Explanation Given information: The below figure represents a trapezoidal channel. Figure-(1) The bottom breadth of the section is 5 m , the trapezoidal angle is 45 ° and the bottom angle is 1 ° Write the expression for the cross -sectional area. A c = y ( b + y tan θ ) ...... (I) Here, the bottom breadth of the section is b , the trapezoidal angle is θ and the flow depth is y . Write the expression for the perimeter of the section. P = b + 2 y sin θ ...... (II) Write the expression for the hydraulic radius of the channel. R h = A c P ...... (III) Write the expression for the bottom slope. S o = tan α ...... (IV) Here, the bottom angle is α . Write the expression for the volume flow rate of the water. Q = a n A c R h 2 / 3 S o 1 / 2 ...... (V) Here, the manning coefficient is n and the constant is a . Calculation: Substitute 1 ° for α in Equation (IV). S o = tan ( 1 ° ) = 0.0175 Substitute 5 m for b and 45 ° for θ in Equation (I). A c = y ( 5 m + y tan 45 ° ) = y ( 5 m + y ) = 5 y + y 2 Substitute 5 m for b and 45 ° for θ in Equation (II). P = 5 m + 2 ( y ) sin 45 ° = 5 + 2 1 2 y = 5 + 2 2 y Substitute 5 + 2 2 y for P and 5 y + y 2 for A c in Equation (III)

Fluid Mechanics: Fundamentals and Applications

4th Edition

ISBN: 9781259696534

Author: Yunus A. Cengel Dr., John M. Cimbala

Publisher: McGraw-Hill Education

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Chapter 13, Problem 60P

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The normal depth of flow.

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Chapter 13, Problem 59EP

Chapter 13, Problem 61P

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Chapter 13 Solutions

Fluid Mechanics: Fundamentals and Applications

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The normal depth of flow.

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Chapter 13 Solutions