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Re: pic: Omni Design Trial
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Now, for the thread.... I would stay away from any sort of holomonic drivetrain this year. The manueverability will be nice, but all of the pushing and jostling that will happen in a match will make you wish you never did it.... |
Re: pic: Omni Design Trial
Yes, I now know that she has mecanum experience....but it seems that she overlooked a highly relevant fact about the wheels. I did not think that she would have done this if she had a mecanum wheel at hand to play with.
I think we are all starting to agree on the subject now.... |
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I design things for a living -- mecanum wheels included -- and am quite familiar with their operation. |
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The difference is in whether or not they're constrained and allowed to move forward by the motion of the bot. In a mecanum if it is moving forward the rollers won't turn because if they were the wheel would have a lateral velocity (different from force, there is a lateral force). On an omni when moving in the forward direction there is a lateral velocity so the rollers do turn.
However this means that in an ideal situation, when you have no friction in the bearings you will not see ANY difference between the two. You may see a slight difference in top speed because of the angle on the wheels but you will see absolutly no difference in power since no power is used up in heating the bearings. In the real world you will see that in the forward direction since the mecanum rollers aren't turning there will be a slightly better efficiency and more power will get to the floor, but I would be willing to bet that you couldn't measure the difference cause when your talking about a 321 watt motor, the amount lost to the bearings is inconsiquecial. |
Re: pic: Omni Design Trial
Though incredibly versatile, the standard Mecanum wheel has an unfortunate side effect which reduces its effeciency considerably. Its wide range of mobility is due to the fact that the peripheral rollers translate a portion of the motor force into a force perpendicular or at an angle to that produced by the motor. This means that are large portion of the force in one direction is lost through the translation into a resulting force by the rollers.
... Losses of effeciency when traveling in a straight line are due to energy lost in a direction normal to that of travel through the peripheral rollers which bleed off available energy as they rotate. From http://www.araa.asn.au/acra/acra2002...eter-Tlale.pdf |
Re: pic: Omni Design Trial
Thanks for the explanation, Alex.
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I'd like to know...really.... |
Re: pic: Omni Design Trial
Mecanum wheels are not that hard to find or that expecive. andymark makes an 8inch and 6inch wheel. last year my team used the andymarks and might be doing it again this yea its a possiblility.
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Re: pic: Omni Design Trial
For a small team the $300 for a complete set of mecanums can be a real hardship where as you can get a complete set of omins for $80 that are more than good enough... I don't know how these omnis compare to the andymark but I do know that they work very well and are more that durable enough for the game.
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If you draw a vector diagram for a mecanum wheel, you get a line going at an angle to the axis of rotation. The forward pointing vector is a component vector and is of less magnitude than the diagonal vector. Summing these forward vectors give you a lower magnitude then if you had standard wheels in which the entire vector is pointing in the forward direction. |
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For anyone who's really interested in finding out all the science behind how a mecanum works, that paper is an excellent read. I remember when I first came across that paper. I went to all of my friends saying, "See!? This is what I've been talking about!" |
Re: pic: Omni Design Trial
Thanks for the explanation, Fred. We now know that the maximum force that can be transmitted by a mecanum wheel in the forward direction is not as high as with a regular wheel. How does this affect the power transmission? Is there more frictional loss because of the side pointing vector? If so, how could I calculate that?
Also, what about the speed? If the rollers are not rotating relative to the wheel body as in straight ahead driving, is the full speed of the motor applied by the wheels? The paper is interesting, but doesn't offer any explanation...it seems to be mostly selling the new design.....it would be nice if it had even a little bit of actual theory, and really nice if it had some empirical data to back up the claims. |
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Speed however will change. It is our experience that the rollers do in fact spin while going straight. On the ground the force is encouraging them to spin, and "perfect" traction would prevent that, but this is usually not the case. I suspect that there is some movement on the carpet, but additionally as soon as the wheel rotates the rollers will spin more as they pick up off the floor. If at all possible, it would be a great test to get the same diameter wheels as the mecanum and compare speeds on the official carpet. We did not go into that much detail with our prototype analysis, but we made a rough estimate with vector calculations to adjust the gear ratios accordingly for our ideal fps. |
Re: pic: Omni Design Trial
So, if you were to set up the wheels to be optimized for straight driving by adjusting the friction to be high enough that the rollers would not be able to roll at normal driving loads, would that make the sideways force vector on the rollers negligible under these conditions? I'm thinking that the inability to overcome static friction would keep the rollers acting like regular tread, and the wheels would indeed act almost like regular wheels under those conditions.
I'm thinking about this as it applies to this game only. |
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I just wanted to point out a small error in the discussion regarding Force and Motion.
NET force will result in Acceleration ... constant velocity requires no force whatsoever. When we accelerate robots we see the result of all the forces involved. The net force. The other forces on the robot are varied and the one we should discuss here primarily is friction (which is a result of the weight of the robot and the coefficnet of friction between the wheels and the carpet). This frictional force is what accelerates the robot. This frictional force is a result of the wheels applying a force to the carpet and carpet pushing back. The net force on the robot, when it is going forward is in that direction. If the angled wheels on a set of mecanums are not turning it is simply indicating that the sideways forces are balanced. It does NOT indicate there are NO sideways forces. I would imagine that the pin loading on the bearings in this angled state is much different than when it is moving parallel to the wheel's orientation. I you could measure the temperature of these wheels over the course of the match I would be very surprised if they do not get quite warm. This loss of efficiency that we all discuss with holonomic or mecanum systems has to result in energy being spent somewhere else... Anyway these are my suggestions on this topic. Specifically they would indicate why that holonomic drives and mecanum drives have to work in the same way. Force applied does not net acceleration. Net force does. Good luck to everyone no matter what drive system they use!!! Have a great season!!! May the NET FORCE be with you!!! |
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