Explanation Given information: The volume flow rate V ˙ through the pipe is a function of the dynamic viscosity μ , the pressure gradient d P / d x , and diameter D . The diameter of the pipe is doubled. Expression for the dimension for the diameter, D = [ L ] Here, the dimension for the length is [ L ] . Expression for the dimension for the volume flow rate, V ˙ = V t ...... (I) Here, the volume flow rate is V ˙ , the volume is V and the time is t . Substitute [ L 3 ] for V and [ T ] for t in Equation (I). V ˙ = [ L 3 ] [ T ] = [ L 3 T − 1 ] Here, the dimension for the volume is [ L 3 ] and the dimension for the time is [ T ] . Expression for the pressure gradient, d P d x = P l ...... (II) Here, the force is P , the pressure gradient is d P d x and the length is l . Substitute [ M L T − 2 ] for P and [ L ] for l in Equation (II). d P d x = [ M L T − 2 ] [ L ] = [ M L − 2 T − 2 ] Here, the dimension for the pressure is Expression for the dynamic viscosity, μ = P × t l 2 ...... (III) Here, the dynamic viscosity is μ and the length is l . Substitute [ T ] for t , [ M L T − 2 ] for P and [ L 2 ] for l 2 in Equation (III). μ = [ M L T − 2 ] × [ T ] [ L 2 ] = [ M L T 1 − 2 − 2 + 1 ] = [ M L T − 1 − 1 ] The volume flow rate is the function of the dynamic viscosity, the pressure gradient and diameter. Expression for the volume flow rate, V ˙ = f ( D , μ , d P d x ) Expression for the number of pi-terms, n = k − r ....... (IV) Here, the number of variable is k , the number of dimensions is r and the number of pi terms is n . Expression for first pi terms, Π 1 = V ˙ ( d P d x ) a D b μ c ....... (V) Here, the constant are a , c and b . Dimension for pi term, Π = [ L 0 T 0 ] Expression for the constant, C = Π 1 ....... (VI) Here, the constant is C . Expression for the ratio of the volume flow rate, V ˙ 2 V ˙ 1 = ( D 2 2 ) μ C ( d P d x ) × ( d P d x ) ( D 1 ) 2 μ C V ˙ 2 V ˙ 1 = D 2 2 D 1 2 ........ (VII) Conclusion: The number of variables is 4 and the number of dimensions is 3 . Substitute 4 for k and 3 for r in Equation (IV). n = 4 − 3 = 1 Substitute [ L 0 T 0 ] for Π , [ M L T − 1 − 1 ] for μ , [ M L − 2 T − 2 ] for d P d x , [ L 3 T − 1 ] for V ˙ and [ L ] for D in Equation (V)

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Chapter 7, Problem 63P

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The diameter of pipe is doubled, the factor by which setting volume flow rate go up.

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Chapter 7, Problem 62P

Chapter 7, Problem 64P

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Chapter 7 Solutions