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Lift over foils
JAXAshby wrote in message
... jim, airspeed over a wing does not have to faster than airspeed below a wing for a wing to have lift. "bernoulli" sounds conventiently scientific to explain lift, but it ain't real. My assumptions were that we're talking subsonic, and substantially laminar flow. I made that clear. These assumptions are relevant to this group, since sails and keels aren't supersonic, and try to minimise flow breakaway in the interests of efficiency. To create lift (by changing the momentum of the passing air) there must be low pressure above the wing compared to the pressure below the wing. There will be tip vortices proving this point. I'm sure you accept this. Within my assumptions, to accept your flat statement: 'airspeed over a wing does not *have to [be]* faster than airspeed below a wing for a wing to have lift', I would need to understand where the energy due to this pressure drop goes. My assumption (perhaps incorrect) was that it goes into a temporary increase in kinetic energy - ie, an increase in local fluid speed. Whether this is or isn't Bernouilli is irrelevant. So, what assumptions do you make that allow this pressure drop not to be accompanied by a speed increase? Where does your energy go? Incidentally, I'm enjoying this revision of basic aerodynamics, and intrigued to learn what's changed since the 1970's, so keep going. It helps if you answer my questions directly. JimB |
Lift over foils
jim, the 'bernouli's" say the air is one unit at the leading edge of the wing,
and because it travels a shorter distance along the straight bottom surface than the longer top surface it therefore means the air along the top *had to* speed up to "catch up" with the air on the bottom, therefore less pressure. This is not true. it does not HAVE to. The most efficient wing surface out there is a thin sheet shaped into an "S", with the top forward part of the "S" the leading edge and the bottom rear part the trailing edge. Indentical distances for air to travel and the most lift available for the drag. (problem: andy particular "S" only works for one airspeed) Instead of thinking of "low" pressure and "high" pressure, think of what low and high means. high has more air molecules pressing against the surface at higher molecular speeds. low has fewer molecules and/or lower molecular speed of those molecules. To create lift (by changing the momentum of the passing air) there must be low pressure above the wing compared to the pressure below the wing. reword this using impact of molecules instead of low/high pressure and see what happens. |
Lift over foils
JAXAshby wrote in message ... jim, the 'bernouli's" say the air is one unit at the leading edge of the wing, and because it travels a shorter distance along the straight bottom surface than the longer top surface it therefore means the air along the top *had to* speed up to "catch up" with the air on the bottom, therefore less pressure. Bernouilli may have said that. I didn't. And I like symmetrical aerofoils, like rudders and keels, or ones that work well upside down as well as the right way up. This is not true. it does not HAVE to. I'm not proposing that the air 'has to catch up'. I'm just saying that if it loses pressure, it's got to gain speed (or disperse energy in some other way). The most efficient wing surface out there is a thin sheet shaped into an "S", with the top forward part of the "S" the leading edge and the bottom rear part the trailing edge. Indentical distances for air to travel and the most lift available for the drag. (problem: andy particular "S" only works for one airspeed) Now I think the device you're proposing is designed to add a downward speed to the air, then subtract that speed, leaving no net change in downward speed. Is that correct? If so, you're proposing that a net force can be generated by displacing air through a distance, rather than adding momentum to it. Interesting. I haven't heard of this design in aerodymamics before except in the context of windmills. I can see how such a device would generate a magnificent torque (lift at the front, cancelled by 'anti-lift' at the rear). This torque would have to be stabilised by a net lifting body on a lever arm for any practical application. But I am very out of date in this subject, so a few questions first: Has it been written up anywhere? Do you know any practical applications? For sure, I wouldn't want to fly upside down with this one. Nor use it for a keel. Instead of thinking of "low" pressure and "high" pressure, think of what low and high means. high has more air molecules pressing against the surface at higher molecular speeds. low has fewer molecules and/or lower molecular speed of those molecules. Yup. Got that. Brownian motion or some similar name and all that. But I don't see what difference it makes. To create lift (by changing the momentum of the passing air) there must be low pressure above the wing compared to the pressure below the wing. reword this using impact of molecules instead of low/high pressure and see what happens. Right: 'to create lift there must be fewer molecules at lower molecular speeds above the wing compared to the higher number of molecules at higher molecular speeds below the wing'. So? Jax, I hope you're not making the mistake of confusing the temperature/pressure linked random motion of molecules with the mean speed of a flow pattern! My point remains: 'there are fewer molecules at lower [random] molecular speeds above the wing' - so what did they sacrifice their energy to? My argument is that it could only go to an increased mean stream speed. Are you denying this? or am I out of date here as well? JimB |
