Respuesta :
Answer:
u(y)/U = [(y/H) - ((H²/2μ)(dp/dx)(y/H))] × [(1 - y/H)]
Explanation:
The flow is steady, compressible and planar. Thus the incompressible the continuity equation is given as;
(δu/δx) + (δv/δy) = 0
The velocity(v) in the vertical direction would be zero at both boundaries as well as everywhere in the flow.
This means the continuity equation will dictate that:
∂u
/∂x = 0
It means that u is only just a function of y i.e. u = u(y).
Thus, The Navier-Stokes equation in the y-direction will now be reduced to:
∂p
/∂y = 0
This means the pressure can only then be a function of x.
The Navier-Stokes equation in the x-direction would be;
ρ[(∂u
/∂t) + u(∂u/∂x) + v(∂u/∂y) + w(∂u/∂z)] = -dp/dx + μ(∂²u/∂x²) + v(∂²u/∂y²) + w(∂²u/∂z²)
Recall that v = 0 and u = u(y).
Thus, the Navier-Stokes equation in the x-direction would now become;
∂²u/∂y² = (1/μ)(dp/dx)
We now Integrate twice with respect to y to give;
u(y) = (1/2μ)(dp/dx)y² + c1•y + c2)
At boundary condition of y = 0, C2 will be zero.
Thus;
u(y) = (1/2μ)(dp/dx)y² + c1•y)
At height of y = H, we have;
U = (1/2μ)(dp/dx)H² + c1•H) - - - (eq 1)
Making C1 the subject gives;
c1 = (U/H) - (H/2μ)(dp/dx)
Putting that for c1 in (eq 1) and rearranging to simplify gives us;
u(y)/U = [(y/H) - ((H²/2μ)(dp/dx)(y/H))] × [(1 - y/H)]
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