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Stall Control

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Tony Elliott 05/2008 Page 1 Wings, Wings, Wings Stall Control with camber changes Martin Simmons has done an excellent job of describing many aspects of lifting systems and the numerous details that need to be considered to achieve efficient and well designed solutions. The key concept to note however, is that there are MANY variables that need to be considered when designing lifting surfaces. This short paper is written to expand on the details written in Martin Simmons Model Aircraft Aerodynamics publication as it relates to stall control by camber changes. One has to remember that you cannot design a lifting system to meet an infinite variety of flight conditions. It simply is not feasible with current technology. Many attempts have been made over many years to develop variable geometry wing surfaces specifically to enhance a limited flight envelope but the solutions are complex, expensive and invariably heavy. The key to remember in the details that follow is that we are attempting to design a wing system that meets a specific flight envelope one that has a known and controllable slow speed stall point and a known, designed top speed with a never to exceed speed. So, let’s look at a simple solution for tip stall control through camber and physical twist variation in a tapered wing. Note: in the discussions that follow, one core assumption is made. I have assumed the same as Martin Simmons in that an Elliptical lift distribution exists across the span of the wing. This is a key assumption. I can personally see why one might assume that a wash-in might be required with a higher cambered tip airfoil based on the aerodynamic zero lift angle of attack parameter. It may seem intuitive that this might be the case IF your point of reference is the zero lift angles of attack ONLY. However, as noted above, there are other factors that need to be considered to understand why this would be the wrong course of action. Adding a higher cambered airfoil to the wing tip and then introducing wash-in would cause significant flight issues with a considerably smaller flight envelope and significant tip stalling characteristics. To understand the concept of increased camber at the wing tip with WASH-OUT introduced to counter aerodynamic wash-in one must review the lift curves of a specific family of airfoils with varying cambers. This is shown in Martin Simmons book as Fig 7.4. You will notice that the lift curves move to the left and upwards on the graph as camber increases. What is also apparent is the increasingly negative aerodynamic zero-lift angles of attack as the camber increases. However, what is NOT so apparent is the reduction in geometric (physical) angle of the stall angle that occurs as the camber increases. This is shown in Martin Simmons diagram (7.4) where the coefficient of lift max intersects with the angle of attack horizontal axis in the middle of the graph (notated by “N.B. geometric stall angles). Let’s summarize those three points: 1). As camber increases, the lift curves move left and upwards on the lift/angle of attack graph 2). As camber increases, the zero-lift angle of attack increases negatively 3). As camber increases, the physical angle of attack at which the airfoil stalls decreases So let’s see what all this means:
Transcript
Page 1: Stall Control

Tony Elliott – 05/2008 Page 1

Wings, Wings, Wings – Stall Control with camber changes

Martin Simmons has done an excellent job of describing many aspects of lifting systems and the numerous details

that need to be considered to achieve efficient and well designed solutions. The key concept to note however, is

that there are MANY variables that need to be considered when designing lifting surfaces. This short paper is

written to expand on the details written in Martin Simmons Model Aircraft Aerodynamics publication as it relates

to stall control by camber changes.

One has to remember that you cannot design a lifting system to meet an infinite variety of flight conditions. It

simply is not feasible with current technology. Many attempts have been made over many years to develop

variable geometry wing surfaces specifically to enhance a limited flight envelope but the solutions are complex,

expensive and invariably heavy. The key to remember in the details that follow is that we are attempting to design

a wing system that meets a specific flight envelope – one that has a known and controllable slow speed stall point

and a known, designed top speed with a never to exceed speed.

So, let’s look at a simple solution for tip stall control through camber and physical twist variation in a tapered

wing. Note: in the discussions that follow, one core assumption is made. I have assumed the same as Martin

Simmons in that an Elliptical lift distribution exists across the span of the wing. This is a key assumption.

I can personally see why one might assume that a wash-in might be required with a higher cambered tip airfoil

based on the aerodynamic zero lift angle of attack parameter. It may seem intuitive that this might be the case IF

your point of reference is the zero lift angles of attack ONLY. However, as noted above, there are other factors

that need to be considered to understand why this would be the wrong course of action. Adding a higher

cambered airfoil to the wing tip and then introducing wash-in would cause significant flight issues with a

considerably smaller flight envelope and significant tip stalling characteristics.

To understand the concept of increased camber at the wing tip with WASH-OUT introduced to counter

aerodynamic wash-in one must review the lift curves of a specific family of airfoils with varying cambers. This is

shown in Martin Simmons book as Fig 7.4. You will notice that the lift curves move to the left and upwards on the

graph as camber increases. What is also apparent is the increasingly negative aerodynamic zero-lift angles of

attack as the camber increases. However, what is NOT so apparent is the reduction in geometric (physical) angle

of the stall angle that occurs as the camber increases. This is shown in Martin Simmons diagram (7.4) where the

coefficient of lift max intersects with the angle of attack horizontal axis in the middle of the graph (notated by

“N.B. geometric stall angles).