Lift over foils
JAXAshby wrote in message ... jim, the 'bernouli's" say the air is one unit at the leading edge of the wing, and because it travels a shorter distance along the straight bottom surface than the longer top surface it therefore means the air along the top *had to* speed up to "catch up" with the air on the bottom, therefore less pressure. Bernouilli may have said that. I didn't. And I like symmetrical aerofoils, like rudders and keels, or ones that work well upside down as well as the right way up. This is not true. it does not HAVE to. I'm not proposing that the air 'has to catch up'. I'm just saying that if it loses pressure, it's got to gain speed (or disperse energy in some other way). The most efficient wing surface out there is a thin sheet shaped into an "S", with the top forward part of the "S" the leading edge and the bottom rear part the trailing edge. Indentical distances for air to travel and the most lift available for the drag. (problem: andy particular "S" only works for one airspeed) Now I think the device you're proposing is designed to add a downward speed to the air, then subtract that speed, leaving no net change in downward speed. Is that correct? If so, you're proposing that a net force can be generated by displacing air through a distance, rather than adding momentum to it. Interesting. I haven't heard of this design in aerodymamics before except in the context of windmills. I can see how such a device would generate a magnificent torque (lift at the front, cancelled by 'anti-lift' at the rear). This torque would have to be stabilised by a net lifting body on a lever arm for any practical application. But I am very out of date in this subject, so a few questions first: Has it been written up anywhere? Do you know any practical applications? For sure, I wouldn't want to fly upside down with this one. Nor use it for a keel. Instead of thinking of "low" pressure and "high" pressure, think of what low and high means. high has more air molecules pressing against the surface at higher molecular speeds. low has fewer molecules and/or lower molecular speed of those molecules. Yup. Got that. Brownian motion or some similar name and all that. But I don't see what difference it makes. To create lift (by changing the momentum of the passing air) there must be low pressure above the wing compared to the pressure below the wing. reword this using impact of molecules instead of low/high pressure and see what happens. Right: 'to create lift there must be fewer molecules at lower molecular speeds above the wing compared to the higher number of molecules at higher molecular speeds below the wing'. So? Jax, I hope you're not making the mistake of confusing the temperature/pressure linked random motion of molecules with the mean speed of a flow pattern! My point remains: 'there are fewer molecules at lower [random] molecular speeds above the wing' - so what did they sacrifice their energy to? My argument is that it could only go to an increased mean stream speed. Are you denying this? or am I out of date here as well? JimB |
Lift over foils
I haven't heard of this design ("S" shaped airfoils) in aerodymamics before
.... first semester aero eng books have had it for decades. It is not a practical airfoil, but it shows why foils lift. |
Lift over foils
I haven't heard of this design ("S" shaped airfoils) in aerodymamics before
.... first semester aero eng books have had it for decades. It is not a practical airfoil, but it shows why foils lift. |
Lift over foils
On Thu, 1 Apr 2004 10:33:19 +0100, "JimB"
wrote: I'm not proposing that the air 'has to catch up'. I'm just saying that if it loses pressure, it's got to gain speed (or disperse energy in some other way). ================================== Let's try for an intuitive approach using a flat plate (your hand, for example). Imagine sticking your hand out the window of a moving car and "flying" it through the air as most of us have probably done as a kid until our parents yelled at us. If you hand is more or less parallel to the ground, you have wind resistance (drag), but no lift. Tilt you hand slightly upwards and now the wind strikes the bottom of your palm and forces it upwards (lift). The reason lift is created is that your hand is deflecting molecules of air downwards (change in momentum), and the resultant force is upwards. It's simple Newtonian mechanics. |
Lift over foils
On Thu, 1 Apr 2004 10:33:19 +0100, "JimB"
