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Drag and Momentum Balance for Flow Around a Cylinder
Aerodynamic drag is exerted on an object when fluid flows around it. This force
is due to a combination of the shear and pressure forces acting on the surface of
the object. The determination of these forces is difficult since it involves the
measurement of both velocity and pressure fields near the surface of the object.
However, making some assumptions, this force can be estimated by using the
conservation of mass and momentum around the object.
PROBLEM (this is also an experiment in EML 4304L):
Drag force on a circular cylinder (unit width 1m) will be given here as an example. As
shown below, velocity profiles before and after the cylinder are measured. Determine the
drag force acting on the cylinder by assuming uniform pressure at the measuring stations.
Vin=50 m/s
(2)
y
|y|>1
1 m u(y)=50 (m/s),
=20+30|y| (m/s), |y|1
(5)
x
(1)
(4)
(3)
Control Volume and Control Surfaces
Consider a control volume surrounding the cylinder as shown in the previous
slide. Assume the flow around the cylinder is symmetric, therefore, only half of
the control volume is needed as shown below. There are a total of five control
surfaces in this problem.
• Surface 4 is the symmetry plane, therefore, does not contribute any forces or
momentum fluxes, (no flow, therefore not momentum crosses 4).
• Surface 5 is the surface surrounding the cylinder, and the integration of the
pressure and shear stresses on 5 will give the total force the cylinder is acting on
the fluid: Rx. This force should balance with the forces acting on surfaces (1),
(2) & (3) plus the momentum flow in & out of those surfaces.
•(Note: the net force in the y direction will be zero, why?)
(1)
(3)
(2)
y
(5)
x
(4)
• The surface forces on surfaces (1) &
(3) will be free-stream pressure and
1 m they should cancel.
• Momentum flow in & out of (1) & (3)
can be determined by integration.
• Question: Is there momentum flow out
of surface (2)?
Mass Conservation
Obviously, since there is more mass flows into (1) than that flows out of (3).
Their difference is the mass flow out of surface (2). If there is mass flow then
the momentum flow is nozero. Use mass conservation:
mass flow in (1) = mass flow out (2) + mass flow out (3)
  V dA  0,    V dA    V dA    V dA  0,
CS
(1)
(2)
(3)
or m1  m 2  m3  0
 V1 A1  m2 
yH

0
1
H
0
1
 udA  0, m2   [V1 A1   (20  30 y )(1)dy   V1dA]
m2   [V1 (1)( H )  (20 y  15 y 2 ) |10 V1 (1)( H  1)]
 (1.2)[(50)(1)  (35)]  18( kg / s )
Mass flow leaving the upper surface (2) is 18 (kg/s) and equal amount
of mass is expected to leave the lower half of the control surface.
Momentum Conservation
The force acting on the cylinder can be evaluated
using the linear momentum balance:

Vd    V (V  dA)   ( )   ( )   ( )   ( )   ( )
FS  FB 

t CV
(5)
(4)
(3)
(2)
(1)
CS
Only need to evaluate the force in the x direction:
 ( P   ) dA   P dA   P dA   (
(5)
x
x
x
(3)
(1)
(1)
)
(
)
(2)
Rx  Patm A1  Patm A3    V12 dA   V (V  dA) 
(1)
(
)
(3)

V 2 dA
(3)
(2)
1
H
0
1
Rx   V12 A1  m2V1    (20  30 y ) 2 dA   V12 dA
  V12 (1)( H )  m2V1   [400 y  600 y 2  300 y 3 ] |10  V12 (1)( H  1)
 (18)(50)  (1.2)[400  600  300]  (1.2)(50) 2 (1)  540( N )
Lift and Drag Forces
The force acting on the cylinder by the fluid is equal in magnitude and opposite
in direction: Kx=-Rx=540(N). Drag force is in the positive x direction.
MOVIE (NCSC University of Illinois)
PIV MOVIE
Periodic shedding of vortices into the wake generates alternative up- and downwash as shown. Consequently, oscillatory loading will be exerted on the cylinder.
L
t
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