Lift on aircraft wing

Putting this in very basic terms ,,and that there may well be plus and minus in the answers with regarding various wing shapes the question is

As i understand it the shape of a wing makes the air pressure passing over it less than the pressure under the wing. so if there is a figure of say 14 psi under the wing, what would be it above?

It's usually less than one psi of pressure difference between the upper and lower wing surface - often barely any difference at all on light aircraft with relatively big wings. Divide the wing loading (weight carried divided by wing area) in pounds/square foot by 144 and you get the theoretical pressure difference.

So for a Boeing 787 it's about 0.85psi (14psi under the wing, 13.15psi above). For an F-35A fighter it's 0.74psi, and for a Cessna 172 it's a hair under 0.1psi. For a modern sailplane it's 0.06psi.

But through the magic of physics, a small pressure over a big area can do a lot of work.

If you crunch the numbers - a fully laden Boeing 787 is generating 496,699 pounds-force via the pressure differential on its wing surfaces. But weighs over 502,000lbs. The Cessna is also just short of being able to lift its gross weight via wing pressure force alone. The difference comes from the lift generated by the wing's angle of attack; the wing is angled down from its leading edge and deflects air downwards.

These numbers are in the weird world of 'accurate but theoretical' - for any given specific flight condition the exact balance between lift generated by the Bernoulli principle and lift generated by angle of attack will be different, and of course the application of things like flaps, slats, droops etc. will change it further.

Loughborough Industrial Design

My job involves lots of poring over old drawings of aircraft and although I don't design ones that actually fly it helps to understand a bit about how they work.

I did originally want to go into aero engineering but struggled with A-level maths so took a slightly different course.

"Bernoulli's principle is not how wings generate lift" can of worms being opened in 3... 2....

It's normally specified in 1g flight - which is why fighters have lower wing loading than bombers

Have you appeared in that telly programme yet?

I did my best to avoid that.

Its almost as if you need to put a vertical acceleration into a mass of air to create a lift force....

The figures you quote don't make any sense to me without you stating the speed and angle of attack of the aircraft, do you mean at level cruising speed?

The lift of the wings may be limited to those figures by trim to maintain level flight but the wing will be capable of providing much more lift, if that were not the case the aircraft would never get off the ground.

Wing lift rises in proportion to the square of the airspeed so the wing will have a much higher lift capacity than the mass of the aircraft at speeds higher than take off.

To be honest, I think that referring to lift generated by Bernoulli, lift generated by pressure and lift generated by angle of attack is just a confusion.

all the lift generated comes via pressure on the wing (neglecting fuselage effects). If you increase angle of attack, then you increase the pressure differential (at a constant speed and altitude)

Angle of attack is just a reference, there's nothing special about zero degrees that says you get lift via a different phenomena to when you've got extra angrier of attack. It's just a way of setting how much lift you've got when the aircraft is on the runway.

So you've got just under 1g of lift on the take off run, then because you're slow you need a reasonable angle of attack to generate sufficient lift, and take off. Ignoring flaps, as you accelerate (so lift increases) but also climb (so lift decreases) you trim up and down the CL / alpha curve to keep 1g lift (ie 0.85ish psi in the example)