wrote: I'm not proposing that the air 'has to catch up'. I'm just saying that if it loses pressure, it's got to gain speed (or disperse energy in some other way). ================================== Let's try for an intuitive approach using a flat plate (your hand, for example). Imagine sticking your hand out the window of a moving car and "flying" it through the air as most of us have probably done as a kid until our parents yelled at us. If you hand is more or less parallel to the ground, you have wind resistance (drag), but no lift. Tilt you hand slightly upwards and now the wind strikes the bottom of your palm and forces it upwards (lift). The reason lift is created is that your hand is deflecting molecules of air downwards (change in momentum), and the resultant force is upwards. It's simple Newtonian mechanics. |
Lift over foils
Wayne.B wrote in message ... On Thu, 1 Apr 2004 10:33:19 +0100, "JimB" wrote: I'm not proposing that the air 'has to catch up'. I'm just saying that if it loses pressure, it's got to gain speed (or disperse energy in some other way). ================================== Let's try for an intuitive approach using a flat plate (your hand, for example). Imagine sticking your hand out the window of a moving car and "flying" it through the air as most of us have probably done as a kid until our parents yelled at us. If you hand is more or less parallel to the ground, you have wind resistance (drag), but no lift. Tilt you hand slightly upwards and now the wind strikes the bottom of your palm and forces it upwards (lift). The reason lift is created is that your hand is deflecting molecules of air downwards (change in momentum), and the resultant force is upwards. It's simple Newtonian mechanics. It's OK Wayne. I understand the dynamics of lift reasonably well. I'm trolling to check that Jax also understands it. JimB |
Lift over foils
Wayne.B wrote in message ... On Thu, 1 Apr 2004 10:33:19 +0100, "JimB" wrote: I'm not proposing that the air 'has to catch up'. I'm just saying that if it loses pressure, it's got to gain speed (or disperse energy in some other way). ================================== Let's try for an intuitive approach using a flat plate (your hand, for example). Imagine sticking your hand out the window of a moving car and "flying" it through the air as most of us have probably done as a kid until our parents yelled at us. If you hand is more or less parallel to the ground, you have wind resistance (drag), but no lift. Tilt you hand slightly upwards and now the wind strikes the bottom of your palm and forces it upwards (lift). The reason lift is created is that your hand is deflecting molecules of air downwards (change in momentum), and the resultant force is upwards. It's simple Newtonian mechanics. It's OK Wayne. I understand the dynamics of lift reasonably well. I'm trolling to check that Jax also understands it. JimB |
Lift over foils
JAXAshby wrote in message ... I haven't heard of this design ("S" shaped airfoils) in aerodymamics before Naughty Jax. You've mis-quoted me by adding the bit in brackets. In full: "Now I think the device you're proposing is designed to add a downward speed to the air, then subtract that speed, leaving no net change in downward speed. Is that correct? If so, you're proposing that a net force can be generated by displacing air through a distance, rather than adding momentum to it. Interesting. *I haven't heard of this design in aerodymamics before* except in the context of windmills. I can see how such a device would generate a magnificent torque (lift at the front, cancelled by 'anti-lift' at the rear)." The design I was referring to was the technique of creating lift without adding downward momentum to the passing air, and I have asked if my understanding of your device (the S foil) and its working is correct. Because, I always thought that if there was a force, you had a linked change in momentum. So (unless I mis-understand you) you're proposing a revision of the basic laws of physics. Explain please. Without mis-quoting. JimB |
Lift over foils
JAXAshby wrote in message ... I haven't heard of this design ("S" shaped airfoils) in aerodymamics before Naughty Jax. You've mis-quoted me by adding the bit in brackets. In full: "Now I think the device you're proposing is designed to add a downward speed to the air, then subtract that speed, leaving no net change in downward speed. Is that correct? If so, you're proposing that a net force can be generated by displacing air through a distance, rather than adding momentum to it. Interesting. *I haven't heard of this design in aerodymamics before* except in the context of windmills. I can see how such a device would generate a magnificent torque (lift at the front, cancelled by 'anti-lift' at the rear)." The design I was referring to was the technique of creating lift without adding downward momentum to the passing air, and I have asked if my understanding of your device (the S foil) and its working is correct. Because, I always thought that if there was a force, you had a linked change in momentum. So (unless I mis-understand you) you're proposing a revision of the basic laws of physics. Explain please. Without mis-quoting. JimB |
Lift over foils
On Thu, 01 Apr 2004 23:25:21 -0500, Wayne.B
