Explanation Given information: The velocity field is V → = ( u , v ) = ( 2.5 − 1.6 x ) i → + ( 0.7 + 1.6 y ) j → Write the expression for acceleration in x direction. a x = u d u d x + v d u d y + w d u d z + d u d t ....... (I) Write the expression for acceleration in x direction. a y = u d v d x + v d v d y + w d v d z + d v d t ....... (II) Here, velocity component along x direction is u , velocity component along y direction is v , and velocity component along z direction is w . Calculation: Substitute ( 0.65 − 1.7 x ) for u and ( 1.3 + 1.7 y ) for v in Equation (I). a x = ( 2.5 − 1.6 x ) d ( 2.5 − 1.6 x ) d x + ( 0.7 + 1.6 y ) d ( 2.5 − 1.6 x ) d y = ( 2.5 − 1.6 x ) × ( − 1.6 ) = − 4 + 2

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ISBN: 8220103676205

Author: CENGEL

Publisher: YUZU

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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 128P

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The x and y component of material acceleration ax and ay.

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Chapter 4, Problem 127P

Chapter 4, Problem 129P

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EBK FLUID MECHANICS: FUNDAMENTALS AND A

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The x and y component of material acceleration a x and a y .

Solution Summary: The author explains the x and y components of material acceleration in Equation (I).

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Chapter 4 Solutions