But my intuition about how the main rotor could be made to tilt the body (to go forward/backwards/right/left) was completely wrong. It turns out each rotor blade can tilt on its long axis, in two ways. They can be tilted all in lockstep, which affects their general lifting power. But what's really nifty, and what I never would have guessed, is that the machine will automatically cause each rotor to tilt individually just as it reaches the point in its cycle that's in the direction the pilot wants to go, and then flip back when it passes that point. Now that's a fast adjustment! I had vaguely in mind that the whole rotor system, including its axis, must be tiltable, but then on reflection that couldn't have been right. Tilt each rotor blade one at a time as it reaches a particular point in its superfast rotation! Very clever. No wonder helicopters need such obsessive levels of maintenance.
And now for Bernoulli, and my indistinct memory of reading a quibble about the explanation for lift that we carry around in our heads: the wing is shaped with a big curve on top and a much flatter one below, so when air passes it must go faster on top in order to traverse the same distance, resulting in higher pressure below the wing and lower pressure above, ergo lift. But, you ask, who says the the air on top has to get to the back of the wing at the same time as the air below? And in fact it doesn't: it gets there a lot faster; the air on the bottom never catches up. Hmm.
The Wiki lift article claims that the Bernoulli equation itself just describes what will happen if you assume a speed differential above and below the wing, which can be observed experimentally. In order to explain and predict the observed speed differential, you need a more involved treatment of conservation of momentum, mass, and energy, and Navier-Stokes equations that can't readily be solved, and simplifying assumptions about viscosity that allow them to be approximated for some conditions. I'll just have to take their word for it: experimentation tells us that if you mold a proper wing shape and use the right angle of attack at a good speed, you'll get an airspeed differential and lift. In my brain, that gets filed under "magic."
5 comments:
That explains vortices in the trailing wake.
Hah- classic: I thought I had a lightbulb moment about understanding vortices left behind an airfoil, but I thought the faster airflow on top would spin them clockwise looking at a wing moving to the left- alas it's the opposite! The faster speed of the air coming off the upper surface pushes down and backspins the vortices and breaks them off the flow successively. Fascinating. (google "starting vortex")
Yes, magic is the right answer.
My husband tells me that all these cross-section models assume that the wing is of infinite length, so that there are no edge conditions to speak of. But it turns out that the edge conditions for a real wing may be contributing more to lift and performance than the "ideal" conditions that theoretically prevail in the mid-wing area.
He also points out that no one tries to solve Navier-Stokes equations any more. They break the problem into tiny finite elements and crunch the numbers with the brute force of a supercomputer. It ain't elegant, but it gets the job done.
Helicopters don't fly, they beat the air into submission
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