wrote: On Thu, 1 Apr 2004 10:33:19 +0100, "JimB" wrote: I'm not proposing that the air 'has to catch up'. I'm just saying that if it loses pressure, it's got to gain speed (or disperse energy in some other way). ================================== Let's try for an intuitive approach using a flat plate (your hand, for example). Imagine sticking your hand out the window of a moving car and "flying" it through the air as most of us have probably done as a kid until our parents yelled at us. If you hand is more or less parallel to the ground, you have wind resistance (drag), but no lift. Tilt you hand slightly upwards and now the wind strikes the bottom of your palm and forces it upwards (lift). The reason lift is created is that your hand is deflecting molecules of air downwards (change in momentum), and the resultant force is upwards. It's simple Newtonian mechanics. Nothing wrong with this explanation, as far as it goes. [Except possibly the idea that aerodynamics is 'simple Newtonian dynamics'. :-) ] But to answer the question, "Why does 2/3 of the lift come from the upper surface?" you might need to continue with some suggestion that the faster flow over and above the upper surface meeting the slower flow under and below the lower surface effectively turns the flow downwards which provides that change of velocity which with the air mass flow, provides the Newtonian mass rate times acceleration called the ' momentum change' - is the lifting force Brian W |
Lift over foils
On Thu, 01 Apr 2004 23:25:21 -0500, Wayne.B
wrote: On Thu, 1 Apr 2004 10:33:19 +0100, "JimB" wrote: I'm not proposing that the air 'has to catch up'. I'm just saying that if it loses pressure, it's got to gain speed (or disperse energy in some other way). ================================== Let's try for an intuitive approach using a flat plate (your hand, for example). Imagine sticking your hand out the window of a moving car and "flying" it through the air as most of us have probably done as a kid until our parents yelled at us. If you hand is more or less parallel to the ground, you have wind resistance (drag), but no lift. Tilt you hand slightly upwards and now the wind strikes the bottom of your palm and forces it upwards (lift). The reason lift is created is that your hand is deflecting molecules of air downwards (change in momentum), and the resultant force is upwards. It's simple Newtonian mechanics. Nothing wrong with this explanation, as far as it goes. [Except possibly the idea that aerodynamics is 'simple Newtonian dynamics'. :-) ] But to answer the question, "Why does 2/3 of the lift come from the upper surface?" you might need to continue with some suggestion that the faster flow over and above the upper surface meeting the slower flow under and below the lower surface effectively turns the flow downwards which provides that change of velocity which with the air mass flow, provides the Newtonian mass rate times acceleration called the ' momentum change' - is the lifting force Brian W |
Lift over foils
"Why does 2/3 of the lift come from the
upper surface?" it doesn't. 100% comes from the difference between the bottom and the top. obviously, the bottom is greater when the foil has lift. |
Lift over foils
"Why does 2/3 of the lift come from the
upper surface?" it doesn't. 100% comes from the difference between the bottom and the top. obviously, the bottom is greater when the foil has lift. |
Lift over foils
the faster flow over and above the upper surface meeting the slower
flow under and below the lower surface effectively turns the flow downwards which provides that change of velocity which with the air mass flow, provides the Newtonian mass rate times acceleration called the ' momentum change' - is the lifting force nah. that's barroom talk after the three beer. It won't design any airfoils at all. |
Lift over foils
the faster flow over and above the upper surface meeting the slower
flow under and below the lower surface effectively turns the flow downwards which provides that change of velocity which with the air mass flow, provides the Newtonian mass rate times acceleration called the ' momentum change' - is the lifting force nah. that's barroom talk after the three beer. It won't design any airfoils at all. |
Lift over foils
JAXAshby wrote in message ... the faster flow over and above the upper surface meeting the slower flow under and below the lower surface effectively turns the flow downwards which provides that change of velocity which with the air mass flow, provides the Newtonian mass rate times acceleration called the ' momentum change' - is the lifting force nah. that's barroom talk after the three beer. It won't design any airfoils at all. So, you don't agree that a change in momentum [of air] is needed to create a [lift] force? This seems to confirm that you live in a different universe from the rest of us, Jax . JimB |
Lift over foils
JAXAshby wrote in message ... the faster flow over and above the upper surface meeting the slower flow under and below the lower surface effectively turns the flow downwards which provides that change of velocity which with the air mass flow, provides the Newtonian mass rate times acceleration called the ' momentum change' - is the lifting force nah. that's barroom talk after the three beer. It won't design any airfoils at all. So, you don't agree that a change in momentum [of air] is needed to create a [lift] force? This seems to confirm that you live in a different universe from the rest of us, Jax . JimB |
Lift over foils
