Explanation Given information: The two pumps or turbine are geometrically similar. Write the expression for the dimensionless pump 1 parameter. C H , 1 = g H 1 ω 1 2 D 1 2 ....... (I) Here, the dimension less parameter for pump 1 is C H , 1 , the acceleration due to gravity is g , the net head of the pump 1 is H 1 , the diameter of the pump 1 is D 1 and the angular acceleration of the pump 1 is ω 1 . Write the expression for the dimensionless pump 2 parameter. C H , 2 = g H 2 ω 2 2 D 2 2 ....... (II) Here, the dimensionless parameter for the pump 2 is C H , 2 , the net head of the pump 2 is H 2 , the diameter of the pump 2 is D 2 and the angular acceleration of the pump 2 is ω 2 . Equate Equation (I) and Equation (II). g H 1 ω 1 2 D 1 2 = g H 2 ω 2 2 D 2 2 H 1 ω 1 2 D 1 2 = H 2 ω 2 2 D 2 2 ω 1 2 ω 2 2 = H 1 D 2 2 H 2 D 1 2 ω 1 ω 2 = ( H 1 H 2 ) 1 / 2 ( D 2 D 1 ) Write the expression for the affinity law dimensionless parameter for pump 1. C P , 1 = b h p 1 ρ 1 ω 1 3 D 1 5 ....... (III) Here, the affinity dimensional parameter for pump 1 is C P , 1 , the density for the pump 1 is ρ 1 and the brake horsepower for the pump 1 is b h p 1 . Write the expression for the affinity law dimensionless parameter for pump 2. C P , 2 = b h p 2 ρ 2 ω 2 3 D 2 5 ....... (IV) Here, the affinity dimensional parameter for pump 2 is C P , 2 , the density for the pump 2 is ρ 2 and the brake horsepower for the pump 2 is b h p 2 . Equate Equation (III) and Equation (IV). b h p 2 ρ 2 ω 2 3 D 2 5 = b h p 1 ρ 1 ω 1 3 D 1 5 D 2 5 D 1 5 = b h p 2 ρ 1 ω 1 3 b h p 1 ρ 2 ω 2 3 D 2 5 D 1 5 = ( b h p 2 b h p 1 ) ( ρ 1 ρ 2 ) ( ω 1 ω 2 ) 3 ....... (V) Substitute ( H 1 H 2 ) 1 / 2 ( D 2 D 1 ) for ω 1 ω 2 in Equation (V). D 2 5 D 1 5 = ( b h p 2 b h p 1 ) ( ρ 1 ρ 2 ) ( ( H 1 H 2 ) 1 / 2 ( D 2 D 1 ) ) 3 D 2 5 D 1 5 = ( b h p 2 b h p 1 ) ( ρ 1 ρ 2 ) ( H 1 H 2 ) 3 / 2 ( D 2 D 1 ) 3 ( D 2 D 1 ) 2 = ( b h p 2 b h p 1 ) ( ρ 1 ρ 2 ) ( H 1 H 2 ) 3 / 2 D 2 = D 1 ( b h p 2 b h p 1 ) 1 / 2 ( ρ 1 ρ 2 ) 1 / 2 ( H 1 H 2 ) 3 / 4 Write the expression for the dimensionless turbine 1 parameter. C H , A = g H A ω A 2 D A 2 ....... (VI) Here, the dimension less parameter for turbine 1 is C H , A , the acceleration due to gravity is g , the net head of the turbine 1 is H A , the diameter of the turbine 1 is D A and the angular acceleration of the turbine 1 is ω A . Write the expression for the dimensionless turbine 2 parameter. C H , B = g H B ω B 2 D B 2 ....... (VII) Here, the dimensionless parameter for the turbine 2 is C H , B , the net head of the turbine 2 is H B , the diameter of the turbine 2 is D B and the angular acceleration of the turbine 2 is ω B . Equate Equation (VI) and Equation (VII). g H A ω A 2 D A 2 = g H B ω B 2 D B 2 H A ω A 2 D A 2 = H B ω B 2 D B 2 ω A 2 ω B 2 = H A D B 2 H B D A 2 ω A ω B = ( H A H B ) 1 / 2 ( D B D A ) Write the expression for the affinity law dimensionless parameter for turbine 1

4th Edition

ISBN: 2810022150991

Author: CENGEL

Publisher: MCG

See similar textbooks

Concept explainers

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.