Let’s summarize those three points:

1). As camber increases, the lift curves move left and upwards on the lift/angle of attack graph

2). As camber increases, the zero-lift angle of attack increases negatively

3). As camber increases, the physical angle of attack at which the airfoil stalls decreases

So let’s see what all this means:

Page 2: Stall Control

Tony Elliott – 05/2008 Page 2

Example 1: Reducing camber at the wing tip – no wash-in or wash-out added

Let’s look at a wing that is designed with a highly cambered airfoil at the root and a low cambered airfoil at the

tip. IF the wing is built with the chord lines flat on the building board, using the two left-most lift curves from the

diagram, you will see that the root will stall before the tip as the angle of attack of the complete wing is increased

(upper right hand side of the diagram where Cl max occurs). This is good when it comes to eliminating tip stall at

slow speeds.

Now, as we look at these same two lift curves, let’s assume we point the nose of the aircraft down and reduce the

angle of attack of the whole wing. As we do this, we move down the lift curves to the lower left quadrant of the

lift curve diagram noted as “negative or inverted stall” in the Martin Simmons diagram 7.4. Here you will see the

lift curve for the moderately cambered tip airfoil reach the negative lift point BEFORE the strongly cambered root

airfoil. What this means is that at high speed (or perhaps better defined, low angles of attack), the tip actually

starts to lift downwards while the root is lifting upwards. This is not a good thing for numerous reasons including

increased vortex drag at the tip, numerous structural considerations as well as a now well defined upper speed

limit.

The aircraft designed in this way may handle fairly well at slow speeds (high angles of attack) but will be severely

limited in high speed (low angles of attack).

Page 3: Stall Control

Tony Elliott – 05/2008 Page 3

Summary 1: Reducing camber at the tips allows us to control low speed tip stall but unfortunately causes the

wing tips to “lift” downwards at higher speeds – net result is a very narrow flight speed envelope.

One can counteract the low angle of attack (high speed) downward lifting tips by introducing wash-in (raising the

LE of the tip airfoil) so that it stalls after the root airfoil at high speeds but this would then cause the tips to stall

before the root at slow speeds!! By adding wash-in to resolve the high speed issue at the tip, you counteract the

advantage gained at slow speeds at the tip! There is no real good solution to be gained by reducing tip camber.

Summary 2: Adding wash-in to counteract downward tip “lift” at high speed causes low speed tip stalls to occur

Now let’s look at the opposite scenario – low camber at root, high camber at tip.

Example 2: Increasing Camber at the wing tip – no wash-in or wash-out added.

By having the increased cambered airfoil at the tip and the lower cambered airfoil at the root, you will see from

the upper right quadrant of the lift diagrams (fig 2 below) that at high angles of attack (slow speed) the tips will

stall before the root which is NOT good. If you carefully look at the lift curves, specifically at their stall points in

this upper right quadrant, the higher cambered airfoils at the tip “DEMONSTRATES “ wash-in – specifically

aerodynamic wash-in (not physical or geometric wash-in) by the fact that the tips will stall before the roots at low

speed.

Now, If you review the lower left quadrant of the graph (low angles of attack or high speed), the root airfoil

approaches the negative lift point BEFORE the tip which is good since the root is likely to stall before the tip.

Summary 1: increasing camber at tips causes tip stall at low speed but at high speeds, the tips still lift as they

should do.

With reference to figure 2, the reader may now see a method of correcting the low speed tip stall caused by the

higher cambered airfoil at the tip. If we now move the left most lift curve (the lift curve for the tip) to the right in

the diagram (see Fig 3 below), we can move the low speed stall point much closer to the root low speed stall

point. In fact, we need to move it just past the root airfoil stall point so that the root stalls before the tip at low

speeds. By moving the highly cambered airfoil lift curve to the right, we also reduce the difference between the

zero lift angles of attack in the lower left quadrant. Note that for a family of varying cambered airfoils, the

differential between the low speed stall points in that family is smaller than the differential between the zero-lift

angles of attack. Therefore, we can move the curve to the right by an amount that causes the stall to occur at the

tip at a higher angle of attack than at the root hence controlling low speed tip stall!

Summary 2: By adding wash-out equal to the zero-lift angle difference between root and tip airfoil, we control

tip stalling by moving the tip airfoil stall point PAST the root airfoil stall point PLUS we control high speed tip

airfoil lift over a much larger flight speed envelope.

The process of increasing camber at the tip and then moving the tip lift curve to the right by adding wash-out

really opens up the flight envelope of a flying surface. The process almost eliminates tip stalling while increasing

the high speed flight range because the complete wing has the same zero-lift angle of attack (tips do not lift

downwards at high speeds).

Page 4: Stall Control

Tony Elliott – 05/2008 Page 4

Page 5: Stall Control

Tony Elliott – 05/2008 Page 5

Still not clear? Let’s view it from a different angle (no pun intended). Let’s look at one lift curve – say the highly

cambered lift curve. This curve represents the coefficient of lift as it changes with respect to angle of attack. Our

goal for controlling tip stall is to move the low speed stall point of the tip airfoil to a larger angle of attack than the

low speed stall point angle of attack of the root airfoil. From figure 2 we see that the stall point of the tip occurs

BEFORE the root. In other words, the tip airfoil has already reached a POSITIVE, NOSE UP angle of attack to cause

it to stall. We need to pull the nose of the tip airfoil downwards by a distance that lets the root airfoil stall first.

Pulling the nose of an airfoil down means that you raise the TE of the airfoil – wash-out! Moving the lift curve to

the right as shown in Figure 2 means you have to add wash-out.


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