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Textbook Solutions for Fluid Mechanics

Chapter 7 Problem 97P

Question

Problem 97P

Oftentimes it is desirable to work with an established dimensionless parameter, but the characteristic scales available do not match those used to define the parameter. In such cases, we create the needed characteristic scales based on dimensional reasoning (usually by inspection). Suppose for example that we have a characteristic velocity scale V, characteristic area A, fluid density ρ, and fluid viscosity ρ., and we wish to define a Reynolds number. We create a length scale . and define

In similar fashion, define the desired established dimensionless parameter for each case: (a) Define a Froude number, given  = volume flow rate per unit depth, length scale L, and gravitational constant g. (b) Define a Reynolds number, given  = volume flow rate per unit depth and kinematic viscosity v. (c) Define a Richardson number (see Table 7-5), given  = volume flow rate per unit depth, length scale L, characteristic density difference ∆ρ, characteristic density ρ, and gravitational constant g.

Solution

Step 1 of 6)

The first step in solving 7 problem number trying to solve the problem we have to refer to the textbook question: Problem 97POftentimes it is desirable to work with an established dimensionless parameter, but the characteristic scales available do not match those used to define the parameter. In such cases, we create the needed characteristic scales based on dimensional reasoning (usually by inspection). Suppose for example that we have a characteristic velocity scale V, characteristic area A, fluid density ρ, and fluid viscosity ρ., and we wish to define a Reynolds number. We create a length scale . and defineIn similar fashion, define the desired established dimensionless parameter for each case: (a) Define a Froude number, given  = volume flow rate per unit depth, length scale L, and gravitational constant g. (b) Define a Reynolds number, given  = volume flow rate per unit depth and kinematic viscosity v. (c) Define a Richardson number (see Table 7-5), given  = volume flow rate per unit depth, length scale L, characteristic density difference ∆ρ, characteristic density ρ, and gravitational constant g.
From the textbook chapter Correlation and Simple Linear Regression you will find a few key concepts needed to solve this.

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Title Fluid Mechanics 2 
Author Yunus A. Cengel, John M. Cimbala
ISBN 9780071284219

Oftentimes it is desirable to work with an established

Chapter 7 textbook questions

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