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Two non-aviation questions
1. If the principles of flight are universally applicable, why is it
that birds don't stall or spin? I wonder especially because I'm sure I've seen some gulls hover in mid-air doing pretty much nothing except having their wings spread! 2. We know it's possible for an aircraft to fly at angle to the direction in which it's pointing. Does anyone know why does such a thing not happen in boats or ships? After all, both ships and aircrafts use media to float on... any sailors here could answer that, I guess Ramapriya |
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1. If the principles of flight are universally applicable, why is it
that birds don't stall or spin? I wonder especially because I'm sure I've seen some gulls hover in mid-air doing pretty much nothing except having their wings spread! I'm not convinced that birds don't stall. However, they seem to know what to do about it, and do it instinctively. Also, birds can change their wings' shape and angle of incidence, and they can flap their wings if necessary, increasing the airflow over the wing (and doing other things). Most airplanes can't do that. Betcha their feathers act as excellent stall warning indicators too. Closely watch gulls hovering in a gusty wind... they are not frozen (watch their wings closely) and I bet every now and then they dip their nose. Near a stall? Maybe. Otoh maybe they just are good enough pilots that they stay away from the stall regeme. 2. We know it's possible for an aircraft to fly at angle to the direction in which it's pointing. Does anyone know why does such a thing not happen in boats or ships? After all, both ships and aircrafts use media to float on... any sailors here could answer that, I guess IT does happen with boats and ships, all the time. The standard vector problem in high school is a boat travelling across the river in a current. For more fun, consider sailing, where you travel at an angle to the wind and the ground, and the course you track is different from the direction from where you are to where you want to be (due to tacking). Planes can "skid" in the air to some degree, moving sideways through the air. Boats can also move sideways through the water, but it's harder since water is much more massive (though there is less weathercocking tendency (with respect to the water), in fact maybe even none, on a boat, and there is some in an airplane (which helps keep the mose pointed forward). Jose -- Freedom. It seemed like a good idea at the time. for Email, make the obvious change in the address. |
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"Ramapriya" wrote in message m... 1. If the principles of flight are universally applicable, why is it that birds don't stall or spin? I wonder especially because I'm sure I've seen some gulls hover in mid-air doing pretty much nothing except having their wings spread! Some kinds of birds stall all the time, they just don't spin since they recover immediately. Watch swifts or swallows feeding, or harriers hunting. They continuously stall, then recover. Gulls can't hover, they just fly forward the same speed as the approaching wind. Kestrels can hover, they do it by adjusting the angle of attack and thrust. Hummingbirds can, of course, hover. In fact, they can fly backwards. |
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Ramapriya wrote:
1. If the principles of flight are universally applicable, why is it that birds don't stall or spin? I wonder especially because I'm sure I've seen some gulls hover in mid-air doing pretty much nothing except having their wings spread! The direct answer is that they do, in fact stall, but as others have said, instantly recover by changing the shape of their wings. One of the funniest things I've ever seen was a flock of geese gracefully approaching a glassy smooth lake in Iowa for landing. Having misjudged their distance above the water, they flared a few feet too high, and promptly entered what was indeed a deep stall. Wings flapping, panic in their eyes, they dunked into the water. It was hilarious! As far as spins, birds have mechanisms to avoid asymmetric lift (which is the root cause of spins) that airplanes do not, like simply folding the unstalled wing. To sum up, generally speaking birds have excellent situational awareness that keeps them out of trouble most of the time, but they do make mistakes at which time they are better prepared to recover then man made flying machines. The gulls that "hover" are only hovering with respect to the ground. They cannot remain aloft without a relative wind providing their wings with lift, and they cannot maintain altitude without flapping unless they are in rising air. They simply use the rising air as their power source, and gliders do the same thing to achieve amazing durations of time aloft completely motorless. 2. We know it's possible for an aircraft to fly at angle to the direction in which it's pointing. Does anyone know why does such a thing not happen in boats or ships? After all, both ships and aircrafts use media to float on... any sailors here could answer that, I guess Ramapriya Crabbing does happen with watercraft - it's the same exact vector problem as in flying, only at a slower pace. Hope this helps. -Aviv |
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2. We know it's possible for an aircraft to fly at angle to the direction in which it's pointing. Does anyone know why does such a thing not happen in boats or ships? After all, both ships and aircrafts use media to float on... any sailors here could answer that, I guess In addition to the issue of boats traveling through water with a current, there is actually the issue of sailboats traveling through the water at a different angle from which they are pointed due to the push on the sail. This slip angle creates an angle of attack on the centerboard, daggerboard, or keel to provide an opposing force. John Bell www.cockpitgps.com |
