Explanation Given Information: The area of the square sections is 4 m × 4 m , the breadth of the channels is 8 m and the depth of the channels is 4 m . Draw the schematic diagram for the separate and combine channel. Figure-(1) Write the expression for the volume flow rate of the water at the maximum height. Q 2 = Q 1 [ ( A c 2 A c 1 ) ( R h 2 R h 1 ) 2 / 3 ] ...... (I) Here, the volume flow of water for separate section is Q 1 , the area for combine section is A c 2 , the area separate section is A c 1 , the hydraulic radius separate section is R h 1 and the hydraulic radius for combine section is R h 2 . Write the expression for the hydraulic radius of the channel. R h = A c P ...... (II) Here, the perimeter of the section is P and the area of the cross section is A c . Substitute A c 1 P 1 for R h 1 and A c 2 P 2 for R h 2 in Equation (I). Q 2 Q 1 = [ ( A c 2 A c 1 ) ( A c 2 P 2 A c 1 P 1 ) 2 / 3 ] = ( A c 2 A c 1 ) 5 / 3 ( P 1 P 2 ) 2 / 3 ...... (III) Here, the perimeter of the separate section is P 1 and the perimeter of the combine section is P 2 . Write the expression for the total cross sectional area of the two channels. A c 1 = 2 ( s 2 ) ...... (IV) Here, the side of the channel is s . Write the expression for the cross sectional flow area of the combine channel. A c 2 = ( l × b ) ...... (V) Here, the length of the channel is l and the breadth of the channel is b . Write the expression for the total wetted perimeter for the two separate channels. P 1 = 4 ( s ) ...... (VI) Write the expression for the wetted perimeter for the combined channel

Fluid Mechanics Fundamentals And Applications

3rd Edition

ISBN: 9780073380322

Author: Yunus Cengel, John Cimbala

Publisher: MCGRAW-HILL HIGHER EDUCATION

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Chapter 13, Problem 55P

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The percentage increase in flow rate as a result of combing the channels.

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Chapter 13, Problem 54P

Chapter 13, Problem 56P

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Chapter 13 Solutions

Fluid Mechanics Fundamentals And Applications

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Chapter 13 Solutions