Explanation Given information: The width of the channel is 10 m , flow rate is 70 m 3 / s The flow depth is 0.80 m and the velocity after the jump is 2.4 m . The figure-(1) shows the schematic diagram of the hydraulic pump. Figure-(1) Write the expression for the average velocity at location 1. V 1 = V ˙ b × y 1 ...... (I) Here, flow depth at location 1 is y 1 , width of the channel is b and volume flow rate is V ˙ . Write the expression for the average velocity at location 2. V 2 = V ˙ b × y 2 ...... (II) Here, flow depth at location 2 is y 2 . Write the expression to calculate the head loss. h L = y 1 − y 2 + V 1 2 − V 2 2 2 g ...... (III) Here, velocity at location 1 is V 1 , velocity at location 2 is V 2 and acceleration due to gravity is g . Write the expression to calculate the mechanical power dissipated. E ˙ d i s s i p a t e d = ( ρ × V ˙ ) g h L ...... (IV) Here, density of water is ρ . Substitute 0.8 m for y 1 70 m 3 / s for V ˙ and 10 m for b in Equation (I). V 1 = 70 m 3 / s 10 m × 0.8 m = 70 m 3 / s 8 m = 8.75 m / s Substitute 2.4 m for y 2 70 m 3 / s for V ˙ and 10 m for b in Equation (II). V 1 = 70 m 3 / s 10 m × 2.4 m = 70 m 3 / s 24 m = 2.92 m / s Substitute 9.81 m / s 2 for g , 8

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Chapter 13, Problem 79P

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Chapter 13, Problem 78P

Chapter 13, Problem 80P

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Consider the flow of water in a 10-m-wide channel at a rate of 70 m3/s and a flow depth of 0.80 m. The water now undergoes a hydraulic jump, and the flow depth after the jump is measured to be 2.4 m. Determine the mechanical power wasted during this jump

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Chapter 13 Solutions

EBK FLUID MECHANICS: FUNDAMENTALS AND A

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