How do airplanes fly with heavy weight and air resistance?

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In summary, an airplane flies because the wings create lift through a differential in air pressure created by the shape of the wing. This is supposedly caused by the curved shape of the wing at the top of the plane, and the force of the wind hitting the bottom of the wing. However, a documentary recently debunked this idea, saying that there is no air pressure difference since the laminar flow of the wind simply wraps around the wing and meets at the other side. Stability is provided by the tail on the plane, which makes the aircraft stable and allows it to be steered.
  • #1
ProgressNation
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I wonder how airplanes fly? I know maybe it's a tough question. Does the airplane fans produce huge force that makes the airplane boosts it's speed?The wings make it fly, and I don't know how it's tail works. But how do the airplanes fly according to it's heavy weight? Plus there is a big air resistance. I'd really love to know how the airplanes work, they're beautifully amazing!
Thank you!
 
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  • #2
This is kind of what the PF mentors typically consider an overbroad question. However, I'll interject one interesting tidbit here I just stumbled across because it's interesting and relevant to your question. I've always learned that airplanes fly because the wings create lift through a differential in air pressure created by the shape of the wing. Supposedly, the curved shape of the wing at the top causes air to move more rapidly there, creating a lower air pressure over the top of the wing which causes the plane to lift. However, I just recently watched a documentary that aimed to debunk this as a myth, saying that there is no air pressure difference since the laminar flow of the wind simply wraps around the wing and meets at the other side.

The actual cause of the lift, according to this documentary, was simply the force of the wind hitting the bottom of the wing, and that lift was created because planes fly slightly tilted with their pitch upward into the wind which forces the plane upwards. They debunked the pressure differential idea by saying if that were true, then planes wouldn't be able to fly upside-down, which they obviously could do. I thought that was kid of interesting. Unfortunately, I can't remember the name of the documentary.
 
  • #3
Thank you for sharing your answer, it's honor for me! But another thing that I want to know is that why does the airplane fans exist? Does the airplane fans exert very huge force which causes the airplane to accelerate very fast where can air resistance go through the wings and make it fly?
Thank you!
 
  • #4
See [thread=618500]this thread[/thread].
 
  • #5
Before long you will come across groups of people who argue endlessly over two different theories. One group say that lift is caused by the pressure difference above and below the wing. The other group say it's caused by the wing deflecting the air downwards. The real answer is both are correct...

http://www.grc.nasa.gov/WWW/k-12/airplane/bernnew.html
 
  • #6
Ok does the fan exerts a huge force to accelerate the engine?? If so, how?
 
  • #7
I don't know how it's tail works

That's one reason why it took man so long to figure out how to fly.

Put simply.. There are lots of different forces that act on an airplane. An airplane has to be designed so that if one of these forces causes the aircraft to pitch (point) up or down then other forces restore the balance. This is known as stability.

Consider a ball balanced on top of a hill. If you give it a slight knock it will roll off down the hill. The position of the ball is said to be "unstable". If you have a ball at the bottom of a valley and you give it a slight knock the ball may move but it will eventually return to it's original position. In this case the ball is said to be "stable".

The tail on a plane basically makes the plane stable. It also allows the plane to be steered but that's another story.
 
  • #8
ProgressNation said:
Ok does the fan exerts a huge force to accelerate the engine?? If so, how?

Start at the back of the engine...

Near the back there is a combustion chamber where fuel is burnt in compressed air. As it burns it expands and rushes out of the back of the engine. A turbine fan in this hot exhaust stream works like a windmill and drives a shaft running down the middle of the engine. This shaft power an air compressor in the centre and the big fan at the front.

The big fan does two jobs. It provides some air for the compressor in the core of the engine but it also sucks in a lot of air that bypasses the core and is sent straight out the back.

Pushing air backwards has the effect of pushing the plane forwards.
 
  • #9
CWatters said:
Before long you will come across groups of people who argue endlessly over two different theories. One group say that lift is caused by the pressure difference above and below the wing. The other group say it's caused by the wing deflecting the air downwards.

That's what I call the "Tastes great!" "No! Less filling!" debate over how airplanes fly. The real answer it's not an either/or proposition. Both explanations are correct.

The real answer is both are correct...
Birds of a feather!
 
