle lock from its resting position onto the drawbar mount to prevent spindle rotation. <br />
#Take the golden-headed hammer from beside the keyboard. It’s cavernous side fits onto the top of the drawbar and is used to loosen it from the spindle. Keep a hold of the tool as you loosen the spindle! When the spindle is fully loosened the tool could drop, damaging the tool or your stock. <br />
#Push the handle of the hammer in the counterclockwise direction while holding onto the tool. After rotating it ¼” turn, reposition the hammer and perform another ¼ turn. This should sufficiently loosen the tool in the spindle. Flip the hammer and use the gold side to rap the top of the drawbar WHILE HOLDING THE TOOL. The tool should release into your hand. Take Tool 11 and place it in its designated toolholding spot. <br />
#Now we will place Tool 1 into the spindle. With your left hand, press Tool 1 firmly into the spindle and hold it there as you rotate the drawbar clockwise with the hammer. Perform two ¼ turns and lean on the side of overtightening in this case. <br />
#Once Tool 1 is secured, release the spindle lock by pivoting it back into its vertical resting position. Then, swing the motor cover closed and secure its black clasp.</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Making_a_Tabbed_Box_using_the_Laser_Cutter&diff=197172Making a Tabbed Box using the Laser Cutter2017-11-27T23:32:35Z<p>Cschober: </p>
<hr />
<div>[[File:Canister3.JPG|200px|right]]<br />
The tabbed box is one of the simplest and most useful things to design for the [[Laser Cutting|laser cutter]]. There are several online applications that will take your input and allow you to download an [[vector graphics|.svg]] file that can be incorporated into [[Inkscape]], [[CorelDraw]], or [[Adobe Illustrator|Illustrator]]. In my view, using an [[Inkscape Extensions|Inkscape extension]] is by far the easiest way to design your box and make adjustments right in Inkscape itself.<br />
<br />
[[File:BoxMaker.png|left]]<br />
<br />
:1. Download the BoxMaker Extension for Inkscape ([http://www.inkscapeforum.com/viewtopic.php?t=18315 BoxMaker0.91.zip]).<br />
:2. Open the .zip file and copy the files “boxmaker.inx” and “boxmaker.py” into your Inkscape extensions folder (usually \Program Files\Inkscape\share\extensions\”).<br />
:3. Restart Inkscape, then click on the “Extensions” menu and highlight the heading “Laser Tools”.<br />
:4. Select “Tabbed Box Maker”, a pop-up menu will appear asking for the properties of the box you would like to design.<br />
::::::::::::::a. Select your measurement units.<br />
::::::::::::::b. Inside/Outside refers to whether your measurement dimensions are for the inside of the box or the outside.<br />
::::::::::::::c. Enter your dimensions and preferred tab width (note, if you select a tab width too big or too small for the box dimensions, the extension will give you an error message.)<br />
::::::::::::::d. Enter the thickness of the material you are going to make the box out of.<br />
::::::::::::::e. The kerf for a laser cutter can be kept at zero.<br />
:5. Click “Apply”, then close the extension. Your box parts should be in your open Inkscape screen ready for further editing.<br />
:6. Remember to set the line widths to 0.001” to make sure that they cut instead of etch.<br />
[[User:Tschule|Timothy M. Schuler, Ph.D.]] ([[User talk:Tschule|talk]])<br />
<br />
<br />
Also a good option is this website which allows you to download laser cut plans for a box through user inputs:<br />
http://www.makercase.com/</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197072Chase Schober2017-10-22T17:37:17Z<p>Cschober: </p>
<hr />
<div> [[File:Chase Tormach.jpg|600px]] [[File:Chase_1.jpg|400px]] <br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (985) 326-1792<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|500px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
'''Tulane University Femtosecond & Terahertz Spectroscopy Laboratory'''<br />
<br />
[[File:Schober Jimmy 1.jpeg|350px]]<br />
[[File:Chase Jimmy 2.jpeg|350px]]<br />
[[File:Chase Jimmy 3.jpeg|350px]]<br />
<br />
<br />
'''Tulane University Reed Macromolecular Research Group:'''<br />
<br />
