10.4-Stress Distributions in Pip, fluid mech
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Stress Distributions in Pipe Flow
10.4 Stress Distributions in Pipe Flow
This section derives equations for the stress distributions on a plane that is oriented normal to stream lines.
These equations, which apply to both laminar and turbulent flow, provide insights about the nature of the flow.
Also, these equations are used for subsequent derivations.
In pipe flow the pressure acting on a plane that is normal to the direction of flow is hydrostatic. This means that
the pressure distribution varies linearly as shown in Fig. 10.6. The reason that the pressure distribution is
hydrostatic can be explained by using Euler's equation (see p. 87).
Figure 10.6
For fully developed flow in a pipe, the pressure distribution on an area normal to
streamlines is hydrostatic.
To derive an equation for the shearstress variation, consider flow of a Newtonian fluid in a round tube that is
inclined at an angle α with respect to the horizontal as shown in Fig. 10.7. Assume that the flow is fully
developed, steady, and laminar. Define a cylindrical control volume of length
L
and radius
r
.
Figure 10.7
Sketch for derivation of an equation for shear stress.
Apply the momentum equation in the
s
direction. The net momentum efflux is zero because the flow is fully
developed; that is, the velocity distribution at the inlet is the same as the velocity distribution at the exit. The
momentum accumulation is also zero because the flow is steady. The momentum equation (6.5) simplifies to
force equilibrium.
(10.13)
Analyze each term in Eq. (10.13) using the force diagram shown in Fig. 10.8:
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Stress Distributions in Pipe Flow
(10.14)
Figure 10.8
Force diagram corresponding to the control volume defined in Fig. 10.6.
Let
W
= γ
A
L
, and let sin α =
z
/
L
as shown in Fig. 10.4
b
. Next, divide Eq. (10.14) by
A
L
:
(10.15)
Equation (10.15) shows that the shearstress distribution varies linearly with
r
as shown in Fig. 10.9. Notice that
the shear stress is zero at the centerline, it reaches a maximum value of τ
0
at the wall, and the variation is linear
in between. This linear shear stress variation applies to both laminar and turbulent flow.
Figure 10.9
In fully developed flow (laminar or turbulent), the shear-stress distribution on an area
that is normal to streamlines is linear.
Copyright ¨ 2009 John Wiley & Sons, Inc. All rights reserved.
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