Center to Center with belts

[steelerborn]

http://www.sdp-si.com/cd/default.htm

[Mk.32]

We did GT2 5mm x 9mm belts this year with C-C + .005 in our west coast drive train and loved them.

http://25.media.tumblr.com/6a0f1b587...cgvo5_1280.jpg

However we used tube and CNC milled them, down to probably +/- .003 tolerances. We never had an single issue after 2 regional.

[Nate Laverdure]

This thread has a lot of useful information on how to do exact c-c spacing with belts.

[craigboez]

Quote:

Originally Posted by Mk.32

We did GT2 5mm x 9mm belts this year with C-C + .005 in our west coast drive train and loved them.

http://25.media.tumblr.com/6a0f1b587...cgvo5_1280.jpg

However we used tube and CNC milled them, down to probably +/- .003 tolerances. We never had an single issue after 2 regional.

Very nice arrangement, we're working on something similar for an offseason project. Two questions:

1. Do you mean you milled the GT2 pulleys? If so, can you provide some details on what is required to do such a thing. Are there specific CAD tools, special cutting tools, etc that make life easier?
2. It sounds like you didn't have any issues with belts skipping/ratcheting, even though 15mm belt sounds like a "safer choice" for a drivetrain. Using the 9mm did you drive it hard, go from full forward to full reverse, push much, etc without issues?

[roystur44]

Take a look at the Andy Mark 2013 KOP drive train.

In the past we've built a tensioned belt setup and then last year we used the Andy Mark Setup. It is a excellent drive setup. Easy to assemble and maintain and we had no belt ratcheting whatsoever despite playing mostly defense. We were geared to 10'/sec , 6 wheel dropped with 4 CIMs. 6" kit wheels


The width of the belts, the size of the pulleys and the dead axle make assembly easy.

I was surprised to see so many 2013 kit bots in the Curie Finals. The Kit bot on Steroids is a excellent drive train.

[Mk.32]

Quote:

Originally Posted by craigboez

Very nice arrangement, we're working on something similar for an offseason project. Two questions:

1. Do you mean you milled the GT2 pulleys? If so, can you provide some details on what is required to do such a thing. Are there specific CAD tools, special cutting tools, etc that make life easier?
2. It sounds like you didn't have any issues with belts skipping/ratcheting, even though 15mm belt sounds like a "safer choice" for a drivetrain. Using the 9mm did you drive it hard, go from full forward to full reverse, push much, etc without issues?

Thanks Really happy with this drive.

What I meant in my post was I CNC milled the bearing holes in the rails so that the C-C distance was a really tight tolerance. (I would think 1/32 off would be to much).

However I did machine my own pulleys, more info: http://www.chiefdelphi.com/media/photos/38380
In short just a tiny (3/32th) square endmill + 3/8 alum plate + cnc. The pulley cad was downloaded from SDPSI and I used just my regular CAM software to come up with the tool path.

We did not have any issues with skipping and ratcheting. And the people that have seen me drive can vouch we pushed the drive as hard as we could, with doing all the above. Also to test I pretty much rammed into a test wall and stalled the motors and the belts still didn't ratchet.

[sanddrag]

I used XL timing belts and pulleys from McMaster and the SDP-SI calculator and I would call it a very loose fit, but it never skipped. I would have liked the fit to have much less slop though.

[DELurker]

The industrial answer is to make the perimeter that encompasses the OD of each pulley and the tangents to those edges equal to the inner perimeter of the belt, so that it fits over all pulleys at the same time. Then, either cam one shaft into location (ie - slide) or use a cam-style idler roller for belt tensioning (cam followers work great for this).

Of course, if you don't want to have a separate tensioner and you want the shafts to be fixed in place, you can have one of the pulleys have either no flange or a removable flange. After all, you typically only need flanges on every other pulley.

A really good resource for timing belt information is http://www.martinsprocket.com/2001/SecK.pdf#J2
It has center-to-center charts, rules of thumb, engineering calculations, and design criteria.

[iyermihir]

Quote:

Originally Posted by DELurker

Of course, if you don't want to have a separate tensioner and you want the shafts to be fixed in place, you can have one of the pulleys have either no flange or a removable flange. After all, you typically only need flanges on every other pulley.