I was approached by a graduate student in Professor Reed's lab and asked to manufacture specialized aluminum cuvette caps. Proteins in solution (intended for pharmaceutical development) tend to adsorb to the walls of the cuvette or to the stir bar and aggregate upon agitation. These caps allow the researchers to suspend a stir bar above the bottom of the cuvette to remove the solid-solid interfacial contact while monitoring aggregation caused by agitation via light scattering. We milled nine caps out of a .75" of aluminum plate and hit our tolerance of ± .002". <br />
<br />
[[File:Chase Reed 2.jpeg|Center|400px]] [[File:Chase Reed 1.jpeg|600px]]<br />
<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
<br />
A large portion of my recent work on the lathe has been to compile a comprehensive training document. In this 37-page step-by-step manual, I thoroughly explain the operations of the lathe through detailed diagrams and user instruction. By the end of the training, the user will have made the widget shown below out of 1" aluminum stock using the Conversational mode of the Tormach lathe. <br />
<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''<br />
<br />
[[File:Lathe Training Part.jpeg|500px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197071Chase Schober2017-10-22T17:32:00Z<p>Cschober: </p>
<hr />
<div> [[File:Chase Tormach.jpg|600px]] [[File:Chase_1.jpg|400px]] <br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (985) 326-1792<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|500px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
'''Tulane University Femtosecond & Terahertz Spectroscopy Laboratory'''<br />
<br />
[[File:Schober Jimmy 1.jpeg|350px]]<br />
[[File:Chase Jimmy 2.jpeg|350px]]<br />
[[File:Chase Jimmy 3.jpeg|350px]]<br />
<br />
<br />
'''Tulane University Reed Macromolecular Research Group:'''<br />
<br />
I was approached by a graduate student in Professor Reed's lab and asked to manufacture specialized aluminum cuvette caps. Proteins in solution (intended for pharmaceutical development) tend to adsorb to the walls of the cuvette or to the stir bar and aggregate upon agitation. These caps allow the researchers to suspend a stir bar above the bottom of the cuvette to remove the solid-solid interfacial contact while monitoring aggregation caused by agitation via light scattering. We milled nine caps out of a .75" of aluminum plate and hit our tolerance of ± .002". <br />
<br />
[[File:Chase Reed 2.jpeg|Center|400px]] [[File:Chase Reed 1.jpeg|600px]]<br />
<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''<br />
<br />
[[File:Lathe Training Part.jpeg|500px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197058Chase Schober2017-10-11T21:20:41Z<p>Cschober: </p>
<hr />
<div> [[File:Chase Tormach.jpg|600px]] [[File:Chase_1.jpg|400px]] <br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|500px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
'''Tulane University Femtosecond & Terahertz Spectroscopy Laboratory'''<br />
<br />
[[File:Schober Jimmy 1.jpeg|350px]]<br />
[[File:Chase Jimmy 2.jpeg|350px]]<br />
[[File:Chase Jimmy 3.jpeg|350px]]<br />
<br />
<br />
'''Tulane University Reed Macromolecular Research Group:'''<br />
<br />
I was approached by a graduate student in Professor Reed's lab and asked to manufacture specialized aluminum cuvette caps. Proteins in solution (intended for pharmaceutical development) tend to adsorb to the walls of the cuvette or to the stir bar and aggregate upon agitation. These caps allow the researchers to suspend a stir bar above the bottom of the cuvette to remove the solid-solid interfacial contact while monitoring aggregation caused by agitation via light scattering. We milled nine caps out of a .75" of aluminum plate and hit our tolerance of ± .002". <br />
<br />
[[File:Chase Reed 2.jpeg|Center|400px]] [[File:Chase Reed 1.jpeg|600px]]<br />
<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''<br />
<br />
[[File:Lathe Training Part.jpeg|500px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=File:Lathe_Training_Part.jpeg&diff=197057File:Lathe Training Part.jpeg2017-10-11T21:20:04Z<p>Cschober: </p>
<hr />
<div></div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197056Chase Schober2017-10-11T01:40:00Z<p>Cschober: </p>
<hr />
<div> [[File:Chase Tormach.jpg|600px]] [[File:Chase_1.jpg|400px]] <br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|500px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
