The flow between two horizontal infinite parallel plates is a two-dimension, steady-state, incompressible and fully- developed flow. The distance between the plates is h m. The bottom plate is stationary and the top plate velocity is U. m/s in the x-direction. The flow is driven by the top moving plate and there is, therefore, no pressure gradient in the direction of the flow. Velocity in the y-direction, v = 0. Note: Align the x-axis to the bottom wall. Use the x-momentum equation to show that the velocity profile equation is u(y) = ay + b and find the values of a and b. Use the energy equation to derive the temperature distribution Ty) for the flow if the surface temperature and temperature gradient on the bottom plate are both zero.

Elements Of Electromagnetics
7th Edition
ISBN:9780190698614
Author:Sadiku, Matthew N. O.
Publisher:Sadiku, Matthew N. O.
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The flow between two horizontal infinite parallel plates is a
two-dimension, steady-state, incompressible and fully-
developed flow. The distance between the plates is h m. The
bottom plate is stationary and the top plate velocity is U.
m/s in the x-direction. The flow is driven by the top moving
plate and there is, therefore, no pressure gradient in the
direction of the flow. Velocity in the y-direction, v = 0.
Note: Align the x-axis to the bottom wall.
Use the x-momentum equation to show that the velocity
profile equation is
(a)
u(y) = ay + b
and find the values of a and b.
Use the energy equation to derive the temperature
distribution T(y) for the flow if the surface temperature and
temperature gradient on the bottom plate are both zero.
(b)
Transcribed Image Text:The flow between two horizontal infinite parallel plates is a two-dimension, steady-state, incompressible and fully- developed flow. The distance between the plates is h m. The bottom plate is stationary and the top plate velocity is U. m/s in the x-direction. The flow is driven by the top moving plate and there is, therefore, no pressure gradient in the direction of the flow. Velocity in the y-direction, v = 0. Note: Align the x-axis to the bottom wall. Use the x-momentum equation to show that the velocity profile equation is (a) u(y) = ay + b and find the values of a and b. Use the energy equation to derive the temperature distribution T(y) for the flow if the surface temperature and temperature gradient on the bottom plate are both zero. (b)
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