Planar vibrating airfoilcould this idea work?

In summary, the conversation is about a concept for an airfoil that can provide vertical take-off and hovering, as well as forward or backward flight. The idea is to use Bernoulli's Principle and alternate the direction of air blowing over the airfoil to create lift. The feasibility of this concept is discussed, with one person suggesting the use of solenoids to move the airfoil back and forth at a high frequency. However, another person points out the potential flaws in this idea and suggests looking into bird and insect flight modes for inspiration. They also mention the importance of a leading edge vortex in creating lift.
  • #1
Frank Kecskes
13
0
I have a concept for an airfoil that might be capable of providing vertical take-off and hovering (as well as forward or backward flight), but I need feedback to see if this would be feasible from an engineering / aeronautical standpoint.

Bernoulli's Principle is classically demonstrated by by blowing air past the top of a drinking straw while the bottom is immersed in a glass of water. The resulting drop in air pressure within the straw causes the water to rise up in the straw.

Now imagine what would happen if air were blown across the top of the straw, alternating rapidly from the left and the right. The water would still rise in the straw as it does not matter from which direction the air is being blown...Correct? Then also, it should not matter whether the air itself is being blown, or the top end of the straw is being moved back and forth rapidly in relation the the air. It is all relative right?

So, now imagine an airfoil mounted so it can move rapidly back and forth causing the air to move over it's curved surface so as to generate lift. A system of solenoids could possibly push and pull such an air foil mounted to a frame, at say a distance of 1/2" back and forth. energizing the solenoids at the correct frequency could then approximate the speed of a conventional airfoil moving through the air at the correct speed to impart lift (in any direction or orientation) so that vertical take-off, hovering and forward / backward flight could be acheived...What are your thoughts?
 
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  • #2
Frank Kecskes said:
I have a concept for an airfoil that might be capable of providing vertical take-off and hovering (as well as forward or backward flight), but I need feedback to see if this would be feasible from an engineering / aeronautical standpoint.

Bernoulli's Principle is classically demonstrated by by blowing air past the top of a drinking straw while the bottom is immersed in a glass of water. The resulting drop in air pressure within the straw causes the water to rise up in the straw.

Now imagine what would happen if air were blown across the top of the straw, alternating rapidly from the left and the right. The water would still rise in the straw as it does not matter from which direction the air is being blown...Correct? Then also, it should not matter whether the air itself is being blown, or the top end of the straw is being moved back and forth rapidly in relation the the air. It is all relative right?

So, now imagine an airfoil mounted so it can move rapidly back and forth causing the air to move over it's curved surface so as to generate lift. A system of solenoids could possibly push and pull such an air foil mounted to a frame, at say a distance of 1/2" back and forth. energizing the solenoids at the correct frequency could then approximate the speed of a conventional airfoil moving through the air at the correct speed to impart lift (in any direction or orientation) so that vertical take-off, hovering and forward / backward flight could be acheived...What are your thoughts?

Pretty creative. Kind of a backward-forward wing movement. I think the main problem will be in the relative velocity of the wing wrt the still air. What is the typicaly helicopter blade velocity wrt the still air that provides lift? How fast would the oscillatory movement need to be to get close to that linear blade velocity?
 
  • #3
I can tell you for instance that the stall velocity of a single engine airplane is approximately 90 fps. If 1/2" back and forth movement were used, I calculate that the frequency of solenoid energizing would have to be 90ft x 12"/ft divided by 1/2" for a frequency of 2,169 Hz. This would approximate a relative velocity of 90 ft/sec to the air.
 
  • #4
On your downstroke, you're basically trying to create lift with a backwards airfoil - and that isn't going to work. To me, this idea is like a flapping wing vehicle - without the important components of pronation and supination. These are the important wing reversal strokes during the wing-beat kinematics of insects. It gives you a large peak force due to wake capture and unsteady aerodynamics at stroke reversal. Because you do not have that in your kinematics, your performance will be worse than an actual flapping wing configuration. You should look for papers by Dr. Micheal Dickinson at Caltech for more on flapping wing flight. I have the references on my website.
 