Videos

Question

Chapter 14, Problem 120P

To determine

The expression for the diameter of the turbine 2.

Whether the expression for the diameter of the turbine 2 is similar with expression for the diameter of the pump 2 or not.

Expert Solution & Answer

Want to see the full answer?

Check out a sample textbook solution

See solution

Chapter 14, Problem 119P

Chapter 14, Problem 121P

Students have asked these similar questions

In MATLAB, can you help me simulate an orbit under earth J2 perturbation with the Milankovich orbital elements? Also, can you check to see if they fit the Milankovich constraint equaiton?

8. All of the members in the Warren truss of Figure 8 are of length 10 ft. Use the method of sections to determine the forces in the members BD,CD,CE. B A C D E F G 2000 lb 3000 lb 5000 lb Figure 8 H

An acrobat is walking on a tightrope of length L =20.1 m attached to supports A and B at a distance of 20.0 m apart. The combined weight of the acrobat and his balancing pole is 900 N, and the friction between his shoes and the rope is large enough to prevent him from slipping. Neglecting the weight of the rope and any elastic deformation, determine the deflection (y) and the tension in portion AC and BC of the rope for values of x from 0.5 m to 10 m using 0.5 m increments. 1. Determine the maximum deflection (y) in the rope. 2. Plot tension of AC and BC vs. x (on the same plot with x on the x-axis). Turn in the plot and the table of x, TAC, and TBC (clearly label each). A C 20.0 m B

Chapter 14 Solutions

FLUID MECHANICS FUNDAMENTALS+APPS

Ch. 14 - What is the more common term for an...Ch. 14 - What the primary differences between fans,...Ch. 14 - List at least two common examples of fans, of...Ch. 14 - Discuss the primary difference between a porn...Ch. 14 - Explain why there is an “extra” term in the...Ch. 14 - For a turbine, discuss the difference between...Ch. 14 - Prob. 7CP Ch. 14 - Prob. 8P Ch. 14 - Prob. 9P Ch. 14 - Prob. 10CP

