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If you want to go flying about in an aeroplane, it's nice to be able to control that flight. To do this, several methods have been developed. You can change the engine thrust to go faster or slower, but this might not be enough control if you're pointed at a mountain.
The solution is control surfaces
which come in a variety of flavors. Perhaps the most obvious to a casual airline passenger is the ailerons. These are movable surfaces mounted on the trailing edge of the outer portion of the wing. Move it down, and the effect is to modify the aerofoil shape of the wing to provide more lift. On the opposite wing, the other aileron moves up, reducing the lift of that wing and there is a net force rolling the aircraft. The same principle is in play with the rudder and elevator on the tail of the aircraft, with some modifications. Elevators usually work together, and they may be split into an all-moving horizontal stabilizer with elevators on the trailing edge. The point being that changing the pitch/roll/yaw of an aircraft requires changing the shape of the related aerodynamic surfaces*.
Movable control surfaces are UNdesirable for a number of reasons:
They require moving parts, these wear out and require servos/jacks/cables etc. to be routed throughout the aircraft.
They mess with stealth. Stealth requires VERY careful control of the aircraft shape and movable control surfaces hurt this badly and mitigation is tricky. The B2 for example has gone to great lengths to remove traditional control surfaces and mitigate movement of the remaining ones.
So how can we achieve the effect of movable control surfaces without movable control surfaces? What is the basic effect we are trying to achieve? Well, an aileron moving down increases the pressure under that portion of the wing and decreases it above the wing. The pressure difference creates extra lift. Can we change the pressure by other means? Yes!
If we place thermoelectric/Peltier elements in-between the upper and lower surfaces of a wing and apply a current, the Peltier will cool the upper surface and heat the lower surface, effectively pumping the heat from top to bottom (with some excess heat from the element inefficiency.). PV-nRt demonstrates that cooling the air will reduce pressure/volume and heating it will increase pressure/volume causing a bigger difference between the two and therefore increased lift. We do the opposite on the other wing and now we have our rolling moment with no change in wing shape.
The same principle can be applied to all the control surfaces. Furthermore, there are opportunities to subtly modify the properties of aerofoils. For example, Peltiers could be used to locally heat & cool parts of a wing aerofoil to make it behave as if it were thicker/thinner or a different profile, e.g. moving the point of maximum thickness back for more efficient high speed flight. For more robust effects, the fuel can be used as a heat sink/source, which would allow other control options, for example in a flying wing, one wing could be cooled and the heat pumped via the fuel to the other. Aerodynamically, one wing would behave as if it were thicker than the other giving a drag difference and a yaw moment - no rudder required.
I'm under no illusions that the forces generated would be small compared to conventional movable control surfaces, but I'm not suggesting this for a dogfighter. Applications like the B2/B21 and small stealthy drones where subtle control inputs are all that's required are most suitable.
*Two notable exceptions to this: 1. Vectored thrust, e.g. the F22 uses movable jet exhaust nozzles to direct thrust up or down to change pitch. 2. Center of gravity manipulation, e.g. Concorde pumped fuel rearward during supersonic flight to avoid the drag associated with elevon deflection as the center of lift moved back.
Icing problem?
https://youtu.be/BPPValf3lcY
[21 Quest, Jul 27 2023]
Improvement of Airfoils Aerodynamic Efficiency by Thermal Camber Phenomenon
https://www.scielo....SvLNyVtrHmj6qq8cHJ/
cooling upper surface and heating lower surface, namely thermal camber, generate lift force and improve aerodynamic performance for symmetric airfoils at a 0° Angle of Attack (AOA). These improvements are more than the airfoils with physical camber. [a1, Jul 27 2023]
Effects of heat transfer on aerodynamics and possible implications for wind tunnel tests
https://www.science...ii/037604219090001Z
Cooling the surface delays flow separation and thus is roughly equivalent to an increase in Reynolds number. Conversely heating promotes flow separation and is roughly equivalent to a decrease in Reynolds number. [a1, Jul 27 2023]
Looks like DARPA is all over this
https://www.militar...-surfaces-actuators
[21 Quest, Jul 28 2023]
Sorry, THIS is the DARPA one
https://newatlas.co...darpa-crane-aurora/
[21 Quest, Jul 28 2023]
Sub, Trans and supersonic drag reduction
https://arc.aiaa.org/doi/10.2514/2.6504
[bs0u0155, Jul 28 2023]
Plasma Hypersonic Drag reduction
https://www.thedriv...nprecedented-speeds
[bs0u0155, Jul 28 2023]
"Boundary Layer Control" on the Blackburn Buccaneer.