  • #5
Frank Kecskes said:
I can tell you for instance that the stall velocity of a single engine airplane is approximately 90 fps. If 1/2" back and forth movement were used, I calculate that the frequency of solenoid energizing would have to be 90ft x 12"/ft divided by 1/2" for a frequency of 2,169 Hz. This would approximate a relative velocity of 90 ft/sec to the air.

It does not make sense to talk about stall in terms of airspeed, as stall is airspeed independent. Stall is a function of the wing angle of attack.
 
  • #6
Hmm. Sorry to burst your bubble, but it wouldn't generate any lift to speak of. A wing requires about 4 cord lengths of travel before the bound vortex is developed to perhaps 90% of it's long term value. The bound vortex is required for lift.

However, refer to bird and insect flight modes that get around this problem.
 
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  • #7
Cyrus: So the Bernoulli analogy is flawed? Isn't the motion of air to air foil all relative? I am not advocating a "flapping airfoil" rather, one the moves forward and backward relative to the air...
 
  • #8
Phrak said:
However, refer to bird and insect flight modes that get around this problem.

Actually, that's exactly how they create lift, a leading edge vortex (among other things).
 
  • #9
Cyrus: Instead of thinking in terms of conventional airfoils, please explain how the "straw principle" analogy that I originally cited, would not apply to the airfoil I described...
 
  • #10
Frank Kecskes said:
Cyrus: So the Bernoulli analogy is flawed? Isn't the motion of air to air foil all relative? I am not advocating a "flapping airfoil" rather, one the moves forward and backward relative to the air...

My wording was a bit ambiguous. By "flapping" it can mean up/down (like a bird), or fore/aft (like an insect). My use of the word flapping here was insect like, which is what you're trying to do.

But, back to airfoils - think about it. When you're airfoil is on its reverse stroke, its flying 'backwards'. Airfoils don't like to do that.

*Note: In reality insects can have a culmination of up/down/fore/aft kinematics.
 
  • #11
Frank Kecskes said:
Cyrus: Instead of thinking in terms of conventional airfoils, please explain how the "straw principle" analogy that I originally cited, would not apply to the airfoil I described...

The problem with your analogy is that it is inadequate to explain how airfoils generate lift. They do so by having a pressure gradient along the chord. That pressure gradient is due to the flow over the airfoil. When you start moving in the reverse direction, the pressure gradient gets screwy and you won't produce a useful amount of lift.
 
  • #12
Cyrus: So why then does water rise in the straw due to pressure drop no matter from what direction the air is blown across the top of the straw??
 
  • #13
Cyrus said:
Actually, that's exactly how they create lift, a leading edge vortex (among other things).

Hu? A vortex still needs to be established. It doesn't happen all at once as soon as a lifting surface is in motion. The rate of development is dependent upon the viscosity of the fluid. Some birds use a flap-slap motion to initiate a vortex on each wing obtaining fairly instant lift.
 
  • #14
Phrak said:
Hu? A vortex still needs to be established. It doesn't happen all at once as soon as a lifting surface is in motion. The rate of development is dependent upon the viscosity of the fluid. Some birds use a flap-slap motion to initiate a vortex on each wing obtaining fairly instant lift.

See the references on my http://aerospaceindustrynews.webs.com/apps/blog/show/3261925-cta-mast" [Broken]. It has been well established that there is a leading edge vortex in flapping flight.
 
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  • #15
Cyrus: So, you are saying that a vortex is created within a straw when you blow across the top of it?
 
  • #16
Frank Kecskes said:
Cyrus: So why then does water rise in the straw due to pressure drop no matter from what direction the air is blown across the top of the straw??

When you blow over a straw, you are increasing the velocity of the air (going over the opening). This is an increase in dynamic pressure. As a result, the static pressure goes down inside the tube of the straw, and the water rises. However, this is not how an airfoil generates lift. An airfoil is generating lift by accelerating the air that passes over it due to its shape. You might get a better primer on airfoils http://www.allstar.fiu.edu/aero/flight31.htm" [Broken].
 
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  • #17
Frank Kecskes said:
Cyrus: So, you are saying that a vortex is created within a straw when you blow across the top of it?

No, not at all.
 
  • #18
Cyrus: So, if I take a flat sheet of paper and lay it o the table, and blow a jet of air across the top of it, it rises up. There is no leading edge geometry here, yet the pressure drop according to Bernoulli's Principle still applies...Correct?
 