  • #10
D H said:
That's what I call the "Tastes great!" "No! Less filling!" debate
:rofl:
 
  • #11
What do you guys make of the "New Theory of Flight" by Claes Johnson?

https://www.youtube.com/watch?v=t7e_6bkUFzE

http://secretofflight.wordpress.com/

Is this really something completely new, or just more detail? Does his "elegant separation" apply to stalled wings only, or in general?
 
  • #12
DiracPool said:
However, I just recently watched a documentary that aimed to debunk this as a myth, saying that there is no air pressure difference since the laminar flow of the wind simply wraps around the wing and meets at the other side.

This is incorrect. If there is a lift force that is generated by the air, it must be accompanied by a pressure difference. Further, the concept of laminar flow has essentially nothing directly to do with the generation of lift. It can affect the values of lift and drag, but it is not part of the fundamental reason lift exists.

DiracPool said:
The actual cause of the lift, according to this documentary, was simply the force of the wind hitting the bottom of the wing, and that lift was created because planes fly slightly tilted with their pitch upward into the wind which forces the plane upwards. They debunked the pressure differential idea by saying if that were true, then planes wouldn't be able to fly upside-down, which they obviously could do. I thought that was kid of interesting. Unfortunately, I can't remember the name of the documentary.

Well, they are mostly right. You can really look at lift two ways: either through the deflection of the air downward or through the pressure difference created on either side of the airfoil. Both of these can accurately describe the lift generated by a wing and both allow for a plane's ability to fly upside down. The thing that makes many of the pressure different explanations wrong is that they don't explain (or incorrectly explain) why that pressure difference exists (hint: it has nothing to do with "equal transit time"). If done correctly, you could solve for the flow around an airfoil and use the pressure differences to calculate lift and drag or draw a control volume around it and look at hte net momentum change due to action of the body and you would get the same answer for lift and drag. Both explanations work equally well. The pressure explanation is often a lot easier to use in practice, however.

Which brings me to...

CWatters said:
Before long you will come across groups of people who argue endlessly over two different theories. One group say that lift is caused by the pressure difference above and below the wing. The other group say it's caused by the wing deflecting the air downwards. The real answer is both are correct...

http://www.grc.nasa.gov/WWW/k-12/airplane/bernnew.html

As CWatters alludes to, this causes a downright comical debate between two warring factions who, in essence, are both correct anyway. It is sort of a chicken vs. egg debate.

A.T. said:
What do you guys make of the "New Theory of Flight" by Claes Johnson?

https://www.youtube.com/watch?v=t7e_6bkUFzE

http://secretofflight.wordpress.com/

Is this really something completely new, or just more detail? Does his "elegant separation" apply to stalled wings only, or in general?

This sounds like a bit of over-promoting their own work. They really didn't present anything new in that presentation, and I would even argue that some if it is wrong. For example, saying Kutta-Joukowski does not describe real physics is true by definition, as that theory makes the assumption that the flow is inviscid and incompressible, which obviously doesn't describe the real world. Further, pretty much everyone already knew that you had three major factors affecting lift and drag: vertical pressure differences, horizontal pressure differences and separation (viscosity would be another major contributor as well). I really see nothing new here. Further, I disagree with the idea that a large rounded-edge airfoil will necessarily produce lift. At low angle of attack with no separation, it would not. It requires that separation to prevent the flow from simply remaining symmetric.
 
  • #13
The thing that the 'pressure difference' brigade seem to ignore is the fact that there needs to be a net downwards motion of the surrounding air in order to produce a net lift force on the plane (reaction / rate of momentum change of the air). How that downward flow is achieved, and how efficiently, is what everyone is really arguing about, I think. The downdraught from a hovering helicopter is more noticeably there because all the displaced air is under the same spot in the sky. For a fixed wing craft, the effect is much more subtle because it's spread out over the whole of the flight path and any coherent motion will quickly be damped out and the kinetic energy dissipated.
Why do Scientists always want to say "this is what really happens" instead of "this model works"?

I did like the animations on that youtube sequence,
 
  • #14
Well if the air is being split by the winds at two different forces, wouldn't they be split into two component pressures and add together to the original pressure in the end?
 
