Track speed gearing and clutching debate.

WyoBoy1000 said:

go 8" across the clutch where you would get the 1:1, if you take 8" and multiply it by 3.14 you get 25.12". So if you stuck a 8" wheel and turned it one revolution it would travel 25.12" then multiply that by 8000 =200960" a min. divide it by 12 to convert to feet =16746.666666 divided by 5280' =3.171717 multiply by 60 to get from min. to hrs = 190.303mph. Then take a 1:1 of 80mph divide 190.303mph divided by 80mph = 2.378788 for a ratio. (the first time I did it I was off on the mile and had 5260' when I should have had 5280')

But this is a ratio if you have 8" drivers, if you factor in the height of the track then the height of the lug it can really change. this is a ratio if you only count the driver size. So if you take the 2.378788 gear up then the 2.24 gear down at 8000 rpm and 60/60 gears in a 1:1, then subtract the two and you get = .138788 then multiply it by 80 =11.10 and because its a gear up you add it to 80 to get 91.10mph 57/63 gears 82.42mph 55/65 = 77.08mph

I could be way off on this but its making sense to me.

Click to expand...

WyoBoy1000 said:

go 8" across the clutch where you would get the 1:1, if you take 8" and multiply it by 3.14 you get 25.12". So if you stuck a 8" wheel and turned it one revolution it would travel 25.12" then multiply that by 8000 =200960" a min. divide it by 12 to convert to feet =16746.666666 divided by 5280' =3.171717 multiply by 60 to get from min. to hrs = 190.303mph. Then take a 1:1 of 80mph divide 190.303mph divided by 80mph = 2.378788 for a ratio. (the first time I did it I was off on the mile and had 5260' when I should have had 5280')

But this is a ratio if you have 8" drivers, if you factor in the height of the track then the height of the lug it can really change. this is a ratio if you only count the driver size. So if you take the 2.378788 gear up then the 2.24 gear down at 8000 rpm and 60/60 gears in a 1:1, then subtract the two and you get = .138788 then multiply it by 80 =11.10 and because its a gear up you add it to 80 to get 91.10mph 57/63 gears 82.42mph 55/65 = 77.08mph

I could be way off on this but its making sense to me.

Click to expand...

WyoBoy1000 said:

Go back to the beginning, you can hit any gear with the cvt clutching with out actually changing gears, higher gears just expand the range of that gear, what every is thinking with a 1:1 is that you can get the best belt grip at a 1:1, but with the right clutching you can do the same thing with out being in a 1:1. But it is this theory that helps, with bad clutching its a good thing because it greatly increases grip, but for good clutching it wont change anything.

Click to expand...

Jeff K said:

OK, I see how you are trying to calculate it, but where does the 8" across the clutch number come from? Are you assuming that when the clutches are 1:1 that the belt is 8" in diameter in the primary and secondary?

WyoBoy1000 said:

Yep. I just started punching numbers, and it made sense so if you can find a fault lets figure it out. I would like to get this figured out because its obvious no one has really figured it out before.

Click to expand...

Click to expand...

WyoBoy1000 said:

^^^ This statement basically defeats the purpose of the CVT system all together. You are basically saying that if you put the primary and secondary in a gear and lock it up they will both be make the same rpm, but rpm in the CVT doesn't mean chit, rpm is only useful if you are shooting for maximum HP. So let eliminate thats and just say 8000rpm and leave it at that. We are not trying to defeat the purpose of the CVT system, but we are trying to have it operate in its most efficient range....at or near 1:1. When you need to put the power to the ground, you want the have the least amount of drivetrain loss.

Maybe it would be useful to go back and re read the thread as I feel like I have already explained the fact that no matter which of the gears mention above you have in your sled I can still hit the same gear ration with the CVT system. Sure, BUT again I am talking about 1:1 where the clutching is most efficient.

Going off of gear to hit clutching is just not how it should be done, you should pick some gears then build your clutching, Most people don't realize the importance of the way a clutch weight is loaded to get engagement and total force. If you have taller gears but will never see that much speed while climbing then you want the total force to be applied at your climbing speed, if you build the weight to give you this effect then drop gears you will shift past the sweet spot of the weight and start loosing performance. Basically I am saying if you focus on gear you might get lucky, if you build your clutching for your sled and the way you ride, thats what counts. Agreed. Whatever gearing you choose, your clutching needs to be set up properly to get the most out of it.