  • #19
Frank Kecskes said:
Cyrus: So, if I take a flat sheet of paper and lay it o the table, and blow a jet of air across the top of it, it rises up. There is no leading edge geometry here, yet the pressure drop according to Bernoulli's Principle still applies...Correct?

Yes. In the case of your paper, you are supplying a jet of air. By doing so, the static pressure of that 'streamline' of air must be lower (due to Bernoulli). The paper then feels the low pressure of air flowing over top of it, and rises accordingly. In an airfoil, it does not work the same way because you are not supplying a jet of air. The airfoil is moving through the air and reducing the pressure* due to it's shape.

Well, keep in mind that Bernoulli's equation is valid along a streamline for steady flow and we assume viscous effects are negligible. None of this is true if you have a flapping airfoil, so it is incorrect to try and apply this equation to your oscillating airfoil.

*In the first 1/3, the airfoil reduces the pressure. But on the last 2/3rds it increases the pressure back to static at the trailing edge.
 
  • #20
Cyrus: Slightly changing the subject, what if I told you there is a way to electrostatically move the air across an airfoil (in one direction) by sequentially electrifying adjacent segments on the surface of an airfoil to approximate the airflow as in a conventionally used wing. And what if I told you that the laminar flow of such electrostaically moving air molecules could be made to be in a layer so thin that the energy required to move them in this fashion would be orders of magnitude less than what a prop or turbine or jet engine currently uses to move an aircraft through the air. Would that indeed be a technology worth while?
 
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  • #21
Frank Kecskes said:
Cyrus: Slightly changing the subject, what if I told you there is a way to electrostatically move the air across an airfoil (in one direction) by sequentially electrifying adjacent segments on the surface of an airfoil to approximate the airflow as in a conventionally used wing. And what if I told you that the laminar flow of such electrostaically moving air molecules could be made to be in a layer so thin that the energy required to move them in this fashion would be orders of magnitude less than what a prop or turbine or jet engine currently uses to move an aircraft through the air. Would that indeed be a technology worth while?

Interesting. I don't know, I'm skeptical if you could get such a thing to produce sufficient velocity to make any useful amount of lift. Are you saying this as a 'hypothetical' or have you actually made and tried this? It should be easy enough to test, all you need is a section of an airfoil attached to a bathroom scale. If it makes thrust, you'll know how much.
 
  • #22
Cyrus said:
See the references on my http://aerospaceindustrynews.webs.com/apps/blog/show/3261925-cta-mast" [Broken]. It has been well established that there is a leading edge vortex in flapping flight.

Of course there is. However, your response and website are completely nonsequitar to vortex generation. I suppose your focus is divided.
 
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  • #23
Cyrus: The sequential charging and discharging of adjacent strip electrode elements spanning the surface of an air foil is only limited by the controlling circuit. That being said, you could cause air molecules to be moved over the surface at whatever speed you chose. Then, by using a frequency of the appropriate value, any portion of the craft outfitted with such electrodes could become a lifting / pushing surface. You could for instance use this concept to provide enough lift and "push" to move an aircraft in any direction. A car outfitted with such an airfoil oriented as a front and rear bumper with sufficient surface area, could literally both move the car forward and also provide the braking action...all with the same principle and nothing to wear out except the generator or battery system providing the power for the electrification of the electrode segments on the airfoil...
 
  • #24
Phrak said:
Of course there is. However, your response and website are completely nonsequitar to vortex generation. I suppose your focus is divided.

I think I misread your post originally, my apologies. I'm not sure what about my response is not satisfying to you, because we are both saying the same thing (at least, I think we are).
 
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  • #25
Cyrus said:
I think I misread your post originally, my apologies. I'm not sure what about my response is not satisfying to you, because we are both saying the same thing (at least, I think we are).

We're both saying a simple to-and-fro motion won't work. You seem to be saying the trajectory and orientation of the lifting surface need to be properly done. I'm saying that it really doesn't matter.

Have you seen flow fields of nonviscous fluids over an airfoil shape? Begin with a two dimensional irrotational flow field around a circle. Conformally transform the circle to an airfoil shape. The field is still irrotational. Without the rotational component, there is no redirection of fluid velocity and no lift. This is the state of affairs for a perfect inviscous fluid.