https://en.wikipedi...Blackburn_Buccaneer
[bs0u0155, Jul 28 2023]
[link]
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If you make the aircraft disk shaped maybe you could get all the thrust, lift, and attidude control by heating or perhaps electircally charging various parts of the surface. Should be very quiet, at most giving off a little electrical hum. |
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Why disk shaped? A cube would be easier to manufacture and would offer greater cargo / passenger capacity |
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You're going to cool the wing surface itself, but what you'd need for this to work is to cool the mass of air above/below the wing. As fast as that air is moving, this isn't going to do that, and may well create a dangerous icing problem. To cool a volume of air, a peltier cooler needs that air to be confined on one side of it. |
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Furthermore, peltier coolers (from what I've read) are typically able to maintain about a 60° temperature differential between the 2 sides. I'm pretty sure sunlight already does that. |
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//but what you'd need for this to work is to cool the mass of air above/below the wing. As fast as that air is moving, this isn't going to do that,// |
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It will cool/heat SOME of the boundary layer air to SOME extent. I admit, I'm not in a position to calculate how much effect it would have, especially given the wide variety of potential flight regimes. Perhap a better application might be in more favorable conditions. A supersonic intake has zones of high temperature and density, maybe there's scope for trading heat/pressure/volume in there. |
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//may well create a dangerous icing problem// |
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I think icing is understood to the point where you could avoid this, icing occurs in transitional parts of jet aircraft flight envelopes, principally climbing or descending through cloud layers with near freezing/supercooled water. Most jet flight occurs >30,000ft where the air is super cold and dry. For stealth reasons, you wouldn't fly through icing cloud conditions anyway you'd stand out like a sore thumb. |
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//peltier coolers (from what I've read) are typically able to maintain about a 60° temperature differential// |
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It's not so much about the temperature as the heat (energy) pumped which works quite efficiently at low ish delta t and with a lot of flow. |
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// Why disk shaped? A cube would be easier ... // |
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Cultural acceptance. Earthers are have been used to flying saucers since the 1940's, but since 1989, Star Trek has put the bad guys in cube-shaped ships. |
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Interesting/innovative idea. [+] My gut is that it would take huge power with very little measurable effect. Good reason to post hear than paying for a patent... |
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//Good reason to post hear than paying for a patent...
// |
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Cheaper to make a model, or simpler still a model wing in a wind tunnel. |
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a1, thanks for the links, it works! I googled around the subject to some degree focusing on control surfaces and pumping heat, but clearly not on aerofoil basics. Have printed and will have a read with a beer or two! |
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My superpower is composing search phrases. But I don't undertand any of what I find. |
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Too slow, don't you think? Captain: "Pull up! Pull up!" Siri: "Correct delta will be achieved in approximately 15.73 seconds, sir. That will be 12 seconds after we impact the building." |
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Usefulness will depend on scale. It may be effective for micro-sized UAVs but diminishingly so the bigger the aircraft is. At some scales it might only be useful for trim adjustments. Hedging now, don’t really know - but I think the potential drag reduction may be worth more than trim control and would scale up better. |
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Somewhere in the depths of my mind, there is a little memory of a hypersonic aircraft with a small (high-pressure) burner on the nose, to get very hot gas flowing over the whole body. A bit of Googling turned up nothing. |
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// a hypersonic aircraft with a small (high-pressure) burner on the nose, to get very hot gas flowing over the whole body. // |
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An actual flying (research?) vehicle, a wind tunnel model, or just a computer simulation? Sounds like somthing that would have been made to study _gas injection and hypersonic heat transfer._ |
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The underlined search phrase might turn up the one you're looking for. |
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//hypersonic aircraft with a small (high-pressure) burner on the nose, to get very hot gas flowing over the whole body.// |
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That's the mechanism behind the super fast torpedos. But the same principle shows up only with plasma generators <link(s)> |
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21 DARPA are reusing old tricks dressed up in a bit of language. This used to be called "blown flaps" or similar. The Blackburn Buccaneer <link> had blown flaps for hi-lift AND blown tail surfaces for enhanced control as it was a relatively large and heavy aircraft for British carriers at the time. Other aircraft like the F104 had blown flaps, the downside being that in a single-engine aircraft, an engine failure meant a simultaneous loss of thrust AND lift. This matters a lot less with drones. |
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