'''Tulane University Femtosecond & Terahertz Spectroscopy Laboratory'''<br />
<br />
[[File:Schober Jimmy 1.jpeg|350px]]<br />
[[File:Chase Jimmy 2.jpeg|350px]]<br />
[[File:Chase Jimmy 3.jpeg|350px]]<br />
<br />
<br />
'''Tulane University Reed Macromolecular Research Group:'''<br />
<br />
I was approached by a graduate student in Professor Reed's lab and asked to manufacture specialized aluminum cuvette caps. Proteins in solution (intended for pharmaceutical development) tend to adsorb to the walls of the cuvette or to the stir bar and aggregate upon agitation. These caps allow the researchers to suspend a stir bar above the bottom of the cuvette to remove the solid-solid interfacial contact while monitoring aggregation caused by agitation via light scattering. We milled nine caps out of a .75" of aluminum plate and hit our tolerance of ± .002". <br />
<br />
[[File:Chase Reed 2.jpeg|Center|400px]] [[File:Chase Reed 1.jpeg|600px]]<br />
<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197055Chase Schober2017-10-11T01:39:18Z<p>Cschober: </p>
<hr />
<div> [[File:Chase Tormach.jpg|600px]] [[File:Chase_1.jpg|400px]] <br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
'''Tulane University Femtosecond & Terahertz Spectroscopy Laboratory'''<br />
<br />
[[File:Schober Jimmy 1.jpeg|350px]]<br />
[[File:Chase Jimmy 2.jpeg|350px]]<br />
[[File:Chase Jimmy 3.jpeg|350px]]<br />
<br />
<br />
'''Tulane University Reed Macromolecular Research Group:'''<br />
<br />
I was approached by a graduate student in Professor Reed's lab and asked to manufacture specialized aluminum cuvette caps. Proteins in solution (intended for pharmaceutical development) tend to adsorb to the walls of the cuvette or to the stir bar and aggregate upon agitation. These caps allow the researchers to suspend a stir bar above the bottom of the cuvette to remove the solid-solid interfacial contact while monitoring aggregation caused by agitation via light scattering. We milled nine caps out of a .75" of aluminum plate and hit our tolerance of ± .002". <br />
<br />
[[File:Chase Reed 2.jpeg|Center|400px]] [[File:Chase Reed 1.jpeg|600px]]<br />
<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197054Chase Schober2017-10-11T01:39:00Z<p>Cschober: </p>
<hr />
<div> [[File:Chase Tormach.jpg|600px]] [[File:Chase_1.jpg|400px]] <br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
'''Tulane University Femtosecond & Terahertz Spectroscopy Laboratory'''<br />
<br />
[[File:Schober Jimmy 1.jpeg|350px]]<br />
[[File:Chase Jimmy 2.jpeg|350px]]<br />
[[File:Chase Jimmy 3.jpeg|350px]]<br />
<br />
<br />
'''Tulane University Reed Macromolecular Research Group:'''<br />
<br />
I was approached by a graduate student in Professor Reed's lab and asked to manufacture specialized aluminum cuvette caps. Proteins in solution (intended for pharmaceutical development) tend to adsorb to the walls of the cuvette or to the stir bar and aggregate upon agitation. These caps allow the researchers to suspend a stir bar above the bottom of the cuvette to remove the solid-solid interfacial contact while monitoring aggregation caused by agitation via light scattering. We milled nine caps out of a .75" of aluminum plate and hit our tolerance of ± .002". <br />
<br />
[[File:Chase Reed 2.jpeg|Center|400px]] [[File:Chase Reed 1.jpeg|600px]]<br />
<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197053Chase Schober2017-10-11T01:38:17Z<p>Cschober: </p>
<hr />
<div> [[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
'''Tulane University Femtosecond & Terahertz Spectroscopy Laboratory'''<br />
<br />
[[File:Schober Jimmy 1.jpeg|350px]]<br />
[[File:Chase Jimmy 2.jpeg|350px]]<br />
[[File:Chase Jimmy 3.jpeg|350px]]<br />
<br />
<br />
'''Tulane University Reed Macromolecular Research Group:'''<br />
<br />
I was approached by a graduate student in Professor Reed's lab and asked to manufacture specialized aluminum cuvette caps. Proteins in solution (intended for pharmaceutical development) tend to adsorb to the walls of the cuvette or to the stir bar and aggregate upon agitation. These caps allow the researchers to suspend a stir bar above the bottom of the cuvette to remove the solid-solid interfacial contact while monitoring aggregation caused by agitation via light scattering. We milled nine caps out of a .75" of aluminum plate and hit our tolerance of ± .002". <br />