Now take a viscous fluid in uniform motion, such as an airsteam first beginning to pass over an airfoil, it's rotation is everywhere zero. It's the stickiness of the air against foil surfaces and into the fluid volume that's required to change the angular momentum of the fluid in the region of the foil required to obtain lift. Once this is established, it will persist around the foil (hopefully, or stall results upon vortex shedding).

So it takes some time and friction between fluid and foil to get this process developed. If you move your foil back and forth, to get lift you have to establish first left handed then righthanded vorticity with each stroke.

This will not happen over a couple cord lengths or less, and the reversal of the stroke will first have to act to reverse the previous circulation. There's all this viscous action going on, half the time reversing what's already there.

I'd imagine that half the time, the foil could be being forced downward instead of up when it's out of phase. I dunno. I'm just guessing about this one. It only just occurred to me.
 
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  • #26
Phrak said:
We're both saying a simple to-and-fro motion won't work. You seem to be saying the trajectory and orientation of the lifting surface need to be properly done. I'm saying that it really doesn't matter.

But it does. The kinematics at the upstroke and down-stroke of insect flight highly depends on this kinematics, hence why I referenced those papers on my website. You will find that there are force peaks that you do not get using quasi-steady approximations.

Have you seen flow fields of nonviscous fluids over an airfoil shape? Begin with a two dimensional irrotational flow field around a circle. Conformally transform the circle to an airfoil shape. The field is still irrotational. Without the rotational component, there is no redirection of fluid velocity and no lift. This is the state of affairs for a perfect inviscous fluid.

Correct.

Now take a viscous fluid in uniform motion, such as an airsteam first beginning to pass over an airfoil, it's rotation is everywhere zero. It's the stickiness of the air against foil surfaces and into the fluid volume that's required to change the angular momentum of the fluid in the region of the foil required to obtain lift. Once this is established, it will persist around the foil (hopefully, or stall results upon vortex shedding).

Also correct, i.e., the boundary layer.

So it takes some time and friction between fluid and foil to get this process developed. If you move your foil back and forth, to get lift you have to establish first left handed then righthanded vorticity with each stroke.

Sure.

This will not happen over a couple cord lengths or less, and the reversal of the stroke will first have to act to reverse the previous circulation. There's all this viscous action going on, half the time reversing what's already there.

Well, that's why insects have pronation and supination kinematics, so they can use what is known as 'wake capture.' (again, see references for that if you want more detail).

I'd imagine that half the time, the foil could be being forced downward instead of up when it's out of phase. I dunno. I'm just guessing about this one. It only just occurred to me.

I'm not sure what you mean here.

Overall, nice post though :smile:.
 
  • #27
Ok, so I've been preaching to the choir. It happens. Without establishing or discovering common ground we'd be talking in circles. Pronation and supination is simple enough. I'll look over wake capture...when I can.
 
  • #28
Frank Kecskes said:
Cyrus: Slightly changing the subject, what if I told you there is a way to electrostatically move the air across an airfoil (in one direction) by sequentially electrifying adjacent segments on the surface of an airfoil to approximate the airflow as in a conventionally used wing. And what if I told you that the laminar flow of such electrostaically moving air molecules could be made to be in a layer so thin that the energy required to move them in this fashion would be orders of magnitude less than what a prop or turbine or jet engine currently uses to move an aircraft through the air. Would that indeed be a technology worth while?

I think if you were to electrify segments of the surface of an airfoil or any surface the air is not going to move in one direction parallel to the surface. Wouldn't the air move away from the electrified segment in all directions? I think I saw an episode of the mythbusters where they purchased some things on the internet that us an electric field to move the air downwards and produce thrust.
 
  • #29
Cyrus: each flat, electrode strip would go from the root of the wing to to the tip of the wing. Each wing would have several such electrodes parallel to one another. The sequence and polarity of energization would be as follows:

1. The leading edge elctrode is initially energized POSITIVE causing the first batch of air molecules in it's vicinity to become positively charged.

2. The adjacent elctrode is then negatively energized and attracts the positively charged air molecules. This electrode is then temporarily de-energized and the momentum of the air molecules in the first batch carry them past the second electrode.