JAXAshby wrote in message ... "Why does 2/3 of the lift come from the upper surface?" it doesn't. Decades of aerodynamicists believe it does, based on the the evidence of thousands of surface pressure measurements by a variety of different methods, in flight and in wind tunnels. They've designed aircraft and their structures, then flown them, then tested them, based on this knowledge. Jax, I'm beginning to believe you come from a different planet. 100% comes from the difference between the bottom and the top. I'll go along with that self evident truth obviously, the bottom is greater when the foil has lift. Sure, the bottom has greater pressure than the top. You've just said that. But your phrasing was designed to mislead people into thinking that you'd said the 'bottom' contributed more lift than the 'top' contributed. And I can't believe that's what you meant. JimB |
Lift over foils
JAXAshby wrote in message ... "Why does 2/3 of the lift come from the upper surface?" it doesn't. Decades of aerodynamicists believe it does, based on the the evidence of thousands of surface pressure measurements by a variety of different methods, in flight and in wind tunnels. They've designed aircraft and their structures, then flown them, then tested them, based on this knowledge. Jax, I'm beginning to believe you come from a different planet. 100% comes from the difference between the bottom and the top. I'll go along with that self evident truth obviously, the bottom is greater when the foil has lift. Sure, the bottom has greater pressure than the top. You've just said that. But your phrasing was designed to mislead people into thinking that you'd said the 'bottom' contributed more lift than the 'top' contributed. And I can't believe that's what you meant. JimB |
Lift over foils
JimB wrote:
JAXAshby wrote in message ... jim, airspeed over a wing does not have to faster than airspeed below a wing for a wing to have lift. "bernoulli" sounds conventiently scientific to explain lift, but it ain't real. My assumptions were that we're talking subsonic, and substantially laminar flow. I made that clear. These assumptions are relevant to this group, since sails and keels aren't supersonic, and try to minimise flow breakaway in the interests of efficiency. To create lift (by changing the momentum of the passing air) there must be low pressure above the wing compared to the pressure below the wing. There will be tip vortices proving this point. I'm sure you accept this. Within my assumptions, to accept your flat statement: 'airspeed over a wing does not *have to [be]* faster than airspeed below a wing for a wing to have lift', I would need to understand where the energy due to this pressure drop goes. My assumption (perhaps incorrect) was that it goes into a temporary increase in kinetic energy - ie, an increase in local fluid speed. Whether this is or isn't Bernouilli is irrelevant. So, what assumptions do you make that allow this pressure drop not to be accompanied by a speed increase? Where does your energy go? Incidentally, I'm enjoying this revision of basic aerodynamics, and intrigued to learn what's changed since the 1970's, so keep going. It helps if you answer my questions directly. JimB How airfoils generate lift is one of my favorite subjects, so I can't resist bothering you folks with my (mostly uneducated) opinion. This is my currently favorite explanation of lift, which AFAIK is partly my own. And no, I'm not an expert. Possibly, some experts will get around to adding enough to this discussion to generate massive confusion in everyone, including themselves. Please keep in mind that I'm attempting to describe Reality, not theories. I think the key is in understanding that if air is given a place to flow to, it does not instantaneously fill the "void" to ambient pressure, but instead fills it at its own rate, according to local conditions. It also helps to remember that air is *not* a single entity (it's a collection of atoms and molecules) and that attempting to treat it as such is not always correct. Note: 'up' and 'down' are meant here as they would relate to normal flight. Lift generated by the interaction between the airflow and the bottom of the wing is easy to explain. It's a simple action-reaction event. If there is a positive angle of attack, the air is accelerated in a downward direction, causing an increase in pressure at the wing's lower surface. Less easily explained is how the wing's upper surface generates lift. If you are willing to keep it simple, it's easy to understand. As the wing moves forward through the air (or vice versa), it creates a "hole" (by that I mean an area of reduced pressure) in the current(as in time, not flow) air column that must again be filled by air until ambient pressure is reached. Because air molecules have mass and inertia, they don't all immediately rush to fill the hole. Some molecules are already there, but more arrive, then more, until the hole is finally filled to ambient pressure. Another way to put it: When the wing moves forward, its curved or sloped surface "yanks the floor out" from under the current air column, leaving the air to refill the space in its own way and its own time, which creates a temporary decrease in pressure. Because the wing's upper surface is in the area of reduced pressure, a lifting force occurs. "Yanking the floor out" can be further illustrated by what happens if you are in an elevator at the top of a tall building. As the elevator starts its downward movement, you can feel your weight temporarily decrease. That weight decrease would correspond to the pressure decrease on the surface of a wing. Because the wing is moving in relation to the air, it is continuously "yanking the floor out" from under its current air column, thereby generating a continuous lifting force. I'm sure this could have been written better, but hopefully you will get the meaning. |