<br />
[[File:Chase Reed 2.jpeg|Center|400px]] [[File:Chase Reed 1.jpeg|600px]]<br />
<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197052Chase Schober2017-10-11T01:34:40Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
'''Tulane University Femtosecond & Terahertz Spectroscopy Laboratory'''<br />
<br />
[[File:Schober Jimmy 1.jpeg|350px]]<br />
[[File:Chase Jimmy 2.jpeg|350px]]<br />
[[File:Chase Jimmy 3.jpeg|350px]]<br />
<br />
<br />
'''Tulane University Reed Macromolecular Research Group:'''<br />
<br />
I was approached by a graduate student in Professor Reed's lab and asked to manufacture specialized aluminum cuvette caps. Proteins in solution (intended for pharmaceutical development) tend to adsorb to the walls of the cuvette or to the stir bar and aggregate upon agitation. These caps allow the researchers to suspend a stir bar above the bottom of the cuvette to remove the solid-solid interfacial contact while monitoring aggregation caused by agitation via light scattering. We milled nine caps out of a .75" of aluminum plate and hit our tolerance of ± .002". <br />
<br />
[[File:Chase Reed 2.jpeg|Center|400px]] [[File:Chase Reed 1.jpeg|600px]]<br />
<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197051Chase Schober2017-10-11T01:33:10Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
'''Tulane University Femtosecond & Terahertz Spectroscopy Laboratory'''<br />
<br />
[[File:Schober Jimmy 1.jpeg|350px]]<br />
[[File:Chase Jimmy 2.jpeg|350px]]<br />
[[File:Chase Jimmy 3.jpeg|350px]]<br />
<br />
<br />
'''Tulane University Reed Macromolecular Research Group:'''<br />
<br />
I was approached by a graduate student in Professor Reed's lab and asked to manufacture specialized aluminum cuvette caps. Proteins in solution (intended for pharmaceutical development) tend to adsorb to the walls of the cuvette or to the stir bar and aggregate upon agitation. These caps allow the researchers to suspend a stir bar above the bottom of the cuvette to remove the solid-solid interfacial contact while monitoring aggregation caused by agitation via light scattering. We milled nine caps out of a .75" of aluminum plate and hit our tolerance of ± .002". <br />
<br />
[[File:Chase Reed 2.jpeg|Center|400px]] [[File:Chase Reed 1.jpeg|600px]]<br />
<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197050Chase Schober2017-10-11T01:31:56Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
[[File:Schober Jimmy 1.jpeg|500px]]<br />
[[File:Chase Jimmy 2.jpeg|500px]]<br />
[[File:Chase Jimmy 3.jpeg|500px]]<br />
<br />
<br />
'''Tulane University Reed Macromolecular Research Group:'''<br />
<br />
I was approached by a graduate student in Professor Reed's lab and asked to manufacture specialized aluminum cuvette caps. Proteins in solution (intended for pharmaceutical development) tend to adsorb to the walls of the cuvette or to the stir bar and aggregate upon agitation. These caps allow the researchers to suspend a stir bar above the bottom of the cuvette to remove the solid-solid interfacial contact while monitoring aggregation caused by agitation via light scattering. We milled nine caps out of a .75" of aluminum plate and hit our tolerance of ± .002". <br />
<br />
[[File:Chase Reed 2.jpeg|Center|400px]] [[File:Chase Reed 1.jpeg|600px]]<br />
<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197049Chase Schober2017-10-11T01:31:06Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
[[File:Schober Jimmy 1.jpeg|500px]]<br />
[[File:Chase Jimmy 2.jpeg|500px]]<br />
[[File:Chase Jimmy 3.jpeg|500px]]<br />
<br />
<br />
'''Tulane University Reed Macromolecular Research Group:'''<br />
<br />
I was approached by a graduate student in Professor Reed's lab and asked to manufacture specialized aluminum cuvette caps. Proteins in solution (intended for pharmaceutical development) tend to adsorb to the walls of the cuvette or to the stir bar and aggregate upon agitation. These caps allow the researchers to suspend a stir bar above the bottom of the cuvette to remove the solid-solid interfacial contact while monitoring aggregation caused by agitation via light scattering. We milled nine caps out of a .75" of aluminum plate and hit our tolerance of ± .002". <br />
