For a two-dimensional viscous dominated flow between two parallel plates, distance 0.9 m apart, where the bottom plate moves at a constant velocity 15.4 m/s and the top plate is fixed. The governing equations can be reduced to dp 0 = dp = 0. dæ ду The discharge per unit width is 18.7 m²/s and µ = 0.800 kg/ms. Find the absolute value of the pressure gradient, in kPa, to 2 d.p.. Answer:

For a two-dimensional viscous dominated flow between two parallel plates, distance 0.9 m apart, where the bottom plate moves at a constant velocity 15.4 m/s and the top plate is fixed. The governing equations can be reduced to

0=−dpdx+μ∂2u∂y2,∂p∂y=00=−dpdx+μ∂2u∂y2,∂p∂y=0.

The discharge per unit width is 18.7 m²/s and μμ = 0.800 kg/ms. Find the absolute value of the pressure gradient, in kPa, to 2 d.p

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For a two-dimensional viscous dominated flow between two parallel plates, distance 0.9 m apart, where the bottom plate moves at a constant velocity 15.4 m/s and the top plate is fixed. The governing equations can be reduced to dp 0. dx dy The discharge per unit width is 18.7 m2/s and µ = 0.800 kg/ms. Find the absolute value of the pressure gradient, in kPa, to 2 d.p.. Answer: