AIRFOIL
The concept of the wing and vertical
and the horizontal tail was discovered by George Cayley in 1799. Consider the wing of aircraft,
the cross-sectional shape obtained by the intersection of the wing with the
perpendicular plane is called Airfoil. The thickness distribution of the airfoil essentially controls the lift and the moment characteristics of the airfoil.
AIRFOIL
The concept of the wing and vertical
and the horizontal tail was discovered by George Cayley in 1799. Consider the wing of aircraft,
the cross-sectional shape obtained by the intersection of the wing with the
perpendicular plane is called Airfoil. The thickness distribution of the airfoil essentially controls the lift and the moment characteristics of the airfoil.
NOMENCLATURE OF AIRFOIL
MEAN CAMBER LINE: It is (which
divides the airfoil into two equal parts) if we plot the points that lie half the way between the upper and the lower surface we obtain a curve.
LEADING EDGE and TRAILING EDGE: The most forward and the rearward
point of a mean camber line is the Leading Edge and Trailing Edge respectively
CHORD LINE: The straight line connecting the
leading and trailing edge is called a Chord Line of an airfoil.
CAMBER: The maximum distance between the
mean camber line and chord line, measured perpendicular is called as Camber.
CHORD: The precise distance from the
leading to trailing edge measured along the chord line simply designated the
Chord (also written as c) of an airfoil.
When the airfoil is inclined with relative wind another term angle of attack is defined.
ANGLE OF ATTACK: The angle between the chord line and the relative wind is called Angle of Attack (α)
ANGLE OF ATTACK: The angle between the chord line and the relative wind is called Angle of Attack (α)
The angle of attack is written as (α)
Relative wind is written as V∞
V∞ is the free –stream velocity
of the air far up-stream of air. The direction of V∞ is defined as the RELATIVE
WIND (V∞)
TYPES OF AIRFOIL
1. CAMBERED AIRFOIL
The airfoil in which we have camber
When α=0, there is still a positive value of lift coefficient (Cl) this means there is still some lift even when the airfoil is at zero angles of attack of the flow. This is due to the positive camber of the airfoil. The value of α when the lift is zero is defined as the ZERO-LIFT ANGLE OF ATTACK (αL=0)
The positive camber of the airfoil means airfoil is not symmetric it has some camber.
When α=0, there is still a positive value of lift coefficient (Cl) this means there is still some lift even when the airfoil is at zero angles of attack of the flow. This is due to the positive camber of the airfoil. The value of α when the lift is zero is defined as the ZERO-LIFT ANGLE OF ATTACK (αL=0)
The positive camber of the airfoil means airfoil is not symmetric it has some camber.
figure 1
As we can see in the above in diagram the lift curve doesn’t pass through the origin which means that if α =o so lift is not equal to 0
2. SYMMETRICAL AIRFOIL
Symmetrical airfoil is an airfoil in which mean camber line and the chord line are the same i.e. there is no camber in symmetric airfoil
figure 1a
As we can see in the figure the curve of the symmetrical airfoil pass through the origin that means that when α =0 there is no lift produced by the airfoil
If we see both the diagram properly as we increase α beyond a certain value of Cl there is a rapid decrease in Cl at high α, the airfoil is called as STALLED
If we see both the diagram properly as we increase α beyond a certain value of Cl there is a rapid decrease in Cl at high α, the airfoil is called as STALLED
CAUSE OF STALLED
Stalled is caused due to flow separation on the upper surface of the airfoil as shown in the figure as the stall airfoil means nearly no lift, this phenomenon of airfoil stall is very critical importance in aeroplane design
How to read NACA serires
How to read NACA serires
case 1
4 digits NACA series
NACA MPXX
M= max camber (M/100)
P= chordwise position of max camber(P/10)
XX= max section thickness(XX/100)
example
NACA 2412
NACA 2412
M=2
P=4
XX=12
max camber is 2/100=0.02
chordwise position of max camber is 0.4
max section thickness is 12/100=0.12
case 2
5 digits NACA series
NACA CLPPXX
CL = Lift coefficient ( CL*1.5)
PP= chordwise position of max camber(PP/2)
XX= maximum thickness (XX/100)
example
NACA 12018
CL=1
PP= 20
XX=18
the lift coefficient is 1*1.5=1.5
chored wise position of max camber is 20/2=10
maximum thickness is 18/100=0.18
XX=18
the lift coefficient is 1*1.5=1.5
chored wise position of max camber is 20/2=10
maximum thickness is 18/100=0.18