Aeroelastic effects
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Aeroelastic Effects - Wind Engineering - Lecture Slides, Slides of Environmental Law and Policy
Some concept of Wind Engineering are Aeroelastic Effects, Along-Wind Dynamic Response, Antennas and Open-Frame Structures, Atmospheric Boundary Layers and Turbulence, Atmospheric Boundary, Basic Bluff-Body Aerodynamics. Main points of this lecture are: Aeroelastic Effects, Aeroelastic Effects, Tacoma Narrows Bridge, Transmission Lines, Aeroelastic Effects, Aerodynamic Damping, Velocity, Relative Velocity, Damping Term, Equation of Motion
Typology: Slides
2012/2013
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- Very flexible dynamically wind-sensitive structures
- Motion of the structure generates aerodynamic forces
- Positive aerodynamic damping : reduces vibrations - steel lattice towers
- if forces act in direction to increase the motion : aerodynamic instability
- Aerodynamic damping (along wind) :
Relative velocity of air with respect to body = U^ x
Consider a body moving with velocity x in a flow of speed U
- Aerodynamic damping (along wind) :
ρ bU C ρ bUx 2
C
U
2 x ρ bU ( 2
ρ b(U x) C 2
D C
D a
2 D a
2 D a
2 D a
Drag force (per unit length) =
for small x/U
aerodynamic damping term
total damping term : cx^ ^ CD ρabUx
along-wind aerodynamic damping is positive
transfer to left hand side of equation of motion : mx cxkxD(t)
- Galloping :
Aerodynamic force per unit length in z direction (body axes) :
Fz = D sin + L cos = ρ U b(C sinα C cos )
D L
2
a ^
(Lecture 8)
cos ) dα
dC sinα C sinα dα
dC ρ U b(C cosα 2
dα
dF (^) L L
D D
2 a
z
For = 0 : )
dα
dC ρ U b(C 2
dα
dF (^) L D
2 a
z
dα
dC ρ U b(C 2
ΔF
L D
2 z a
- Galloping :
Substituting, Δα^ z/U
U
z )( dα
dC ρ U b(C 2
F
L D
2 z a
)z dα
dC ρ Ub(C 2
1 L
a D
For ) 0 , Fz is positive - acts in same direction as
dα
dC (C
L D z
negative aerodynamic damping when transposed to left-hand side
- Galloping :
Cross sections prone to galloping :
Square section (zero angle of attack)
D-shaped cross section
iced-up transmission line or guy cable
- Flutter :
Consider a two dimensional body rotating with angular velocity θ
Vertical velocity at leading edge : θd/
Apparent change in angle of attack : θd/2U
Can generate a cross-wind force and a moment
Aerodynamic instabilities involving rotation are called ‘flutter’
- Flutter :
Types of instabilities :
Name Conditions Type of motion Type of section
Galloping H 1 >0 translational Square section
‘Stall’ flutter A 2 >0 rotational Rectangle, H- section
‘Classical’ flutter H 2 >0, A 1 >0 coupled Flat plate, airfoil
- Flutter :
1
2
-0.
-0.
A 2 *
0
1
2
6
4
2
0
8
1
2
H 2 *
A
unstable
stable
stable
Flutter derivatives for two bridge deck sections :
3 A 1 *
2
1
0 (^0 2 4 6 8 10 )
1
2
0
0
H 1 *
(^2 4 6 8 10 )
1 2
U/nd
U/nd
- Lock - in :
Motion-induced forces during vibration caused by vortex shedding
Frequency ‘locks-in’ to frequency of vibration
Strength of forces and correlation length increased
End of Lecture 14
John Holmes