#7
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(Ramapriya) wrote in news:30a8759c.0411070850.371c210
@posting.google.com: 1. If the principles of flight are universally applicable, why is it that birds don't stall or spin? I wonder especially because I'm sure I've seen some gulls hover in mid-air doing pretty much nothing except having their wings spread! 2. We know it's possible for an aircraft to fly at angle to the direction in which it's pointing. Does anyone know why does such a thing not happen in boats or ships? After all, both ships and aircrafts use media to float on... any sailors here could answer that, I guess Ramapriya Humming birds don't stall in stationary flight because their unique wing movements creat vortecies above and below their wings. The vorticies move air across the wings, and so they always have a forward relative wind, evan when hovering. |
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Ramapriya wrote: 2. We know it's possible for an aircraft to fly at angle to the direction in which it's pointing. Does anyone know why does such a thing not happen in boats or ships? It does -- it's called "leeway". Sailing ships and boats make more leeway than power ones do. George Patterson If a man gets into a fight 3,000 miles away from home, he *had* to have been looking for it. |
#9
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On Sun, 7 Nov 2004 at 20:11:39 in message
, John Bell wrote: In addition to the issue of boats traveling through water with a current, there is actually the issue of sailboats traveling through the water at a different angle from which they are pointed due to the push on the sail. This slip angle creates an angle of attack on the centerboard, daggerboard, or keel to provide an opposing force. An additional way of looking at this is to visualise that a boat sails because it has one lifting part (the hull, keel and rudder) in the water and another lifting system (the sails) in the air. The boat can move because there is a relative velocity between the two fluids. It is obvious you can sail if there is no wind at all provided you are in a tidal flow. Every one knows a sailing boat can tack up wind but can it tack down wind? The answer is not much, mainly I believe because of the much higher drag of the water. Sand yachts and ice yachts can, and they can sail on a reach, downwind faster than the wind is blowing. -- David CL Francis |
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"David CL Francis" wrote The boat can move because there is a relative velocity between the two fluids. It is obvious you can sail if there is no wind at all provided you are in a tidal flow. ******************** Not really. Relative velocity between the wind and water does not enter in, much. In the case of a tidal flow you cite, it would have to be one hell of a tidal flow; enough to make apparent wind, and a LOT, at that. With very slow wind speeds, there is not enough wind to keep the sail in in an airfoil shape, then you go nowhere, other than the speed of the water. Most flows do not reach a minimum speed. Every one knows a sailing boat can tack up wind but can it tack down wind? The answer is not much, mainly I believe because of the much higher drag of the water. Sand yachts and ice yachts can, and they can sail on a reach, downwind faster than the wind is blowing. -- David CL Francis More problems. Sailboats *can* tack down the wind. They often do, if they do not have a spinnaker. (Large parachute shaped sail, added while going down wind) Problem is, you have to go a lot faster to justify the extra distance. Usually, you just go down wind slower, and don't worry about it. The drag of the water *is* an issue, but not as you state. The boat, until you ride on top of the water, can go only so fast, almost irrespective of how much extra power you add. It is called hull speed, and generally speaking, it is higher, the longer the boat is. When you are going into the wind, the hull speed is not tough to get to, if the wind is strong enough. The maximum angle needs to be about 15 degrees or more away from straight into the wind. (again, generalities) The sail is acting like a wing, and airflow is accelerated around it to pull the boat into the wind, just like an airplane wing provides lift. The boat slips sideways, due to the wind pushing against the sail, which pushes sideways on the water, through the keel and rudder. That is what gives the drift. What kills downwind speed, is the fact that the sail is only acting as a barn door, or flat plat, using the wind pressure, and does not have lift in addition. Those are the main factors limiting down wind speed. In the case of ice boats and land boats, the lower friction removes the hull speed limitation. The craft continues to accelerate, until a wind that *was* coming from the side or partway from behind, now with increased hull speeds, will appear to come from the front of the craft, now called apparent wind. The sail can then act like a wing again, and use the lift to continue to go faster and faster. Problem is now, you can only go around 45 degrees into the wind, without slowing way down again. I hope I have made this all clear enough. -- Jim in NC --- Outgoing mail is certified Virus Free. Checked by AVG anti-virus system (http://www.grisoft.com). Version: 6.0.788 / Virus Database: 533 - Release Date: 11/1/2004 |
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