Lift over foils
JimB wrote:
JAXAshby wrote in message ... jim, airspeed over a wing does not have to faster than airspeed below a wing for a wing to have lift. "bernoulli" sounds conventiently scientific to explain lift, but it ain't real. My assumptions were that we're talking subsonic, and substantially laminar flow. I made that clear. These assumptions are relevant to this group, since sails and keels aren't supersonic, and try to minimise flow breakaway in the interests of efficiency. To create lift (by changing the momentum of the passing air) there must be low pressure above the wing compared to the pressure below the wing. There will be tip vortices proving this point. I'm sure you accept this. Within my assumptions, to accept your flat statement: 'airspeed over a wing does not *have to [be]* faster than airspeed below a wing for a wing to have lift', I would need to understand where the energy due to this pressure drop goes. My assumption (perhaps incorrect) was that it goes into a temporary increase in kinetic energy - ie, an increase in local fluid speed. Whether this is or isn't Bernouilli is irrelevant. So, what assumptions do you make that allow this pressure drop not to be accompanied by a speed increase? Where does your energy go? Incidentally, I'm enjoying this revision of basic aerodynamics, and intrigued to learn what's changed since the 1970's, so keep going. It helps if you answer my questions directly. JimB How airfoils generate lift is one of my favorite subjects, so I can't resist bothering you folks with my (mostly uneducated) opinion. This is my currently favorite explanation of lift, which AFAIK is partly my own. And no, I'm not an expert. Possibly, some experts will get around to adding enough to this discussion to generate massive confusion in everyone, including themselves. Please keep in mind that I'm attempting to describe Reality, not theories. I think the key is in understanding that if air is given a place to flow to, it does not instantaneously fill the "void" to ambient pressure, but instead fills it at its own rate, according to local conditions. It also helps to remember that air is *not* a single entity (it's a collection of atoms and molecules) and that attempting to treat it as such is not always correct. Note: 'up' and 'down' are meant here as they would relate to normal flight. Lift generated by the interaction between the airflow and the bottom of the wing is easy to explain. It's a simple action-reaction event. If there is a positive angle of attack, the air is accelerated in a downward direction, causing an increase in pressure at the wing's lower surface. Less easily explained is how the wing's upper surface generates lift. If you are willing to keep it simple, it's easy to understand. As the wing moves forward through the air (or vice versa), it creates a "hole" (by that I mean an area of reduced pressure) in the current(as in time, not flow) air column that must again be filled by air until ambient pressure is reached. Because air molecules have mass and inertia, they don't all immediately rush to fill the hole. Some molecules are already there, but more arrive, then more, until the hole is finally filled to ambient pressure. Another way to put it: When the wing moves forward, its curved or sloped surface "yanks the floor out" from under the current air column, leaving the air to refill the space in its own way and its own time, which creates a temporary decrease in pressure. Because the wing's upper surface is in the area of reduced pressure, a lifting force occurs. "Yanking the floor out" can be further illustrated by what happens if you are in an elevator at the top of a tall building. As the elevator starts its downward movement, you can feel your weight temporarily decrease. That weight decrease would correspond to the pressure decrease on the surface of a wing. Because the wing is moving in relation to the air, it is continuously "yanking the floor out" from under its current air column, thereby generating a continuous lifting force. I'm sure this could have been written better, but hopefully you will get the meaning. |
Lift over foils
