Manually machining a differential -- how many other teams don't have CNC?

Our school is severely limited on manufacturing equipment thus nearly everything is done manually.

We've made some amazing technical sponsors who have mentored us in machining, and as such we've become quite the little machinists.

I wanted to show off the work of one of our team members manually machining a T1 Torsen differential on a 3axis mill using a dividing head. It's pretty awesome

How many other teams don't have CNC thus must really learn to machine things manually. Post pictures/videos of your work.

http://www.youtube.com/watch?v=UovZ_vVGhTY

Our school is severely limited on manufacturing equipment thus nearly everything is done manually.

We've made some amazing technical sponsors who have mentored us in machining, and as such we've become quite the little machinists.

I wanted to show off the work of one of our team members manually machining a T1 Torsen differential on a 3axis mill using a dividing head. It's pretty awesome

How many other teams don't have CNC thus must really learn to machine things manually. Post pictures/videos of your work.

http://www.youtube.com/watch?v=UovZ_vVGhTY

That is highly excellent. I think you guys are all learning the more important aspects of the competition on the design side since you have to think through all the different ways you have at your disposal to make something, rather than just assume you can farm out a spotty design to a CNC operator.

We had rudimentary CNC access, and the NU team is better equipped to use it now than when I was there, but my skills on manual machines are much more useful to me at work now, where I'm a fabricator.

Some of my favorite manufacturing books are very old, I have an excellent sheetmetal working handbook that was published in '39 that was geared towards taking people who knew carpentry and basic work skills and training them to work in aircraft factories for the war.

Very complex parts can be made by a skilled (and careful) operator with an indexing head and lots of planning. Sure it takes a little longer, but if you guys are already manufacturing driveline parts, I don't think you're at a planning disadvantage.

Well done.


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Thrust loads on those side gears in the Torsen can be pretty fierce, are you going to anodize the part, or make inserts, or just rely on lubrication? You don't want to gall up such an expensive piece of 7075 from something simple like that.

Well done piece of machining there. Hope to see more time lapses like this.

Ben

<BLOCKQUOTE class="ip-ubbcode-quote"><div class="ip-ubbcode-quote-title">quote:</div><div class="ip-ubbcode-quote-content">Originally posted by Drew Price:

Thrust loads on those side gears in the Torsen can be pretty fierce, are you going to anodize the part, or make inserts, or just rely on lubrication? You don't want to gall up such an expensive piece of 7075 from something simple like that.

</div></BLOCKQUOTE>

It's not my part so I'm not sure. I think there are washers to buffer the gears from the housing.

Awesome video. The tour group of kids was fun to see. What song is that?

Very impressive. We have a 2 axis CNC that can hold a tolerance of about .030" on a 3 inch diameter circle, so while it does save some time, its kind of a pain and I've found myself remaking a good deal of parts. Last thing I tried to hand machine was a trigger wheel for our engine. I found out about half way through it that our rotary table was only precise in one dimension, so I had to scrap that idea and we were lucky enough to get some time on the 3 axis that our school keeps under lock and key.

Theres also a good reason why I'm primarily a fabricator and not a machinist.

That's a good looking part!

Excellent work there! I totally agree with coleasterling. ME graduates lack the practical skills and their designs almost always indicate this. I don't understand why schools don't require a semester or two of real hands on classes during student's Freshmen year.

Fun times! I manually machined the crankcase for University of Auckland's V-Twin. It certainly helps you make sure the design is up to par when you know you are going to machine it yourself.

It also gives your problem solving skills a workout when you are trying to work out the most accurate way of jigging your part. It's also important (as some of you have found out already) to know the capabilities of the machine you are working with. Even with a digital readout the mill and your part can be off by a surprising amount. I also always made sure I had a plan B before I even started machining, just so that when/if I do cock up it's not going to be the end of the world.

V-Twin Machining Pics