To determine The vertical drop per unit length of the pipe so that the pressure drop is zero for laminar flow. Explanation The figure below represents the schematic diagram of circular pipe. Figure-(1) Write the expression for Navier-Stokes along z direction. − ∂ p ∂ z + μ [ 1 r ∂ ∂ r ( r ∂ V z ∂ r ) ] = ρ g sin θ (I) Here, dynamic viscosity is μ , pressure is p , density of fluid is ρ , acceleration due to gravity is g . Write the expression for the velocity in z in direction. V z = r 2 4 μ ( ∂ p ∂ z ) + r 2 4 μ ρ g sin θ + c 1 ln r + c 2 (II) Consider the boundary condition, at r = R , V z = 0 and at r = 0 , V z = V , but at r = 0 , ln ( 0 ) = − ∞ which is not possible, therefore c 1 must be equal to 0 . Write the expression for volume flow rate through pipe. Q = ∫ 0 R V z ( 2 π r ) d r (III) Write the expression for pressure gradient along z direction. ∂ p ∂ z = − Δ p l (IV) Write the expression for radius of pipe. R = D 2 Write the expression for dynamic viscosity. μ = ρ v Calculation: Substitute 0 for c 1 , 0 for V z and R for r in Equation (II). 0 = R 2 4 μ ( ∂ p ∂ z ) + R 2 4 μ ρ g sin θ + ( 0 ) ln r + c 2 c 2 = − R 2 4 μ ( ∂ p ∂ z ) − R 2 4 μ ρ g sin θ Substitute 0 for c 1 and − R 2 4 μ ( ∂ p ∂ z ) − R 2 4 μ ρ g sin θ for c 2 in Equation (II)

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Chapter 6.9, Problem 94P

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The vertical drop per unit length of the pipe so that the pressure drop is zero for laminar flow.

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Chapter 6.9, Problem 93P

Chapter 6.9, Problem 95P

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