<br />
[[File:Chase Reed 2.jpeg|400px]] [[File:Chase Reed 1.jpeg|600px]]<br />
<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197048Chase Schober2017-10-11T01:30:11Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
[[File:Schober Jimmy 1.jpeg|500px]]<br />
[[File:Chase Jimmy 2.jpeg|500px]]<br />
[[File:Chase Jimmy 3.jpeg|500px]]<br />
<br />
<br />
'''Tulane University Reed Macromolecular Research Group:'''<br />
<br />
I was approached by a graduate student in Professor Reed's lab and asked to manufacture specialized aluminum cuvette caps. Proteins in solution (intended for pharmaceutical development) tend to adsorb to the walls of the cuvette or to the stir bar and aggregate upon agitation. These caps allow the researchers to suspend a stir bar above the bottom of the cuvette to remove the solid-solid interfacial contact while monitoring aggregation caused by agitation via light scattering. We milled nine caps out of a .75" of aluminum plate and hit our tolerance of ± .002". <br />
<br />
[[File:Chase Reed 2.jpeg|500px]]<br />
[[File:Chase Reed 1.jpeg|500px]]<br />
<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197047Chase Schober2017-10-11T01:22:22Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
[[File:Schober Jimmy 1.jpeg|500px]]<br />
[[File:Chase Jimmy 2.jpeg|500px]]<br />
[[File:Chase Jimmy 3.jpeg|500px]]<br />
<br />
<br />
<br />
<br />
[[File:Chase Reed 1.jpeg|500px]]<br />
[[File:Chase Reed 2.jpeg|500px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=File:Chase_Reed_2.jpeg&diff=197046File:Chase Reed 2.jpeg2017-10-11T01:21:54Z<p>Cschober: </p>
<hr />
<div></div>Cschoberhttp://makerspace.tulane.edu/index.php?title=File:Chase_Reed_1.jpeg&diff=197045File:Chase Reed 1.jpeg2017-10-11T01:21:08Z<p>Cschober: </p>
<hr />
<div></div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197044Chase Schober2017-10-11T01:16:19Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
[[File:Schober Jimmy 1.jpeg|500px]]<br />
[[File:Chase Jimmy 2.jpeg|500px]]<br />
[[File:Chase Jimmy 3.jpeg|500px]]<br />
<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=File:Chase_Jimmy_3.jpeg&diff=197043File:Chase Jimmy 3.jpeg2017-10-11T01:15:31Z<p>Cschober: </p>
<hr />
<div></div>Cschoberhttp://makerspace.tulane.edu/index.php?title=File:Chase_Jimmy_2.jpeg&diff=197042File:Chase Jimmy 2.jpeg2017-10-11T01:14:55Z<p>Cschober: </p>
<hr />
<div></div>Cschoberhttp://makerspace.tulane.edu/index.php?title=File:Schober_Jimmy_1.jpeg&diff=197041File:Schober Jimmy 1.jpeg2017-10-11T01:13:52Z<p>Cschober: </p>
<hr />
<div></div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197018Chase Schober2017-09-30T17:12:27Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous reserach and calculated trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197004Chase Schober2017-09-21T04:20:19Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]<br />
<br />
<br />
'''Lathe Training Documentation:'''<br />
'''[https://tulane.box.com/s/7npmpsbj1yfwr7ezamiqlu98td63da24 Lathe Training Walkthrough]'''</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Tormach_CNC_Lathe&diff=197003Tormach CNC Lathe2017-09-21T04:18:37Z<p>Cschober: </p>
<hr />
<div>*Careful with chamfer operations as the tool will cut in a diagonal past the limits that you identify.<br />
*Parting tool is .161" wide and the zero of the tool is on the right side <br />
*Always reference the Z axis first.<br />
*If the axis doesn't move when you attempt to ref X or Z after a restart, go to the settings tab and make sure that the "Disable reference switches" box is unchecked. <br />
*Make sure the chuck key is never left in the spindle because it will go flying through the protective acryllic. <br />
*Once you have put your stock in the spindle, give it a spin to make sure you have properly secured your workpiece. <br />
*Use 1 and 1/8" hex to loosen quick change tool post holder. <br />
<br />
Feeds:<br />
<br />
