Explanation Given information: Discharge from the rectangular channel is 200 ft 3 / s bottom, slope is 5 ft / mile . The figure shown below shows the cross section of trapezoidal channel. Figure-(1) For best cross -section y = b 3 2 and θ = 60 ° Write the expression for the flow rate using manning Equation. ∨ ˙ = a n A c R h 2 / 3 S 0 1 / 2 ...... (I) Here, the cross -sectional flow area is A c the hydraulic radius is R h the bottom slope is S 0 and the dimensional coefficient is a . Write the expression for the cross sectional area of the of the flow A c = ( b + y tan θ ) y ...... (II) Here the width is b and the height is y . Substitute b 3 2 for y and 60 ° for θ in Equation (II). A c = ( b + b 3 2 tan 60 ° ) b 3 2 = ( b + b 3 2 3 ) b 3 2 = 3 3 4 b 2 ....... (III) Write the expression for the wetted perimeter. p = b + 2 y sin θ ...... (IV) Substitute b 3 2 for y and 60 ° for θ in (IV). p = b + 2 ( b 3 2 tan 60 ° ) = b + 2 ( b 3 2 3 / 2 ) = b + 2 b = 3 b ...... (V) Write the expression for the hydraulic radius. R h = A c p ...... (VI) Substitute b 2 2 for A c and 2 b for p in Equation (VI) To determine (b) The bottom width of the channel.

Fluid Mechanics: Fundamentals and Applications

4th Edition

ISBN: 9781259877827

Author: CENGEL

Publisher: MCG

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Chapter 13, Problem 133EP

To determine

(a)

The bottom width of the channel.

To determine

(b)

The bottom width of the channel.

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Chapter 13, Problem 132EP

Chapter 13, Problem 134EP

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Fluid Mechanics: Fundamentals and Applications

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(a) The bottom width of the channel.

Solution Summary: The author shows the cross section of the trapezoidal channel using manning Equation.