Lean angle question.

[GSVR]

Nice problem you lined up there...

If the bike is changing direction then you're changing the direction of the rotational momentum as well. To do that you need to apply an amount of torque orthogonal to both the rotating momentum and the desired change of momentum... But fuck if I can figure out how it all works out on top of my head.

Yeah its like the gyro hanging on a string. But instead of circling a point its travelling in a circle so would have to go spin alot faster to keep the equalibrium

[Mikkel]

Yeah its like the gyro hanging on a string. But instead of circling a point its travelling in a circle so would have to go spin alot faster to keep the equalibrium

No no, it's an entirely different mechanical situation! Much more complex.

[NZsarge]

Let me add this more simple question, given that a bike would turn, brake, accelerate and generally handle better on a set of carbon fibre rims as opposed to most OE rims, are they durable enough to handle the day to day rigours of road use and do they need any special care?

[GSVR]

Let me add this more simple question, given that a bike would turn, brake, accelerate and generally handle better on a set of carbon fibre rims as opposed to most OE rims, are they durable enough to handle the day to day rigours of road use and do they need any special care?

I don't think they are a good idea on a road bike as the extra the cost it would be better to trade up to a better bike. Any damage they do get would most certainly mean throwing them away. Suspension upgrade would be money better spent by far.

You can only use them in F3 on the racetrack as production classes have to use OEM rims

[Mikkel]

Let me add this more simple question, given that a bike would turn, brake, accelerate and generally handle better on a set of carbon fibre rims as opposed to most OE rims, are they durable enough to handle the day to day rigours of road use and do they need any special care?

I don't think they are a good idea on a road bike as the extra the cost it would be better to trade up to a better bike. Any damage they do get would most certainly mean throwing them away. Suspension upgrade would be money better spent by far.

You can only use them in F3 on the racetrack as production classes have to use OEM rims

I'd agree with GSVR. Not worth the money...

Yes, you'd reduce the unsprung weight a small amount - but you'd be hunting for tenths of a second per lap probably to make it worthwhile.

Also, carbon fibre is harder than steel - but not nearly as tough. Dunno how long they'd last on the road.

[NZsarge]

I don't think they are a good idea on a road bike as the extra the cost it would be better to trade up to a better bike. Any damage they do get would most certainly mean throwing them away. Suspension upgrade would be money better spent by far.

You can only use them in F3 on the racetrack as production classes have to use OEM rims

I would have thought by virtue of the fact that they improve your handling particulary braking and cornering they would be worth a look but only in the extreme, I agree that suspension would be a far better place to start upgrading your average bike. Was just interested about the durability of such thing for the everyday rider.

[GSVR]

No no, it's an entirely different mechanical situation! Much more complex.

Well its the precession that keeps the gyro hanging on the string orbiting at an almost zero radius with almost zero centrifugal force and the same effect is holding the bike up slightly but the zeros are large figures. My thoughts are to remove all motorcycle reference and work the problem purely as a gyro orbiting a point at different angles and speeds perhaps with hanging ballast to balance it against the centrifugal force. Then just adjust some of the variables and plot the result.

Or are you talking about solving the textbook example. Its already solved.

[GSVR]

I would have thought by virtue of the fact that they improve your handling particulary braking and cornering they would be worth a look but only in the extreme, I agree that suspension would be a far better place to start upgrading your average bike. Was just interested about the durability of such thing for the everyday rider.

I think plenty would love to have them but do you know what a single rim retails for?

[Grub]

Let me add this more simple question, given that a bike would turn, brake, accelerate and generally handle better on a set of carbon fibre rims as opposed to most OE rims, are they durable enough to handle the day to day rigours of road use and do they need any special care?

Well, I've just finished reading the John Britten book and didn't see anything about the wheels failing ... everything else did from time to time. But did I miss abit where they went back to alloy? Can't remember.

[GSVR]

Well, I've just finished reading the John Britten book and didn't see anything about the wheels failing ... everything else did from time to time. But did I miss abit where they went back to alloy? Can't remember.

The Mark Farmer fatality at the IOM was interesting. It was high speed and I don't think the cause was established. Wonder if he was on Carbon or Alloy

Terry Fitzs has had his rims for a long long time and done alot of racing even in the streets which has to be hard on them.

[NZsarge]

I think plenty would love to have them but do you know what a single rim retails for?

$4710.10cents for both front and rear rims (BST) since you're asking. I think i'll whack a slipper clutch on there too!

[smoky]

As I was approaching the corner I calculated;

... at 140 km/h round a cornerof 120 m radius. The cycle and rider have a mass of 150KG and their centre of gravity is 0.7 m above the ground level when machine is vertical. Each wheel is 0.6 m in diameter and the moment of inertia about its axis of rotation is 1.5 kg m2. The engine has rotating parts whose moment of intertia about their axis of rotation is 0.25 kg m2 and it rotates at five times the wheel speed in the same direction.

Find (a) the angle of banking so the there will be no tendency to sideslip, (b) the angle of the cycle and rider to the vertical.

The answer for (a) is 52 degrees and 5 minutes and (b) is 55 degrees and 33 minutes

To work out (a) they work out the forces acting on the bike - take the bikes weight in newtons ie 150kg x 9.81 = 1472 N. Then the centrifugal force - Mass of bike 150kg and the centrifugal force it creates going round a 120m radius at 140kph = 1890 N.
The resultant force from these two forces has to be perpendicular to the track surface.
(Tangent of 52 degrees and 5 minutes is 1.284) Vector diagram in book.

Goes on to work on the total gyroscopic coupling of the wheels and motor then uses the centre of gravity and forces acting about the point of contact (wheel and track) to arrive at 55 degrees and 33minutes.

So according to this the bike has to lean another 3 degrees and 28 minutes to overcome the gyroscopic forces wanting to "overturn the the cycle outwards"

But I must of got it wrong somewhere - As I finally worked out how much to lean the bike over I realised I had missed the corner and ended up in the drain.
I guess I'll have think to quicker next time.

[GSVR]

Heres a simple question. Motorcycle with heavy rims and tyres (High amounts of gyroscopic coupling going on) goes around a bend at 160 kph and leans 45 degrees. Now these wheels are taken off and some extremely light carbon rims are fitted that produce considerably less gyroscopic effect. The bike is ridden around the same bend at 160kph (all conditions the same, same gear, engine revs, COG when bike is vertical etc.) Only diffence is the wheels having considerably less gyroscopic coupling.

Its not a trick question only difference is the wheels. Everything else is the same.

Does the bike lean less, more, or the same amount? Feel free to give possible reasons for your answer.

I don't know the answer haven't tried to find out yet thats why I am asking.

Well my thoughts are that the lighter wheels will make the bike lean less as more lean is required to overcome the extra force wanting to stand the bike upright the heavier rims generate.

The centre of gravity change does not have an effect as pointed out in the other thread with the excel spreadsheet. Centre of gravity changes effect when they are offcenter to the centerline of the bike (eg rider hanging off)

The amount however is unlikely to be more than a degree which a rider probably will not notice. Tyre profiles and widths would pay a far greater part.