Explanation Express the velocity of the exiting jet. V = P ρ A (I) Here, thrust force is P , density is ρ and cross-sectional area is A . Express the cross-sectional area. A = π 4 D 2 (II) Here, diameter of jet is D . Express the flowrate of the exiting jet. Q = A V (III) Conclusion: Substitute 2 .75 in . for D in Equation (II). A = π 4 ( 2 .75 in . ) 2 = π 4 [ ( 2 .75 in . ) ft 12 in . ] 2 = π 4 ( 0.2292 ft ) 2 = 0.04125 ft 2 Substitute 300 lb for P , 1 .94 slugs / ft 3 for ρ and 0

8th Edition

ISBN: 9781119571490

Author: GERHART

Publisher: WILEY

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Applied Fluid Mechanics

A fluid is a substance that is continuously deformed by the application of shear stress. The rate of deformation of a fluid depends on its viscosity. The fluid tries to flow when it interacts with some other system.

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Chapter 5.2, Problem 76P

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Determine the flowrate and the velocity of the exiting jet.

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Chapter 5.2, Problem 75P

Chapter 5.2, Problem 77P

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Chapter 5 Solutions

FUNDAMENTALS OF FLUID MECHANICS

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