http://littlemachineshop.com/reference/cuttingspeeds.php</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197002Chase Schober2017-09-21T04:17:33Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197001Chase Schober2017-09-21T04:16:42Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|center|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|center|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|center|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|center|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|center|400px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|center|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=197000Chase Schober2017-09-21T04:15:53Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|Center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|center|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=196999Chase Schober2017-09-21T04:15:12Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|Center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|Center|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=196998Chase Schober2017-09-21T04:14:45Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|Center|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=196997Chase Schober2017-09-21T02:54:13Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
[[File:Chase Lathe.jpg|500px]]<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=File:Chase_Lathe.jpg&diff=196996File:Chase Lathe.jpg2017-09-21T02:53:18Z<p>Cschober: </p>
<hr />
<div></div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=196995Chase Schober2017-09-21T02:52:46Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=196994Chase Schober2017-09-21T02:52:25Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=196993Chase Schober2017-09-21T02:52:11Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|500px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=196992Chase Schober2017-09-21T02:51:48Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|400px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=196991Chase Schober2017-09-21T02:50:33Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
[[File:Chase CNC MIll.jpeg|600px]]<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=File:Chase_CNC_MIll.jpeg&diff=196990File:Chase CNC MIll.jpeg2017-09-21T02:49:32Z<p>Cschober: </p>
<hr />
<div></div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=196989Chase Schober2017-09-21T02:19:23Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|600px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]</div>Cschoberhttp://makerspace.tulane.edu/index.php?title=Chase_Schober&diff=196988Chase Schober2017-09-21T02:19:07Z<p>Cschober: </p>
<hr />
<div>[[File:Chase_1.jpg|400px]] [[File:Chase Tormach.jpg|800px]]<br />
<br />
<br />
'''''MakerSpace Ninja'''''<br />
<br />
'''Email:''' cschober@tulane.edu<br />
<br />
'''Phone:''' (504) 722-9514<br />
<br />
'''Major:''' Engineering Physics<br />
<br />
'''Graduation Date:''' May, 2018<br />
<br />
<br />
==Projects==<br />
<br />
*'''CNC Mill'''<br />
Over the summer of 2017, I logged over 300 hours on the Tormach PCNC 770 mill. As the two students who had experience in working the mill both graduated, I trained myself on the machine through meticulous trial and error. After a month, I began to feel comfortable with the various end mills, CAM operations on Fusion 360, and the intense concentration required to operate such a powerful machine. Gradually, I began to machine custom aluminum parts for several research labs on campus to gain experience and by the end of the summer, I had made over 30 aluminum parts for four Tulane research groups. This work has continued into my senior year as I continue to work closely with two of the labs as their lab engineer and lab machinist respectively. Here are some of the more comprehensive projects that I worked on with a description of their process and purpose. <br />
<br />
<br />
'''Tulane University Biomechanics of Growth and Remodeling Lab:'''<br />
<br />
This lab approached me with the engineering plans for an adjustable cruciform to assist in his bio-medical research. They provided me with CAD models of four "slider" parts and one "stamp base". I imported them into Fusion 360, wrote the CAM, and machined the parts using the Tormach PCNC 770. Becuase of the locomotive nature of the sliders, each of their tolerances was ± .002". Each of the stamps required machining on both the top and bottom surface and so were flipped in the vice halfway through the operation. This was an excellent experience in standardizing my measurement procedure and performing the operation so that the two cuts met each other smoothly. <br />