nonameneeded wrote in message . com... JimB wrote: JAXAshby wrote in message ... jim, airspeed over a wing does not have to faster than airspeed below a wing for a wing to have lift. "bernoulli" sounds conventiently scientific to explain lift, but it ain't real. Because the wing is moving in relation to the air, it is continuously "yanking the floor out" from under its current air column, thereby generating a continuous lifting force. Each person can visualise the causes of lift the best way it works for themselves. I can understand completely what you're saying, and it's a nice simile. Like all similes, it's incomplete, but that's irrelevant for sailors and pilots. Brian Walcott in his 1 Apr post gave an excellent, more thorough and technical description of the various elements of cause and effect when creating lift. I would guess he teaches fluid dynamics. Jax has been trying to say that you can create lift (low pressure over a wing) without causing air (in that low pressure) to speed up, and later, without causing air to move downwards. Rather than just telling him he's wrong, I've been trying to show him that his statements are inconsistent with with the laws of physics. So far he hasn't responded, apart from saying 'nah'. JimB |
Lift over foils
nonameneeded wrote in message . com... JimB wrote: JAXAshby wrote in message ... jim, airspeed over a wing does not have to faster than airspeed below a wing for a wing to have lift. "bernoulli" sounds conventiently scientific to explain lift, but it ain't real. Because the wing is moving in relation to the air, it is continuously "yanking the floor out" from under its current air column, thereby generating a continuous lifting force. Each person can visualise the causes of lift the best way it works for themselves. I can understand completely what you're saying, and it's a nice simile. Like all similes, it's incomplete, but that's irrelevant for sailors and pilots. Brian Walcott in his 1 Apr post gave an excellent, more thorough and technical description of the various elements of cause and effect when creating lift. I would guess he teaches fluid dynamics. Jax has been trying to say that you can create lift (low pressure over a wing) without causing air (in that low pressure) to speed up, and later, without causing air to move downwards. Rather than just telling him he's wrong, I've been trying to show him that his statements are inconsistent with with the laws of physics. So far he hasn't responded, apart from saying 'nah'. JimB |
Lift over foils
Let's try for an intuitive approach using a flat plate (your hand, for
example). Imagine sticking your hand out the window of a moving car and "flying" it through the air as most of us have probably done as a kid until our parents yelled at us. If you hand is more or less parallel to the ground, you have wind resistance (drag), but no lift. Tilt you hand slightly upwards and now the wind strikes the bottom of your palm and forces it upwards (lift). The reason lift is created is that your hand is deflecting molecules of air downwards (change in momentum), and the resultant force is upwards. It's simple Newtonian mechanics. .........nah........it's water skiing, which has nothing to do with airfoils (but does illustrate how the flaps help an airfoil at low speeds). High v, low p on top Low v, hi p on bottom (relative) lift QED cheers oz, flight test engineer, Edwards, 1968-71 |
Lift over foils
Let's try for an intuitive approach using a flat plate (your hand, for
example). Imagine sticking your hand out the window of a moving car and "flying" it through the air as most of us have probably done as a kid until our parents yelled at us. If you hand is more or less parallel to the ground, you have wind resistance (drag), but no lift. Tilt you hand slightly upwards and now the wind strikes the bottom of your palm and forces it upwards (lift). The reason lift is created is that your hand is deflecting molecules of air downwards (change in momentum), and the resultant force is upwards. It's simple Newtonian mechanics. .........nah........it's water skiing, which has nothing to do with airfoils (but does illustrate how the flaps help an airfoil at low speeds). High v, low p on top Low v, hi p on bottom (relative) lift QED cheers oz, flight test engineer, Edwards, 1968-71 |
Lift over foils
High v, low p on top
Low v, hi p on bottom (relative) lift QED cheers oz, flight test engineer, Edwards, 1968-71 you may have been a worker bee for the US Air Force but you don't have a clew as to the physics behind air foil lift. |
Lift over foils
High v, low p on top
Low v, hi p on bottom (relative) lift QED cheers oz, flight test engineer, Edwards, 1968-71 you may have been a worker bee for the US Air Force but you don't have a clew as to the physics behind air foil lift. |
Lift over foils
High v, low p on top
Low v, hi p on bottom (relative) lift QED cheers oz, flight test engineer, Edwards, 1968-71 you may have been a worker bee for the US Air Force but you don't have a clew as to the physics behind air foil lift. Oops; forgot .......and assoc. prof of physics, various universities. Don't have a clew right now, as I am negotiating for a boat. But clues, I have in abundance. cheers oz, who found the answer to his own question of a few weeks ago regarding JAX |
Lift over foils
High v, low p on top
Low v, hi p on bottom (relative) lift QED cheers oz, flight test engineer, Edwards, 1968-71 you may have been a worker bee for the US Air Force but you don't have a clew as to the physics behind air foil lift. Oops; forgot .......and assoc. prof of physics, various universities. Don't have a clew right now, as I am negotiating for a boat. But clues, I have in abundance. cheers oz, who found the answer to his own question of a few weeks ago regarding JAX |
Lift over foils
bull****.