Click to expand...

Tonysnoo said:

Hey guys, not trying to ruffle feathers here, but I see some of this getting off on a tangent.

My math is coming up with the some different answers, so I’d like to present something that works for me. I like to work from the final drive back in. For some of you this is well known, sorry to be a bore. I am going over this for some of the rest who want to know how all this works.

First off, most of us have 8 tooth drivers and 3” pitch 3X8 = 24”(2ft) circumference driver.

Now our diamond drives have two ratios in side of them. The input/spur gear and the planetary ratio. The planetary is fixed at 2.24, so we just have to figure out the input ratio and divide the fixed by it.

A 60/60 is easy to figure 2.24/(60/60) = 2.24 / 1 = 2.24
Now the 57/63 ……2.24 / (57/63) = 2.25/.905 = 2.47

Now the MPH at any given SECONDARY clutch RPM can be figured by the following formula:

RPM / final ratio X 2(circumference of driver) X 60(min in hour) / 5280(ft in mile)

Example M8(57/63)
8000 / 2.47 X 2 X 60 / 5280 = 73.6
Example M8 (60/60)
8000 / 2.24 X 2 X 60 / 5280 = 81.2
Example M1000 (60/60)
7400 / 2.24 X 2 X 60 / 5280 = 75.1

Now the other side of the debate here is the clutch ratio. I hear most of you all saying about the same thing, so bottom line….. if we have a 1:1 ratio in the clutches, then we match the engine RPM to the secondary clutch RPM so we then can assume track speed.

I don’t know if 1:1 in our clutches is actually 8” to 8” but I think we all agree it needs to be equal diameter to equal diameter to be 1:1 and be most efficient. Mr Aaen did a lot of work in that area and I gotta believe him.

I agree with many of you. Gearing is best matched to you, your sled, and your needs. I like low gears for 90% of my riding. I run high gears for messing with my buddies when I don't care about belt wear. I don’t really care which is for you. I just wanted to clear up some of the math to help with the decision.

Sorry for being so long winded, but I hope this helps for part of the question.

Click to expand...

WyoBoy1000 said:

What is getting me is I thought you got circumference by multiplying the diameter by 3.14. So 8x3.14= 25.12 not 24"

Click to expand...

WyoBoy1000 said:

Well, if you look at it that way it changes everything, so the driver size is actually 7.64".

Now tell me this take out everything and tell me the ratio going from the crank to 8" across in the primary. Because I figured it to be 2.37 and you are telling me it should be figured as 2.093. I am assuming What I missed was to factor in 1" diameter to discount the 8" diameter. which would be 3.14x8000=25120 /12=2093.333/5280 x 60= 23.7879mph -- 190.303 =166.5151 / 80=2.08, pretty close to the 2.09 which could be just from carrying numbers over.

But with a 7.64" driver your numbers should be right, If you add the thickness of the flat part of the track you would be pretty close to a 85mph,

I was thinking in my rushed state of factoring I was missing something, but at least we know now, I think?


So your figures would have 55/65 running about 69mph.

Now back to the argument if you need lower gears or not.

Click to expand...

WyoBoy1000 said:

Well, if you look at it that way it changes everything, so the driver size is actually 7.64".

Now tell me this take out everything and tell me the ratio going from the crank to 8" across in the primary.

But with a 7.64" driver your numbers should be right, If you add the thickness of the flat part of the track you would be pretty close to a 85mph,

QUOTE]

I would suspect (if I read and understood your post correctly), if your belt was riding in your primary clutch at aproximately 4" from center(8" total diam) you would be in overdrive past 1:1/

This is the first time I actually bothered to try to figure out at what diameter 1:1 was in a clutch system.

Follow with me and make sure my logic is OK.

The belt for our sleds is a little longer than 46" so I am going to round off. The center to center distance of the clutches is 11.5" So visualize if we have both clutches at the same diameter belt print then we would have 11.5 X 2 (23") used up in space between the two clutches. That would leave 23" left over to go around 1/2 of the drive and 1/2 of the secondary. Since we have 2 halves that are equal, then we could just treat them as a whole for calculating purposes. That would tell me that 23/3.1416 = 7.3"

I would have to say that anything outside of that 7.3" diameter(in the primary) would start to get into clutch overdrive. Then the speed calcs above get increased by whatever percentage of overdrive you achieve.

Wow, that hurt my feeble brain.......LOL

Click to expand...