Explanation Given information: The velocity component along the r is V cos θ ( 1 − a 2 r 2 ) and the velocity component along the θ is − V sin θ ( 1 + a 2 r 2 ) . Write the expression for the velocity component along the r direction. u r = V cos θ ( 1 − a 2 r 2 ) .......(I) Here, the constant is a , variable in radial direction is r , and the horizontal velocity is V . Write the expression for the velocity component along the θ direction. u θ = − V sin θ ( 1 + a 2 r 2 ) .......(II) Write the expression for the stagnation point along the r direction. u r = 0 .......(III) Write the expression for the stagnation point along θ direction. u θ = 0 .......(IV) Calculation: Substitute V cos θ ( 1 − a 2 r 2 ) for u r in Equation (III). ( 1 − a 2 r 2 ) V cos θ = 0 1 − a 2 r 2 = 0 a 2 r 2 = 1 r = a

Fluid Mechanics: Fundamentals and Applications

4th Edition

ISBN: 9781259877827

Author: CENGEL

Publisher: MCG

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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 114P

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The location of the stagnation point in cylindrical and Cartesian coordinates.

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Chapter 4, Problem 113P

Chapter 4, Problem 116P

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Fluid Mechanics: Fundamentals and Applications

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The location of the stagnation point in cylindrical and Cartesian coordinates.

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