<br />
The stamp base required the use of a T-slotter to route the hole for the sliders. I researched the appropriate feeds and speeds of the new tool and manipulated the CAM to produce a cut within specification. This part also required a vice flip in order to machine both sides. <br />
<br />
The cruciform, made of the five machined components, is being actively used by the Biomechanics of Growth and Remodeling Lab at Tulane University. Before we came into contact, a machining company had quoted their lab $585.00 for the five parts. <br />
<br />
[[File:Chase Schuster 2.png|300px]] [[File:Chase Schuster 3.jpeg|300px]] [[File:Chase Schuster 1.jpeg|300px]]<br />
<br />
<br />
'''Tulane University Photonic Materials and Device Lab:'''<br />
<br />
I was approached by this lab at the beginning of the summer and provided them with access to the 3D printers and laser engravers in the MakerSpace. As I began to train on the CNC mill, they took interest in my services and hired me as their lab machinist. The bulk of their demand has been aluminum parts for the Full Spectrum Solar Energy Conversion system they are developing. Below are some of the more complex parts that I have machined for them with a technical description. <br />
<br />
1) This 4.2" diameter aluminum part contained 30 separate holes with an inside profile. The operations required were straightforward and consisted of milling the stock to size, facing each profile, and then spot drilling each hole. Then, the 30 holes were drilled (requiring three separate twist drill bits). After that, a 3/16", 2 flute end mill was used to perform an adaptive cut on the inside profile. Following the adaptive, the same end mill cleaned up the profile with a contour operation. Finally, an outside contour operation was performed to cut the circular piece out of the rectangular stock. Finish work was performed on a polishing wheel. I machined a duplicate of this part several weeks after to expedite prototyping. <br />
<br />
[[File:Chase Escarra 1.jpeg|400px]]<br />
<br />
2) This 4.2" diameter aluminum part required tight tolerances for the six external profiles. As it was being used as a stamp to form a polymer mold, the height of the profile was required to be 125 microns ± 25 microns. This was especially difficult because the thickness of the part was .118" and was sensitive to vice buckling as a result. Finally, the grooves in between the profiles were 1 mm wide and required the use of a .5mm end mill. After one failed attempt (as a result of the vice bucking), I met the specifications and the part is now being used to produce polymer molds. <br />
<br />
[[File:Chase Escarra 2.jpeg|400px]]<br />
<br />
3) This 4.2" diameter aluminum part contained 30 separate holes and seven 125 micron-deep pockets. As it closely resembles a combination of the two previous parts, I was comfortable with the operations and their tolerances. <br />
<br />
[[File:2017-08-16 20.03.53.jpg|400px]]<br />
<br />
4)<br />
<br />
[[File:Chase Escarra 4.jpeg|400px]]<br />
<br />
5) I have been heavily involved in the modification of a glass-cutting diamond saw. In addition to machining several iterations of the blade bushing (shown below), I machined the aluminum saw support and am currently working on a safety enclosure and fluid cooling system. <br />
<br />
[[File:Chase Escarra 5.jpeg|400px]]<br />
<br />
<br />
<br />
*'''CNC Lathe'''<br />
In addition to my work with the Tormach PCNC 770 mill, I also had the chance to operate a Tormach 15L Slant Pro CNC Lathe. I set all of the tool offsets, troubleshooted several coolant and oil pump issues, and then developed an extensive training manual to institutionalize the experience I had gained through use. Here are some projects that I have undertaken on the lathe. <br />
<br />
<br />
<br />
'''Tulane University Cellular Biomechanics and Biotransport Lab:'''<br />
<br />
I was approached by several members of a Biomedical lab on campus to make an acoustic device. The apparatus consisted of the two parts shown below in addition to two that were not imaged. Much of the machining was accomplished on the lathe, while several modifying operations were conducted on the mill. <br />
<br />
[[File:Chase Jarrod 1.jpeg|400px]]<br />
[[File:Chase Jarrod 3.png|400px]]</div>Cschober