Explanation Given information: Initially particle is located on x axis at x A and the flow is symmetric about x axis. Write the expression for the two-dimensional velocity field in the vector form. V = ( U 0 + b x ) i → − b y j → ...... (I) Here, the horizontal speed is U 0 , the constant is b , and the distance in x direction is x and the distance in y direction is y . Write the expression for the velocity component along x direction. u = U 0 + b x ...... (II) Here, the variable is x in x direction. Write the expression for the velocity component along x direction. v = − b y ...... (III) Here, the variable is y in y direction. Write the expression for the velocity in x direction in differential form. d x d t = u ...... (IV) Calculation: Substitute U 0 + b x for u in Equation (IV). d x d t = U 0 + b x d x U 0 + b x = d t ...... (V) Integrate the Equation (V). ∫ d x U 0 + b x = ∫ d t 1 b ln ( U 0 + b x ) = t − 1 b ln C 1 1 b ( ln ( U 0 + b x ) + ln C 1 ) = t 1 b ln ( U 0 + b x ) C 1

Fluid Mechanics Fundamentals And Applications

3rd Edition

ISBN: 9780073380322

Author: Yunus Cengel, John Cimbala

Publisher: MCGRAW-HILL HIGHER EDUCATION

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Fluid Kinematics

The branch of science that deals with objects which are either in motion or stationary are studied under the branch of classical mechanics. Fluid mechanics is a subcategory of classical mechanics that deals with the behavior of fluids at rest (fluid stat…

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Chapter 4, Problem 51P

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An expression for the location of the fluid at some arbitrary time in terms of its initial location.

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Chapter 4, Problem 50P

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Chapter 4 Solutions

Fluid Mechanics Fundamentals And Applications

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An expression for the location of the fluid at some arbitrary time in terms of its initial location.

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An expression for the location of the fluid at some arbitrary time in terms of its initial location.

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Chapter 4 Solutions