  • #15
sophiecentaur said:
The thing that the 'pressure difference' brigade seem to ignore is the fact that there needs to be a net downwards motion of the surrounding air in order to produce a net lift force on the plane (reaction / rate of momentum change of the air).

The other side of that coin is that a lot of the downward deflection group like to ignore the fact that there also must exist a pressure difference and that the two are really part of the same phenomenon.

sophiecentaur said:
Why do Scientists always want to say "this is what really happens" instead of "this model works"?

Ego.
 
  • #16
sophiecentaur said:
..."this model works"...

This model always worked for me:

018653.jpg

There was also a version with a high power elastomer based engine, as I recall.

(google google google)

ah ha!

gl002__14767__42533.1351890032.1280.1280.jpg

That model worked too.
 
  • #17
Ego can often result in Egg on Face!

Om Cheeto - the wheels came off your idea!
 
  • #18
That pressure difference idea really sucks.
 
  • #19
sophiecentaur said:
That pressure difference idea really sucks.

Come now, science never sucks!

It blows.
 
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  • #20
DiracPool said:
The actual cause of the lift, according to this documentary, was simply the force of the wind hitting the bottom of the wing, and that lift was created because planes fly slightly tilted with their pitch upward into the wind which forces the plane upwards.

If by "simply" they mean "only", then how did they explain loss of lift when flow separates from the upper surface (e.g. "stall"), or when a wing deploy spoilers. How would they explain that blowing air between two sheets of paper will make the papers move closer to each other rather that away from each other?

In general you have to look at the complete flow to understand and model what is going on, and from that you can often give equivalent explanations using either forces, pressure differences, conservation of momentum, etc. As others also have noted, it may not make much sense to try assign one explanation as being more fundamental. However, what I think you can consider fundamental in this context, is that an air flow give rise to a lower static pressure (as the example with the two sheets of paper illustrate).
 
  • #21
Filip Larsen said:
If by "simply" they mean "only", then how did they explain loss of lift when flow separates from the upper surface (e.g. "stall"), or when a wing deploy spoilers. How would they explain that blowing air between two sheets of paper will make the papers move closer to each other rather that away from each other?

I don't think they got into it that deeply, it was a side note to some other main theme of the documentary. And I'm not taking sides, I'm no fluid mechanic, I just remember being a bit stunned when I heard it because I was brought up on the pressure differential model. But it kind of made sense to me having been a surfer for the first 30 years of my life. When you surf or waterski or wakeboard, you maintain lift above the surface through angling your nose up and deflecting the water down. You can slow down your velocity by driving your back foot down if you want to let the barrel catch up to you so you can get "tubed" :smile: If you angle the pitch of your nose high enough you actually will "stall" and fall off the wave. If you're a water skier, you start out underwater and "lift" to the surface through angling the pitch of your ski's or wakeboard upwards as the boat begins to pull you from rest. So, to me, this idea of lift being generated through the deflection of air downwards by the airfoil made sense. I had just never thought of it that way before since I had been indoctrinated into the pressure model. But I can see how both may play a combined role.
 
  • #22
DiracPool said:
The actual cause of the lift, according to this documentary, was simply the force of the wind hitting the bottom of the wing, and that lift was created because planes fly slightly tilted with their pitch upward into the wind which forces the plane upwards.
What documentary are you talking about? A link would be nice. There's a lot of junk science on the internet and on TV.

That explanation is pretty much bogus. It describes why a sheet of plywood gets lift. It does not explain how a well-designed wing gets lift. That sheet of plywood is pushed by the wind. A well designed wing gets most of its lift from the upper surface, not the bottom one.

They debunked the pressure differential idea by saying if that were true, then planes wouldn't be able to fly upside-down, which they obviously could do.
That sounds like a non sequitur.
 
  • #23
D H said:
What documentary are you talking about? A link would be nice. There's a lot of junk science on the internet and on TV.

I scoured my DVR but nothing rang a bell. I even ran a search online and couldn't find it. It was just a few minute segment of an hour show so I'm not surprised. However, I did come across an article in that search that is essentially the guy's argument verbatim, so here it is:

<crackpot link deleted>

Again, I'm not qualified to make a scientific assessment on this so it would be interesting to hear some of your reactions to it.
 
