yeah, I saw that one. I was really amazed at how they did that.fliptw wrote:NB: mythbusters also did this conveyor airplane bit too.
Strictly speaking the tires would explode and what remains of the wheels would turn into a spectacular shower of sparks, but that still wouldn't prevent the plane from taking off. Although it would jeopardize it making a safe landing again so no pilot would actually go through with it.Drakona wrote:No, Woodchip is right, as snoopy hinted. A sufficiently fast conveyor belt will prevent the airplane from taking off. The wheels might be low friction, but they aren't zero. You just have to spin them fast enough. I mean, really fast enough.
It's all in the posing of the problem.
If you say "the conveyor belt goes backwards as fast as the airplane goes forwards", then it takes off no problem.
If you say, "the conveyor belt goes backwards fast enough that the airplane holds still," then it doesn't take off. It's also an insanely fast conveyor belt.
Funny, every time I hear this problem posed, I'm always tempted to bring up the supersonic conveyor belt. I usually restrain myself, though, because it sows so much confusion, and apparently the mere distinction between ground speed and air speed sows enough confusion . . .
Pretty gutsy to take a 1000-pound airplane up in 33+ knot winds. They'd have to be remarkably constant...tunnelcat wrote:I used to know a friend who owned a Piper Cub. The plane had a very low takeoff speed. If the wind was blowing hard and constant enough, he could actually take off and fly backwards if he throttled back a little.
.. relative to a stationary object on the ground. That doesn't sound very promising for the plane. 
Wouldn’t matter…as soon as you applied “any” forward thrust the aircraft would begin to slow its backward motion, and would just be a matter of time, before building forward air speed.Thenior wrote:Now what if the plane was holding still, and allowed the conveyor belt to give it a backward momentum of 100 knots. The plane would then have to apply at least 100 knots of propulsion from the opposite direction to become 0 knots. But the instant it reaches 100 knots propulsion, it would then begin to gain forward momentum.
But what if it was going backward @ 100 knots and only applied 20 knots of forward propulsion?
first: there is no "backward momentum", only backward speed. momentum has to do with rotation ...Thenior wrote:Now what if the plane was holding still, and allowed the conveyor belt to give it a backward momentum of 100 knots. The plane would then have to apply at least 100 knots of propulsion from the opposite direction to become 0 knots. But the instant it reaches 100 knots propulsion, it would then begin to gain forward momentum.
But what if it was going backward @ 100 knots and only applied 20 knots of forward propulsion?
Lothar, it was funny to watch him do it. The runway ran in a northeasterly direction and the wind was almost always right down the runway. It was a private grass airstrip, so he didn't have to worry about other traffic most of the time. I saw him do it at least twice when the wind was the right speed. Strangest looking thing to watch.Lothar wrote:Pretty gutsy to take a 1000-pound airplane up in 33+ knot winds. They'd have to be remarkably constant...
Wrong. Momentum is simply mass times velocity; it applies both to linear and rotational speed.Floyd wrote:first: there is no "backward momentum", only backward speed.
right -- but you can't neglect friction (drag) from the equation. In general, an aircraft (or any other object) will accelerate until thrust equals drag. If you don't apply adequate thrust, the final speed will be below (dirty or clean) stall speed, meaning the aircraft won't be able to take off.you don't apply "knots" propulsion, but force of propulsion
oh. seems like a false friend. i should have looked up "momentum" before, which is "impuls" in german. what i have mistaken it for was "torque" (="moment" in german). thanks for pointing this out.Lothar wrote:Wrong. Momentum is simply mass times velocity; it applies both to linear and rotational speed.Floyd wrote:first: there is no "backward momentum", only backward speed.
Oh, I've no doubt that's true in the practical case. Even if the static friction of tires on runway is enough to prevent takeoff--and I'd think they'd want to design airplanes so that was generally true--it doesn't surprise me to hear that the kinetic friction isn't. But that's with the runway holding still.Krom wrote:The problem is no matter how fast you ran the treadmill the wheels would never generate sufficient friction to stop the plane, by the time the wheels exploded they would be immediately converted to bare metal skids on the treadmill which still wouldn't have enough friction. Likely the ONLY time the wheels have enough friction to do the job is when the plane is already stopped. Once it is moving with the engines at full thrust the tires are just going to slip and burn even if you lock the brakes.Drakona wrote:No, Woodchip is right, as snoopy hinted. A sufficiently fast conveyor belt will prevent the airplane from taking off. The wheels might be low friction, but they aren't zero. You just have to spin them fast enough. I mean, really fast enough.
I'll say that I think the drag of the wheels will increase as you increase in speed.Drakona wrote:Perhaps my grasp of physics is incomplete. I had been thinking the coefficient of kinetic friction between the surfaces would be the same, regardless of how fast the plane is going relative to the runway/conveyor. If that's true, then the amount of drag the runway applies to the airplane increases linearly with the relative speed of the runway. At some speed, the conveyor really is fast enough to cancel out the force the engine applies and prevent the airplane from taking off.
