Explanation Given information: The flow rate is 15 gal / min , length of pipe is 70 ft , three 90 ° bend loss and the roughness of plate is 0.0085 . Write the expression for the head loss. h L = ( f L D + ∑ K L ) V 2 2 2 g ...... (I) Here, the minor losses are ∑ K L , the velocity of flow is V 2 , the friction factor is f , the length of pipe is L and the diameter is D . Write the expression for the cross sectional area of the channel. A = π D 2 4 ...... (II) Here, the diameter of pipe is D . Write the expression for the minor losses. ∑ K L = K entrance + 3 K bend + K gate + K angle ...... (III) Here, the head loss at entrance is K entrance , the head loss at valve is K valve , the head loss at elbow is K Elbow and the head loss at exit is K exit . Write the expression for energy balance. P 1 ρ g + α 1 V 1 2 2 g + Z 1 = P 2 ρ g + α 2 V 2 2 2 g + Z 2 + h t u r b i n e + h L ...... (IV) Here, the pressure at section 1 is P 1 , the pressure at section 2 is P 2 , the velocity at section 1 is V 1 , the velocity at section 2 is V 2 , the elevation at section 1 is Z 1 , the elevation at section 2 is Z 2 , the kinetic energy correction factor is α , the turbine loss is h t u r b i n e and the friction loss is h L . Write the expression for the friction factor. 1 f = − 2 log ( ε / D 3.7 + 2.51 Re f ) ...... (V) Here, the friction factor is f , the Reynolds number is Re , the roughness factor is ε , and the diameter of pipe is D . Write the expression for the Reynolds number. Re = ρ V D μ ...... (VI) Here, the density is ρ , the velocity of flow is V , diameter is D and the viscosity of fluid is μ . Write the expression for velocity. V 2 = V ˙ A ...... (VII) Calculation: Substitute 15 gal / min for V ˙ in Equation (VII). V 2 = 15 gal / min ( π 4 D 2 ) = 15 gal / min ( D 2 ) ft 2 ( 0.0334 ft 3 / sec 1 gal / min ) = 0.0425 D 2 ft / sec Refer to table (8-4) "Loss coefficient of various pipe" to obtain the value of K entrance as 0.5 , K bend as 1.1 , K gate as ( 0.2 ) and K angle as 5 . Substitute 0.5 for K entrance , 1.1 for K bend , ( 0.2 ) for K gate and 5 for K angle in Equation (III). ∑ K L = 0.5 + ( 3 × 1.1 ) + 0.2 + 5 = 8.3 + 0.7 = 9 Substitute 70 ft for L , 9 for ∑ K L and 0.0425 D 2 ft / sec for V 2 in Equation (I). h L = ( f 70 ft D + 9 ) 2.825 × 10 − 5 D 4 Refer to table (A-3E) "Properties of saturated water" to obtain the value of density as 62.30 lbm / ft 3 , and dynamic viscosity as 6.556 × 10 − 4 lbm / ft ⋅ s . Substitute 60 psig for P 1 , 0 for P 2 , 6

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Applied Fluid Mechanics

A fluid is a substance that is continuously deformed by the application of shear stress. The rate of deformation of a fluid depends on its viscosity. The fluid tries to flow when it interacts with some other system.

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Chapter 8, Problem 145EP

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The minimum diameter of the piping system.

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Chapter 8, Problem 142P

Chapter 8, Problem 146EP

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The minimum diameter of the piping system.

Solution Summary: The author explains the minimum diameter of the piping system and the expression for the head loss.

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