billyk
Guru
I've restarted this thread, originally "Incredibly stable recumbents" (in Riding Techniques) because that one became very long and began to wander ... to say the least.
I'm especially interested in the model Hamish Barker presented, that allows identifying the specific elements that cause a particular bicycle to be more or less stable at various speeds. The model is described in the quite technical paper at
http://rspa.royalsocietypublishing.org/content/463/2084/1955
Hamish posted plots of his solutions to this model in the above thread.
Hamish also posted links to videos demonstrating this stuff. See:
http://bicycle.tudelft.nl/schwab/Bicycle/
These show a regular upright (and riderless) bike pushed to roll freely, wobbling and recovering.
Consider three facts:
1) It's easy to wheel an upright bike holding it by the seat, even turning with fair precision; but it is far harder to wheel a Cruzbike like this. (Possible, but vulnerable to sudden failure!)
2) Many postings here throughout the years have noted a sense of coming close to a wobble at high speed. We control it, but I think this is something most of us have felt. Let's be honest about this.
3) Bicycles are balanced by steering to put the wheels underneath the lean. This is a principal result of the Dutch experiments (see movies linked above), as well as previous studies. It has little or nothing to do with the gyroscopic effect of spinning wheels, and a well-designed bicycle will naturally self-steer and recover it's balance when pushed and let roll freely (see movies). That's what the head tube angle and trail do. This is quite similar to how you balance a broomstick on your hand: move the hand to be always under the CoG of the broom.
Unfortunately I'm reluctant to test the ability of my Quest to recover rolling freely after a push! But I suspect it is not great.
In terms of the model Hamish has shown, what is the fundamental difference between Cruzbikes and uprights?
I think the key difference is that on a CB the mass is much further forward than on a DF: both for the drivetrain/boom assembly, and the rider. The whole drivetrain and its structure is in _front_ of the steering axis, and the rider is nearly wrapped around the steering column.
It therefore seems to me that the essential experiment to be done with Hamish's model is to keep everything else constant and move the mass (frame+rider) gradually forward: How does this affect stability? Which of the terms of the model are affected?
I would speculate that the difference is akin to the difference between balancing a tall broomstick (easy) and balancing a spoon (very difficult): With the CoG of the broomstick far from your hand, it is easy to stay underneath it (upright bike with the mass far from the steering axis); on the other hand, balancing the spoon (Cruzbike with the mass close to the steering axis (?)) is harder. Is the Cruzbike/upright situation analogous to the spoon vs broom?
Hamish found that the "weave mode" (oscillation and recovery as in the movies linked above) of a Cruzbike remains unstable at any speed. This is not fatal; as Hamish noted it just means that the rider needs to actively control the wobble. How does the weave mode change as the mass is moved forward?
Another possibility is "wheel flop", the tendency of the front wheel to want to flop over more than the turning input. It's caused by lowering the CoG when the front wheel is turned (as the ground contact point changes), tending to increase the turn. This tendency is increased with mass further forward, but I can't identify this with any of the eigenvalues of Hamish's model. At least this seems to be the reason it's hard to wheel a Cruzbike by its seat.
My further speculation is that the "incredible stability" we feel is not due to the geometry but to our four points of contact with the steering: a much more immediate and forceful response to wobbles and instabilities.
My applause to Hamish for making a leap ahead. I look forward to his refining his experiments.
Billy K
I'm especially interested in the model Hamish Barker presented, that allows identifying the specific elements that cause a particular bicycle to be more or less stable at various speeds. The model is described in the quite technical paper at
http://rspa.royalsocietypublishing.org/content/463/2084/1955
Hamish posted plots of his solutions to this model in the above thread.
Hamish also posted links to videos demonstrating this stuff. See:
http://bicycle.tudelft.nl/schwab/Bicycle/
These show a regular upright (and riderless) bike pushed to roll freely, wobbling and recovering.
Consider three facts:
1) It's easy to wheel an upright bike holding it by the seat, even turning with fair precision; but it is far harder to wheel a Cruzbike like this. (Possible, but vulnerable to sudden failure!)
2) Many postings here throughout the years have noted a sense of coming close to a wobble at high speed. We control it, but I think this is something most of us have felt. Let's be honest about this.
3) Bicycles are balanced by steering to put the wheels underneath the lean. This is a principal result of the Dutch experiments (see movies linked above), as well as previous studies. It has little or nothing to do with the gyroscopic effect of spinning wheels, and a well-designed bicycle will naturally self-steer and recover it's balance when pushed and let roll freely (see movies). That's what the head tube angle and trail do. This is quite similar to how you balance a broomstick on your hand: move the hand to be always under the CoG of the broom.
Unfortunately I'm reluctant to test the ability of my Quest to recover rolling freely after a push! But I suspect it is not great.
In terms of the model Hamish has shown, what is the fundamental difference between Cruzbikes and uprights?
I think the key difference is that on a CB the mass is much further forward than on a DF: both for the drivetrain/boom assembly, and the rider. The whole drivetrain and its structure is in _front_ of the steering axis, and the rider is nearly wrapped around the steering column.
It therefore seems to me that the essential experiment to be done with Hamish's model is to keep everything else constant and move the mass (frame+rider) gradually forward: How does this affect stability? Which of the terms of the model are affected?
I would speculate that the difference is akin to the difference between balancing a tall broomstick (easy) and balancing a spoon (very difficult): With the CoG of the broomstick far from your hand, it is easy to stay underneath it (upright bike with the mass far from the steering axis); on the other hand, balancing the spoon (Cruzbike with the mass close to the steering axis (?)) is harder. Is the Cruzbike/upright situation analogous to the spoon vs broom?
Hamish found that the "weave mode" (oscillation and recovery as in the movies linked above) of a Cruzbike remains unstable at any speed. This is not fatal; as Hamish noted it just means that the rider needs to actively control the wobble. How does the weave mode change as the mass is moved forward?
Another possibility is "wheel flop", the tendency of the front wheel to want to flop over more than the turning input. It's caused by lowering the CoG when the front wheel is turned (as the ground contact point changes), tending to increase the turn. This tendency is increased with mass further forward, but I can't identify this with any of the eigenvalues of Hamish's model. At least this seems to be the reason it's hard to wheel a Cruzbike by its seat.
My further speculation is that the "incredible stability" we feel is not due to the geometry but to our four points of contact with the steering: a much more immediate and forceful response to wobbles and instabilities.
My applause to Hamish for making a leap ahead. I look forward to his refining his experiments.
Billy K
.gif)