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  • #24
nst.john said:
Well if the air is being split by the winds at two different forces, wouldn't they be split into two component pressures and add together to the original pressure in the end?
Yes, after the air had moved across the surface of the wing.
When the flow is split and moveing over and below the wing then the pressure is different because one of the split flows travels a longer distance than the other over the wing, which gives rise to lift.
 
  • #25
Buckleymanor said:
Yes, after the air had moved across the surface of the wing.
When the flow is split and moveing over and below the wing then the pressure is different because one of the split flows travels a longer distance than the other over the wing, which gives rise to lift.

Is there a way to quantify the lifting force of that pressure difference taking in, say, the area of wing, angle of incidence to the incoming air, airspeed etc?
 
  • #26
DiracPool said:
Is there a way to quantify the lifting force of that pressure difference taking in, say, the area of wing, angle of incidence to the incoming air, airspeed etc?
Yes, though there would be a lot of variables to consider some of which I would probably miss.
If you were an aircraft designer, probably a piece of angel cake.
 
  • #27
Buckleymanor said:
Yes, though there would be a lot of variables to consider some of which I would probably miss.
If you were an aircraft designer, probably a piece of angel cake.

I guess there would have to be. That's what aerospace engineers do. That's why it's so puzzling to me why there is any ambiguity at all in this area. These engineers must know where the forces are coming from and what they are quantitatively and qualitatively, don't they?
 
  • #28
DiracPool said:
I scoured my DVR but nothing rang a bell. I even ran a search online and couldn't find it. It was just a few minute segment of an hour show so I'm not surprised. However, I did come across an article in that search that is essentially the guy's argument verbatim, so here it is:

<crackpot link deleted>

Again, I'm not qualified to make a scientific assessment on this so it would be interesting to hear some of your reactions to it.
As you might have noticed, I deleted that link. It has a few things right, but it also has far too many things that are flat out wrong.
 
  • #29
D H said:
As you might have noticed, I deleted that link. It has a few things right, but it also has far too many things that are flat out wrong.

Fair enough.
 
  • #30
Buckleymanor said:
Yes, after the air had moved across the surface of the wing.
When the flow is split and moveing over and below the wing then the pressure is different because one of the split flows travels a longer distance than the other over the wing, which gives rise to lift.

As was pointed out (I believe by bonehead) earlier in this thread, it isn't because the travel distance is different. The shape of the wing causes the air velocity over and under the wing to be dramatically different, and that is what "causes" lift (although as mentioned before, there are several correct ways to look at it).
 
  • #31
D H said:
That explanation is pretty much bogus. It describes why a sheet of plywood gets lift. It does not explain how a well-designed wing gets lift. That sheet of plywood is pushed by the wind. A well designed wing gets most of its lift from the upper surface, not the bottom one.

Interestingly, even a flat plate airfoil still gets a large fraction of its lift from the upper surface (possibly even a majority, but I don't know off the top of my head). There's no shape you can really make (to my knowledge) that will get almost all of its lift from the lower surface at low speed. At very high (high supersonic) speed, this can change, but that's an entirely separate problem
 
  • #32
I'd like to know how you define a portion of lift as coming from an upper or lower surface. I have never run across that statement except here on this forum. To be honest, I find that statement to be incredibly misleading in every logical way I can see it making sense.
 
  • #33
It is often said that with an engine big enough, you can make a barn door fly.

Note that does not necessarily imply a stable fly.
 
  • #34
cjl said:
As was pointed out (I believe by bonehead) earlier in this thread, it isn't because the travel distance is different. The shape of the wing causes the air velocity over and under the wing to be dramatically different, and that is what "causes" lift (although as mentioned before, there are several correct ways to look at it).

bonehead mentions, (hint: it has nothing to do with "equal transit time").
By that I reckon he is hinting that the transit times are not equal nor should be to creat lift.
If the shape of the wing by any design causes the air velocity over and under the wing to be dramatically different then you get lift.
It does not have to be the case that the shape of the wing causes the travel time to be different but when it does you still get lift.
You could apply flaps and creat drag in one direction to creat lift.
The distance can be the same or different but as you say it's the difference between air velocity over and under or vice versa that causes a pressure differential which causes lift?
 
