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BERNOULLI VS
NEWTON
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| Lift is the force that holds an aircraft in the air. How is
lift generated? There are many explanations for the generation of lift found
in encyclopedias, in basic physics textbooks, and on Web sites. Unfortunately,
many of the explanations are misleading and incorrect. Theories on the generation
of lift have become a source of great controversy and a topic for heated
arguments.The proponents of the arguments usually fall into two camps: (1)
those who support the "Bernoulli"
position that lift is generated by a pressure difference across the wing,
and (2) those who support the "Newton" position that lift is the
reaction force on a body caused by deflecting a flow of gas. So who is correct?
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Explanation of aerodynamic lift ( or downforce ) with only
Bernoulli Equation is not enough.The primary advantage of this explanation
is that is easy to understand and has been taught for many years. Because
of its simplicity, it is used to describe lift in most flight training manuals.
The major disadvantage is that is relies on the "principle of equal
transit times" which is wrong. This description focuses on the shape
of the wing and prevents one from understanding such important phenomena
as inverted flight, power, ground effect, and the dependence of lift on
the angle of attack of the wing.
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| Other description is based primarily on Newton's laws. The
physical description is useful for understanding flight, and is accessible
to all that are curious. Little math is needed to yield an estimate of many
phenomena associated with flight. This description gives a clear, intuitive
understanding of such phenomena as the power curve, ground effect, and high-speed
stalls. However, unlike the mathematical aerodynamics description, the physical
description has no design or simulation capabilities |
| Neither Newton nor Bernoulli ever attempted to explain
the aerodynamic lift of an object. |
| When a gas flows over an object, or when an object moves through
a gas, the molecules of the gas are free to move about the object; they
are not closely bound to one another as in a solid. Because the molecules
move, there is a velocity (speed plus direction) associated with the gas.
Within the gas, the velocity can have very different values at different
places near the object. Bernoulli's equation relates the pressure on the
object to the local velocity; so as the velocity changes around the object,
the pressure changes as well. Adding up (integrating) the pressure variation
times the area around the entire body determines the aerodynamic force on
the body. The lift is the component of the aerodynamic force which is perpendicular
to the original flow direction of the gas. The drag is the component of
the aerodynamic force which is parallel to the original flow direction of
the gas. Now adding up the velocity variation around the object instead
of the pressure variation also determines the aerodynamic force. The integrated
velocity variation around the object produces a net turning of the gas flow.
From Newton's third law of motion, a turning action of the flow will result
in a re-action (aerodynamic force) on the object. So both "Bernoulli"
and "Newton" are correct. Integrating the effects of either the
pressure or the velocity determines the aerodynamic force on an object.
We can use equations developed by each of them to determine the magnitude
and direction of the aerodynamic force. |
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| Downforce Wing Due to Bernoulli |
Downforce Wing Due to Newton |
Downforce Wing of Formula1 Car |
| So where is the argument? Arguments arise because people mis-apply
Bernoulli and Newton's equations and because they over-simplify the description
of the problem of aerodynamic lift. The most popular incorrect theory of
lift arises from a mis-application of Bernoulli's equation. The theory is
known as the "equal transit time" or "longer path" theory which states that
wings are designed with the upper surface longer than the lower surface,
to generate higher velocities on the upper surface because the molecules
of gas on the upper surface have to reach the trailing edge at the same
time as the molecules on the lower surface. The theory then invokes Bernoulli's
equation to explain lower pressure on the upper surface and higher pressure
on the lower surface resulting in a lift force. The error in this theory
involves the specification of the velocity on the upper surface. In reality,
the velocity on the upper surface of a lifting wing is much higher than
the velocity which produces an equal transit time. If we know the correct
velocity distribution, we can use Bernoulli's equation to get the pressure,
then use the pressure to determine the force. But the equal transit velocity
is not the correct velocity. Another incorrect theory uses a Venturi flow
to try to determine the velocity. But this also gives the wrong answer since
a wing section isn't really half a Venturi nozzle. There is also an incorrect
theory which uses Newton's third law applied to the bottom surface of a
wing. This theory equates aerodynamic lift to a stone skipping across the
water. It neglects the physical reality that both the lower and upper surface
of a wing contribute to the turning of a flow of gas. |