3. The second electrode is then positively energized, "pushing" this first batch further toward the trailing edge.

4. The process continues until the first batch of air molecules (through successive electrostatic "push-pull" sequences) pass over the airfoil via the remaining elctrode strips all the way to the trailing edge of the wing.

Another way to look at it is as follows: An electric motor uses timed energization and denergization of electromagnets to "push-pull" the tangential edge of a rotor around and around. A linear motor or rail gun does the same, but in a linear, straight line form of motion.

So, the elctrostatic airfoil does the same thing with batches of air molecules being "push-pulled" in one direction, over the surface of an airfoil, by electrostatic means. Given the correct electrostatic potential, sequence and frequency of energization and de-energization of electrode segments, a laminar flow of air can be made to move across an airfoil at any desired speed.
 
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  • #30
Frank Kecskes said:
Cyrus: each flat, electrode strip would go from the root of the wing to to the tip of the wing. Each wing would have several such electrodes parallel to one another. The sequence and polarity of energization would be as follows:

1. The leading edge elctrode is initially energized POSITIVE causing the first batch of air molecules in it's vicinity to become positively charged.

2. The adjacent elctrode is then negatively energized and attracts the positively charged air molecules. This electrode is then temporarily de-energized and the momentum of the air molecules in the first batch carry them past the second electrode.

3. The second electrode is then positively energized, "pushing" this first batch further toward the trailing edge.

4. The process continues until the first batch of air molecules (through successive electrostatic "push-pull" sequences) pass over the airfoil via the remaining elctrode strips all the way to the trailing edge of the wing.

Another way to look at it is as follows: An electric motor uses timed energization and denergization of electromagnets to "push-pull" the tangential edge of a rotor around and around. A linear motor or rail gun does the same, but in a linear, straight line form of motion.

So, the elctrostatic airfoil does the same thing with batches of air molecules being "push-pulled" in one direction, over the surface of an airfoil, by electrostatic means. Given the correct electrostatic potential, sequence and frequency of energization and de-energization of electrode segments, a laminar flow of air can be made to move across an airfoil at any desired speed.

I do not know much about ionizing air with an electric field but I think the resulting airflow would be actually be turbulent and unsteady. Once the polarity of an electrode is switched to begin pushing the molecules it will not only push them parallel to the surface, it will also push some molecules upwards away from the surface. At the same time the electrodes attracting any molecules will also be pulling them downwards towards the surface. Once an electrode is turned off to allow the air's momentum to carry it past the electrode the air will begin to slow down and due to the shear layer it would roll up and become turbulent.

But at the same time I have seen electrodes being used as a flow control device to improve the flow over a turbine blade. Although it was only being used to energize the boundary layer and delay separation. You could always build this thing and find out. It doesn't sound like it would be to difficult.
 
  • #31
Regarding the OP's idea: rather than having the wings oscillate back and forth, why not just attach them to a central pivot point and rotate them around in a circle...?
 

1. What is a planar vibrating airfoil?

A planar vibrating airfoil is a type of airfoil that is designed to generate lift by vibrating instead of through traditional methods such as angle of attack or shape. It is often used in the development of micro air vehicles and drones.

2. How does a planar vibrating airfoil work?

The planar vibrating airfoil works by creating small vibrations along its surface, which creates a change in pressure that results in lift. This is similar to how traditional airfoils work, but the vibrations allow for more control and maneuverability.

3. What are the potential benefits of using a planar vibrating airfoil?

One potential benefit of using a planar vibrating airfoil is its ability to generate lift at low speeds, which can be useful for small and lightweight aircraft. It also allows for more precise control and maneuverability, making it ideal for applications that require precise movements.

4. Are there any limitations or challenges to using a planar vibrating airfoil?

One limitation of using a planar vibrating airfoil is that it may not be as efficient as traditional airfoils at higher speeds. Additionally, the vibrations can cause added stress on the structure of the airfoil, which may require additional maintenance and support.

5. Has the concept of a planar vibrating airfoil been tested or implemented in real-world applications?

Yes, the concept of a planar vibrating airfoil has been tested and implemented in various real-world applications, including micro air vehicles and drones. However, more research and development is needed to fully optimize and improve the design for different uses and environments.

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