  • #35
As a pilot,we are taught that lift is provided by both the pressure difference and the angle of attack of the wing, (angle between the chord line of the wing and the direction of motion) lift and drag both increase as aoa increases, up to the critical aoa, which is when the airflow separates from the top of the wing to cause a stall. Aoa must increase as speed decreases to maintain lift. At some speed the aoa required exceeds the critical aoa, and the plane stalls. To see an extreme example, google blue angels slow flyby, and you will see a pronounced nose up attitude comapred to the forward motion of the airframe. The op question is very broad, and covers a large part of the initial ground school for a private pilot, due to its complexity. I would highly recommend reading a book of some form on the subject, perhaps something aimed at the fledgling student pilot.

Apologies for errors in spelling and typos, am sending this via my tablet.
 
<h2>1. How do airplanes generate enough lift to fly with heavy weight?</h2><p>Airplanes generate lift through the use of their wings, which are shaped in a way that creates a difference in air pressure between the top and bottom of the wing. This difference in pressure causes the airplane to rise and stay aloft, even with heavy weight.</p><h2>2. Does air resistance affect the ability of airplanes to fly with heavy weight?</h2><p>Yes, air resistance, also known as drag, does affect the ability of airplanes to fly with heavy weight. The more weight an airplane has, the more drag it will experience, which can make it more difficult to maintain lift and stay in the air. However, airplanes are designed to minimize drag and still be able to fly with heavy weight.</p><h2>3. How do airplanes overcome air resistance when flying with heavy weight?</h2><p>Airplanes overcome air resistance by using powerful engines and aerodynamic design. The engines provide the necessary thrust to overcome drag, while the aerodynamic design of the airplane reduces the amount of drag it experiences. This allows the airplane to maintain lift and fly with heavy weight.</p><h2>4. Can airplanes fly with heavy weight at any altitude?</h2><p>No, airplanes cannot fly with heavy weight at any altitude. As altitude increases, the air becomes thinner and provides less lift for the airplane. This means that an airplane may not be able to generate enough lift to fly with heavy weight at higher altitudes. Pilots must carefully consider weight and altitude when planning a flight.</p><h2>5. How do pilots adjust for heavy weight and air resistance during flight?</h2><p>Pilots can adjust for heavy weight and air resistance by making changes to the airplane's speed, angle of attack, and altitude. They can also adjust the flaps and other control surfaces to optimize the airplane's aerodynamics. Additionally, pilots must carefully monitor the airplane's weight and balance to ensure safe and efficient flight with heavy weight and air resistance.</p>

1. How do airplanes generate enough lift to fly with heavy weight?

Airplanes generate lift through the use of their wings, which are shaped in a way that creates a difference in air pressure between the top and bottom of the wing. This difference in pressure causes the airplane to rise and stay aloft, even with heavy weight.

2. Does air resistance affect the ability of airplanes to fly with heavy weight?

Yes, air resistance, also known as drag, does affect the ability of airplanes to fly with heavy weight. The more weight an airplane has, the more drag it will experience, which can make it more difficult to maintain lift and stay in the air. However, airplanes are designed to minimize drag and still be able to fly with heavy weight.

3. How do airplanes overcome air resistance when flying with heavy weight?

Airplanes overcome air resistance by using powerful engines and aerodynamic design. The engines provide the necessary thrust to overcome drag, while the aerodynamic design of the airplane reduces the amount of drag it experiences. This allows the airplane to maintain lift and fly with heavy weight.

4. Can airplanes fly with heavy weight at any altitude?

No, airplanes cannot fly with heavy weight at any altitude. As altitude increases, the air becomes thinner and provides less lift for the airplane. This means that an airplane may not be able to generate enough lift to fly with heavy weight at higher altitudes. Pilots must carefully consider weight and altitude when planning a flight.

5. How do pilots adjust for heavy weight and air resistance during flight?

Pilots can adjust for heavy weight and air resistance by making changes to the airplane's speed, angle of attack, and altitude. They can also adjust the flaps and other control surfaces to optimize the airplane's aerodynamics. Additionally, pilots must carefully monitor the airplane's weight and balance to ensure safe and efficient flight with heavy weight and air resistance.

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