High v, low p on top Low v, hi p on bottom (relative) lift QED cheers oz, flight test engineer, Edwards, 1968-71 you may have been a worker bee for the US Air Force but you don't have a clew as to the physics behind air foil lift. Oops; forgot ......and assoc. prof of physics, various universities. Don't have a clew right now, as I am negotiating for a boat. But clues, I have in abundance. cheers |
Lift over foils
bull****.
High v, low p on top Low v, hi p on bottom (relative) lift QED cheers oz, flight test engineer, Edwards, 1968-71 you may have been a worker bee for the US Air Force but you don't have a clew as to the physics behind air foil lift. Oops; forgot ......and assoc. prof of physics, various universities. Don't have a clew right now, as I am negotiating for a boat. But clues, I have in abundance. cheers |
Lift over foils
JAXAshby wrote in message ... High v, low p on top Low v, hi p on bottom (relative) lift QED cheers oz, flight test engineer, Edwards, 1968-71 you may have been a worker bee for the US Air Force but you don't have a clew as to the physics behind air foil lift. Jax! You've woken up again! What's your reason for insulting this fellow? Are you, as before, saying that if the pressure drops, the local air speed doesn't change? Are you once again confusing Brownian motion of molecules with the energy of an airflow? Are you once again proposing that lift can be created with an S foil which adds no net momentum to a passing airstream? Since you're rubbishing his qualifications (not his arguments) I think it's about time you told us your qualifications and experience in this field. JimB |
Lift over foils
JAXAshby wrote in message ... High v, low p on top Low v, hi p on bottom (relative) lift QED cheers oz, flight test engineer, Edwards, 1968-71 you may have been a worker bee for the US Air Force but you don't have a clew as to the physics behind air foil lift. Jax! You've woken up again! What's your reason for insulting this fellow? Are you, as before, saying that if the pressure drops, the local air speed doesn't change? Are you once again confusing Brownian motion of molecules with the energy of an airflow? Are you once again proposing that lift can be created with an S foil which adds no net momentum to a passing airstream? Since you're rubbishing his qualifications (not his arguments) I think it's about time you told us your qualifications and experience in this field. JimB |
Lift over foils
Subject: Lift over foils
From: (JAXAshby) Date: 4/14/2004 6:42 PM Central Daylight Time Message-id: bull****. ....appears to be confirmation of what the others were saying regarding the content of your messages. cheers oz, who has copies of proof, if you want to put money in escrow to back up your mouth (or fingers, in this case) |
Lift over foils
Subject: Lift over foils
From: (JAXAshby) Date: 4/14/2004 6:42 PM Central Daylight Time Message-id: bull****. ....appears to be confirmation of what the others were saying regarding the content of your messages. cheers oz, who has copies of proof, if you want to put money in escrow to back up your mouth (or fingers, in this case) |
Lift over foils
I
think it's about time you told us your qualifications and experience in this field. JimB minor thing. my baby brother used to write technical articles for the Experimental Aircraft Association. |
Lift over foils
I
think it's about time you told us your qualifications and experience in this field. JimB minor thing. my baby brother used to write technical articles for the Experimental Aircraft Association. |
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