We had fixed flanges on all of our pulleys this year and it worked fine. The trick is to put the belt on the pulleys before putting the pulleys on the shafts. Keep the pulleys in the same plane as you slide them onto the shafts and it will work fine.

-Mihir Iyer

[MichaelBick]

Quote:

Originally Posted by Mk.32

Thanks Really happy with this drive.

What I meant in my post was I CNC milled the bearing holes in the rails so that the C-C distance was a really tight tolerance. (I would think 1/32 off would be to much).

However I did machine my own pulleys, more info: http://www.chiefdelphi.com/media/photos/38380
In short just a tiny (3/32th) square endmill + 3/8 alum plate + cnc. The pulley cad was downloaded from SDPSI and I used just my regular CAM software to come up with the tool path.

We did not have any issues with skipping and ratcheting. And the people that have seen me drive can vouch we pushed the drive as hard as we could, with doing all the above. Also to test I pretty much rammed into a test wall and stalled the motors and the belts still didn't ratchet.

What were your robot dimensions(in case we go back to 28x38 next year)

[Clem1640]

We use a worksheet to calculate C-C distances for axles driving chains or belts. This works really well without requiring tensioners for short runs (<=6"). Longer runs require tensioners or empirical determination. Link to worksheet below:

http://www.chiefdelphi.com/media/papers/2715

[MetalJacket]

Quote:

Originally Posted by Mk.32

We did not have any issues with skipping and ratcheting. And the people that have seen me drive can vouch we pushed the drive as hard as we could, with doing all the above. Also to test I pretty much rammed into a test wall and stalled the motors and the belts still didn't ratchet.

Just to clarify for my own knowledge, there should be little to no performance issues using 9mm wide belts compared to using 15mm wide belts (like those in this year's KoP) assuming they both have the same tooth profile? I'm currently working on a practice sheet metal chassis using belts and I'm trying to make the wheel wells as thin as possible but I don't want to compromise performance for space. Thanks,
Jesse

[DampRobot]

Quote:

Originally Posted by MetalJacket

Just to clarify for my own knowledge, there should be little to no performance issues using 9mm wide belts compared to using 15mm wide belts (like those in this year's KoP) assuming they both have the same tooth profile? I'm currently working on a practice sheet metal chassis using belts and I'm trying to make the wheel wells as thin as possible but I don't want to compromise performance for space. Thanks,
Jesse

Not necessarily true. The maximum torque that can be put on a belt varies proportionally to its width. If you're right on the edge in terms of how much torque that can be on the belt, the switch from 15mm to 9mm definitely makes a difference in whether it will ratchet or not. If you want to be sure, check the Gates website. They should have some nice tables that give all of the relevant torque and speed information.

Just keep in mind that for FRC, your FoS or duty rating will probably be much lower than 1 (i.e., it can take more torque than what's on the table). Those belts are designed for hundreds of thousands of cycles, something they'll never see in FRC, so we can probably get away with more torque than they were designed for. Adam Heard probably has a more exact number, as he's built a lot of belts drivetrains before.

[MetalJacket]

Quote:

Originally Posted by DampRobot

Not necessarily true. The maximum torque that can be put on a belt varies proportionally to its width. If you're right on the edge in terms of how much torque that can be on the belt, the switch from 15mm to 9mm definitely makes a difference in whether it will ratchet or not. If you want to be sure, check the Gates website. They should have some nice tables that give all of the relevant torque and speed information.

Just keep in mind that for FRC, your FoS or duty rating will probably be much lower than 1 (i.e., it can take more torque than what's on the table). Those belts are designed for hundreds of thousands of cycles, something they'll never see in FRC, so we can probably get away with more torque than they were designed for. Adam Heard probably has a more exact number, as he's built a lot of belts drivetrains before.

OK thanks, I'll check out the Gates website to try to get some more exact numbers.

[jspatz1]

We've always had perfect results by simply laying out the belt in a CAD sketch. Draw the pitch diameter circles of your pulleys, connect them with tangent lines, trim the inner portion of the circles, then measure the loop length. Adjust the C to C until the loop length matches the available belt pitch length.