Explanation Given information: The shut off head is 60 mm of water column, the coefficient is 2.5 × 10 − 7 mm / lpm 2 , the diameter of the pipe is 150 mm , the length of the pipe is 24.5 mm , the roughness of the pipe is 0.15 mm , the minor loss coefficient for the valve is 6.6 , the minor loss coefficient of entrance is 3.3 , the minor loss coefficient of the damper is 1.8 and the minor loss coefficient of tee is 0.36 . Assume that the flow is steady and the air flowing in the duct is turbulent. Write the expression for the available head. H r e q u i r e d = P 2 − P 1 ρ g + α 2 V 2 2 − α 1 V 1 2 2 g + ( z 2 − z 1 ) + h L ....(I) Here, the velocity at inlet is V 1 , the pressure at the inlet is P 1 , the head at inlet is z 1 , the velocity at the outlet is V 2 , the pressure at the outlet is P 2 , the head at the outlet is z 2 and the head loss is h L . Write the expression for total head loss. h L = ( f L D + K e + K d + K t + K v + n K e l b o w ) V 2 2 2 g ....(II) Here, the friction factor for the duct is f , the length of pipe is L , the diameter of the pipe is D , the minor loss coefficient at entrance is K e , the minor loss coefficient of damper is K d , the minor loss coefficient of tee is K t , the minor loss coefficient for elbow is K e l b o w and the number of elbow is n . Write the expression for roughness factor. R = ε D ....(III) Here, the roughness of the pipe is ε . Write the expression for the area of the pipe. A = π D 2 4 ....(IV) Write the expression foe the performance data. H a v a i l a b l e = H o − a V ˙ 2 ....(V) Here, the available head is H a and the volume flow rate is V ˙ . Write the expression for the volume flow rate. V ˙ = A V 2 ....(VI) Write the expression for H o in mm of air column. H o = H o ( ρ w ρ a ) ....(VII) Here, the density of water is ρ w and the density of the air is ρ a Write the expression for a in mm of air column. a = a ( ρ w ρ a ) ....(VIII) Calculation: Substitute 60 mm for H o , 997 kg / m 3 for ρ w and 1.184 kg / m 3 for ρ a in Equation (VII). H o = 60 mm 997 kg / m 3 1.184 kg / m 3 = 50523.45 mm ( 1 m 1000 mm ) = 50.52 m Substitute 2.5 × 10 − 7 mm for a , 997 kg / m 3 for ρ w and 1.184 kg / m 3 for ρ a in Equation (VIII). a = 2.5 × 10 − 7 mm / lpm 2 ( 997 kg / m 3 1.184 kg / m 3 ) = 2105.15 × 10 − 7 mm / lpm 2 ( 1 m 1000 mm ) = 2.1 × 10 − 7 m / lpm 2 Substitute 150 mm for D in Equation (IV). A = π ( 150 mm ) 2 4 = 0.785 ( 150 mm ( 1 m 1000 mm ) ) 2 = 0.017 m 2 Substitute 0.15 mm for ε and 150 mm for D in Equation (III). R = 0.15 mm 150 mm = 0.001 Refer to the Table 8-2, "Equivalent roughness values for new commercial pipes" to obtain the value of friction factor as 0.02 at relative roughness 0.001. Substitute 24.5 m for L , 150 mm for D , 3 for n , 0.21 for K e l b o w , 6.6 for K v , 1.8 for K d , 3.3 for K e , 0.36 for K t , 0.02 for f and 9.81 m / s 2 for g in Equation (II). h L = ( 0.02 24.5 m 150 mm + 3.3 + 1.8 + 0.36 + 6.6 + 3 × 0.21 ) V 2 2 2 × 9 .81 m / s 2 = ( 0

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Author: CENGEL

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Chapter 14, Problem 52P

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The plot for the required v/s volumetric flow rate and available head v/s volumetric flow rate.

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Chapter 14, Problem 51P

Chapter 14, Problem 53P

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Chapter 14 Solutions

FLUID MECHANICS FUND. (LL)-W/ACCESS

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The plot for the required v/s volumetric flow rate and available head v/s volumetric flow rate.

Solution Summary: The author plots the required v/s volumetric flow rate, available head, and tee flow rates. The flow is steady and the air flowing in the duct is turbulent.

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The plot for the required v/s volumetric flow rate and available head v/s volumetric flow rate.

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Chapter 14 Solutions