49. Water flows at a rate of 200 GPM into a piping system connected in series. Length, diameter, and loss coefficient of each pipe are given below. For p= 62.4 Ibm/ft° and µ = 0.7E-3 Ibm ft/s find total pressure drop and the diameter of an equivalent pipe representing this system.

FROM BOOK: ENGINEERING THERMOFLUIDS, M. MASSOUD

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49. Water flows at a rate of 200 GPM into a piping system connected in series. Length, diameter, and loss coefficient of each pipe are given below. For p= 62.4 Ibm/ft and u = 0.7E–3 lbm ft/s find total pressure drop and the diameter of an equivalent pipe representing this system. C) Fluid Power Theory an.. IndPitEn IlIb. Fluid Mechanics: Incompressible Viscous Flow 392 Pipe D K No. (ft) 100.00 (in) 5.00 (-) 50.00 1 2 80.00 4.50 45.00 3 70.00 4.00 65.00 4 120.00 3.50 55.00 5 90.00 3.00 15.00

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[Ans.: Flow In Serial Pipes Pipe No. L D A V K Re f ΔΡ (fi) (in) (ft') (ft/s) (-) x IE-6 (-) (psi) GPM 100 5.00 0.136 3.27 50.00 200 0.121 0.01770 3.90 0.01733 5.33 2 80 4.50 0.110 4.05 5.12 45.00 200 65.00 200 55.00 0.135 0.152 0.173 0.01648 18.49 0.202 0.01598 11.51 0.087 0.067 3 70 4.00 0.01693 12.03 4 120 3.50 6.65 200 5 90 15.00 200 3.00 0.049 9.09 Data For The Equivalent Pipe Representing The Compound Piping System L (ft) ΔΡ(psi) D (in) A (ft') V (f/s) K(-) V (GPM) 1 (ft"') 491.48 3.06 0.083 5.37 233.02 200.00 5159.06 51.3].