Is Anyone Successfully Shooting with a Belt?

[Chris_Ely]

My team was going to prototype a belt shooter, but then we ran some calculations.
The Frisbee's linear is theoretically half of the belt or wheels tangential velocity. So, the larger the wheel, the larger the tangential velocity. The belt has the same linear speed the tangential speed of the pulley that it rides on. Most belt pulleys are small when compared to the wheels that most teams are using--around 2 inches in diameter verses 6-8 inches in diameter-- so in order for the belt shooter to move the Frisbee as fast as a larger wheeled shooter, it has to move faster. Moving faster increases the chance for slippage between the belt and the Frisbee.
If you had belt pulleys of a larger diameter, and a belt that has a high grip on the Frisbee, I seen no reason that a belt shooter would not perform the same, if not better, that a wheeled shooter.

[velcro]

I see what you are saying - with a 2" pulley, the motor has to go faster to get the same surface speed as an 8" wheel. But whether we have a belt going 100 inches/sec or a wheel with a surface speed of 100 inches/sec, if the friction is the same and the normal force is the same, then the slippage is the same.

It seems like is should work, but has anyone demonstrated that it can practically be done?

[wilful]

We tried using belt to shoot frisbees, they didn't work. The solid metal pulleys do not compress, neither do the frisbees. This causes problems achieving enough friction to throw the frisbee.

[Aren Siekmeier]

See http://www.fightingcalculators.org/blog/?p=91 and the rest of our blog. In concept, the belt shooter was far more attractive to us than a wheel shooter, so we focused on making it work over other designs that took fewer iterations, and are now very happy with what we've come up with, and moving forward with the competition design (with no illusion of it being final).

[Orion.DeYoe]

We prototyped a belt shooter. We used 6 in. wheels for the rollers and direct drove it from a CIM. We used the orange urethane belt (just like the polycord everyone used last year, except flat) for the belt.
As soon as we powered it up we noticed a huge problem. When you get the CIM up to full speed (the kind of speed you would need to launch a frisbee a reasonable distance) the centrifugal force caused the belt to "float" off of the rollers.
We did some more work on the prototype and put in a ridiculously tight tensioner to keep the belt on the rollers. Then we ran the launcher at about 60% power. We were able to get 20-25 feet of distance launching at ~30 degrees.
This distance could be enough for some applications, but not for others. We're planning to prototype a two-wheeled shooter next.
We figured that if we got some belts that wouldn't stretch then we could use those, but our options seem to be pretty limited as to the belts we can get.
My conclusion? Yes, belts can be made to work, but you could waste a lot of time trying to get it to work consistently. Time that might be better spent on designing and building a good climbing mechanism.

[COL Woodchuck]

As a engineer who has spent over 20 years designing belt conveyors I think there are some significant losses that need to be considered with using a straight line belt shooter vs a curved track wheel shooter.
First you need to consider the losses from the slider bed behind the belt. Using "standard" rough top PVC belt with a polyester fabric carcass the friction coef. is about .28 using a metal backing, .24 using uhmw, and mabe you can get it down to .20 using Teflon.
You also need to consider the losses of bending and unbending the belt as it goes around the drive and idler rollers. We have seen this factor play a significant roll in overall losses as the speed of the belt increases such as is needed for a shooter.
Finally you have losses from moving the bearings on two wheels and the load on the bearings from with belt tension.
Using a curved shooter with a single wheel the only losses are in the bearings of the wheel and the deflection of moving the rubber of the tire.