Ch. 14 - There are three main categories of dynamic pumps....Ch. 14 - For each statement about cow cetrifugal the...Ch. 14 - Prob. 13CP Ch. 14 - Consider flow through a water pump. For each...Ch. 14 - Write the equation that defines actual (available)...Ch. 14 - Consider a typical centrifugal liquid pump. For...Ch. 14 - Prob. 17CP Ch. 14 - Consider steady, incompressible flow through two...Ch. 14 - Prob. 19CP Ch. 14 - Prob. 20P Ch. 14 - Suppose the pump of Fig. P1 4-19C is situated...Ch. 14 - Prob. 22P Ch. 14 - Prob. 23EP Ch. 14 - Consider the flow system sketched in Fig. PI 4-24....Ch. 14 - Prob. 25P Ch. 14 - Repeat Prob. 14-25, but with a rough pipe-pipe...Ch. 14 - Consider the piping system of Fig. P14—24. with...Ch. 14 - The performance data for a centrifugal water pump...Ch. 14 - For the centrifugal water pump of Prob. 14-29,...Ch. 14 - Suppose the pump of Probs. 14-29 and 14-30 is used...Ch. 14 - Suppose you are looking into purchasing a water...Ch. 14 - The performance data of a water pump follow the...Ch. 14 - For the application at hand, the flow rate of...Ch. 14 - A water pump is used to pump water from one large...Ch. 14 - For the pump and piping system of Prob. 14-35E,...Ch. 14 - A water pump is used to pump water from one large...Ch. 14 - Suppose that the free surface of the inlet...Ch. 14 - Calculate the volume flow rate between the...Ch. 14 - Comparing the results of Probs. 14-39 and 14-43,...Ch. 14 - Prob. 45P Ch. 14 - The performance data for a centrifugal water pump...Ch. 14 - Transform each column of the pump performance data...Ch. 14 - 14-51 A local ventilation system (a hood and duct...Ch. 14 - Prob. 52P Ch. 14 - Repeat Prob. 14-51, ignoring all minor losses. How...Ch. 14 - Suppose the one- way of Fig. P14-51 malfunctions...Ch. 14 - A local ventilation system (a hood and duct...Ch. 14 - For the duct system and fan of Prob. 14-55E,...Ch. 14 - Repeat Prob. 14-55E, ignoring all minor losses....Ch. 14 - A self-priming centrifugal pump is used to pump...Ch. 14 - Repeat Prob. 14-60. but at a water temperature of...Ch. 14 - Repeat Prob. 14-60, but with the pipe diameter...Ch. 14 - Prob. 63EP Ch. 14 - Prob. 64EP Ch. 14 - Prob. 66P Ch. 14 - Prob. 67P Ch. 14 - Prob. 68P Ch. 14 - Prob. 69P Ch. 14 - Two water pumps are arranged in Series. The...Ch. 14 - The same two water pumps of Prob. 14-70 are...Ch. 14 - Prob. 72CP Ch. 14 - Name and briefly describe the differences between...Ch. 14 - Discuss the meaning of reverse swirl in reaction...Ch. 14 - Prob. 75CP Ch. 14 - Prob. 76CP Ch. 14 - Prob. 77P Ch. 14 - Prob. 78P Ch. 14 - Prob. 79P Ch. 14 - Prob. 80P Ch. 14 - Wind ( =1.204kg/m3 ) blows through a HAWT wind...Ch. 14 - Prob. 82P Ch. 14 - Prob. 84CP Ch. 14 - A Francis radial-flow hydroturbine has the...Ch. 14 - Prob. 87P Ch. 14 - Prob. 88P Ch. 14 - Prob. 89P Ch. 14 - Prob. 90CP Ch. 14 - Prob. 91CP Ch. 14 - Discuss which dimensionless pump performance...Ch. 14 - Prob. 93CP Ch. 14 - Prob. 94P Ch. 14 - Prob. 95P Ch. 14 - Prob. 96P Ch. 14 - Prob. 97P Ch. 14 - Prob. 98P Ch. 14 - Prob. 99P Ch. 14 - Prob. 100EP Ch. 14 - Prob. 101P Ch. 14 - Calculate the pump specific speed of the pump of...Ch. 14 - Prob. 103P Ch. 14 - Prob. 104P Ch. 14 - Prob. 105P Ch. 14 - Prob. 106P Ch. 14 - Prob. 107EP Ch. 14 - Prob. 108P Ch. 14 - Prob. 109P Ch. 14 - Prob. 110P Ch. 14 - Prove that the model turbine (Prob. 14-109) and...Ch. 14 - Prob. 112P Ch. 14 - Prob. 113P Ch. 14 - Prob. 114P Ch. 14 - Prob. 115CP Ch. 14 - Prob. 116CP Ch. 14 - Prob. 117CP Ch. 14 - Prob. 118P Ch. 14 - For two dynamically similar pumps, manipulate the...Ch. 14 - Prob. 120P Ch. 14 - Prob. 121P Ch. 14 - Prob. 122P Ch. 14 - Calculate and compare the turbine specific speed...Ch. 14 - Prob. 124P Ch. 14 - Prob. 125P Ch. 14 - Prob. 126P Ch. 14 - Prob. 127P Ch. 14 - Prob. 128P Ch. 14 - Prob. 129P Ch. 14 - Prob. 130P Ch. 14 - Prob. 131P Ch. 14 - Prob. 132P Ch. 14 - Prob. 133P Ch. 14 - Prob. 134P Ch. 14 - Prob. 135P Ch. 14 - A two-lobe rotary positive-displacement pump moves...Ch. 14 - Prob. 137P Ch. 14 - Prob. 138P Ch. 14 - Prob. 139P Ch. 14 - Prob. 140P Ch. 14 - Which choice is correct for the comparison of the...Ch. 14 - Prob. 142P Ch. 14 - In a hydroelectric power plant, water flows...Ch. 14 - Prob. 144P Ch. 14 - Prob. 145P Ch. 14 - Prob. 146P Ch. 14 - Prob. 147P Ch. 14 - Prob. 148P Ch. 14 - Prob. 149P Ch. 14 - Prob. 150P Ch. 14 - Prob. 151P

Knowledge Booster

Learn more about

Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, mechanical-engineering and related others by exploring similar questions and additional content below.

The expression for the diameter of the turbine 2. Whether the expression for the diameter of the turbine 2 is similar with expression for the diameter of the pump 2 or not.

Solution Summary: The author explains the expression for the diameter of the turbine 2 and the dimensionless pump 1 parameter.