Explanation Write the expression of velocity potential function. ϕ = 2 x 2 y − ( 2 3 ) y 3 (I) Here, the displacement in x direction is x and the displacement in y direction is y . Write the expression of x component of the velocity. u = ∂ ϕ ∂ x (II) Substitute 2 x 2 y − ( 2 3 ) y 3 for ϕ in Equation (II). u = ∂ ∂ x { 2 x 2 y − ( 2 3 ) y 3 } = 2 y ∂ ∂ x ( x 2 ) − 2 3 ∂ ∂ x ( y 3 ) = 4 x y − 0 = 4 x y (III) Write the expression of y component of the velocity. v = ∂ ϕ ∂ y (IV) Substitute 2 x 2 y − ( 2 3 ) y 3 for ϕ in Equation (IV). v = ∂ ∂ y { 2 x 2 y − ( 2 3 ) y 3 } = 2 x 2 ∂ ∂ y ( y ) − 2 3 ∂ ∂ y ( y 3 ) = 2 x 2 − 2 3 × 3 y 2 = 2 ( x 2 − y 2 ) (V) Differentiate Equation (III) with respect to y . ∂ u ∂ y = ∂ ∂ y ( 4 x y ) = 4 x (VI) Differentiate Equation (V) with respect to x . ∂ v ∂ x = ∂ ∂ x { 2 ( x 2 − y 2 ) } = 2 × ∂ ∂ x ( x 2 ) = 4 x Write the expression of angular velocity. ω = 1 2 ( ∂ v ∂ x − ∂ u ∂ y ) (VII) Substitute 4 x for ∂ u ∂ y and 4 x for ∂ v ∂ x in Equation (VII). ω = 1 2 ( 4 x − 4 x ) = 1 2 × 0 = 0 Here, the angular velocity is zero, hence the floe is irrotational. Write the expression of Bernoulli’s equation for irrotational flow. p 1 γ + V 1 2 2 g = p 2 γ + V 2 2 2 g (VIII) Here, the pressure at point ( 1 , 1 ) is p 1 , the pressure at point ( 2 , 2 ) is p 2 , the acceleration due to gravity is g , the specific weight of the water is γ , the velocity at point ( 1 , 1 ) iws V 1 and the velocity at point ( 2 , 2 ) is V 2 . Write the expression of velocity at point ( 1 , 1 ) . V 1 = u 1 2 + v 1 2 (IX) Write the expression of velocity at point ( 2 , 2 ) . V 2 = u 2 2 + v 2 2 (X) Conclusion: At point ( 1 , 1 ) . Substitute u 1 for u 1 for x and 1 for y in Equation (III). u 1 = 4 × ( 1 ) × ( 1 ) = 4 m / s Substitute v 1 for v , 1 for x and 1 for y in Equation (IV)

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Chapter 6.4, Problem 32P

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The pressure at point x=2 m and y=2 m.

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Ch. 6.1 - Prob. 1P Ch. 6.1 - The velocity in a certain flow field is given by...Ch. 6.1 - The flow in the plane two-dimensional channel...Ch. 6.1 - The three components of velocity in a flow field...Ch. 6.1 - Determine an expression for the vorticity of the...Ch. 6.1 - According to Eq. 6.134, the x-velocity in fully...Ch. 6.1 - For a certain incompressible, two-dimensional flow...Ch. 6.1 - An incompressible viscous fluid is placed between...Ch. 6.1 - A viscous fluid is contained in the space between...Ch. 6.1 - ..Air is delivered through a constant-diameter...

Ch. 6.2 - For a certain incompressible flow field it is...Ch. 6.2 - Prob. 12P Ch. 6.2 - Prob. 14P Ch. 6.2 - For each of the following stream functions, with...Ch. 6.2 - The stream function for an incompressible,...Ch. 6.2 - Prob. 17P Ch. 6.2 - Prob. 18P Ch. 6.2 - In a two-dimensional, incompressible flow field,...Ch. 6.2 - The stream function for an incompressible flow...Ch. 6.2 - The stream function for an incompressible,...Ch. 6.2 - Consider the incompressible, two-dimensional flow...Ch. 6.3 - A fluid with a density of 2000 kg/m3 flows...Ch. 6.3 - Prob. 24P Ch. 6.3 - Prob. 25P Ch. 6.4 - The stream function for a given two-dimensional...Ch. 6.4 - Prob. 27P Ch. 6.4 - Prob. 28P Ch. 6.4 - Prob. 29P Ch. 6.4 - The velocity potential for a certain inviscid flow...Ch. 6.4 - Prob. 31P Ch. 6.4 - Prob. 32P Ch. 6.4 - Prob. 33P Ch. 6.4 - Prob. 34P Ch. 6.4 - Prob. 35P Ch. 6.4 - Prob. 36P Ch. 6.4 - Prob. 37P Ch. 6.5 - Prob. 38P Ch. 6.5 - Prob. 39P Ch. 6.5 - Water flows through a two-dimensional diffuser...Ch. 6.5 - Prob. 41P Ch. 6.5 - Prob. 42P Ch. 6.5 - Prob. 43P Ch. 6.5 - Prob. 44P Ch. 6.5 - Prob. 45P Ch. 6.5 - Prob. 46P Ch. 6.5 - Consider the flow of a liquid of viscosity μ and...Ch. 6.5 - Prob. 48P Ch. 6.5 - Show that the circulation of a free vortex for any...Ch. 6.5 - Prob. 50P Ch. 6.6 - Potential flow against a flat plate (Fig. P6.51a)...Ch. 6.6 - Prob. 52P Ch. 6.6 - Prob. 53P Ch. 6.6 - Prob. 54P Ch. 6.6 - Prob. 55P Ch. 6.6 - Prob. 56P Ch. 6.6 - A 15-mph wind flows over a Quonset hut having a...Ch. 6.6 - Prob. 58P Ch. 6.6 - Prob. 59P Ch. 6.6 - Prob. 60P Ch. 6.6 - Prob. 61P Ch. 6.6 - Prob. 62P Ch. 6.6 - The velocity potential for a cylinder (Fig. P6.63)...Ch. 6.6 - (See The Wide World of Fluids article titled “A...Ch. 6.6 - Prob. 65P Ch. 6.6 - Air at 25 °C flows normal to the axis of an...Ch. 6.8 - Determine the shearing stress for an...Ch. 6.8 - Prob. 68P Ch. 6.8 - The velocity of a fluid particle moving along a...Ch. 6.8 - “Stokes’s first problem” involves the...Ch. 6.9 - Oil (SAE 30) at 15.6 °C flows steadily between...Ch. 6.9 - Prob. 72P Ch. 6.9 - Prob. 73P Ch. 6.9 - We will see in Chapter 8 that the pressure drop in...Ch. 6.9 - (See The Wide World of Fluids article titled “10...Ch. 6.9 - The bearing shown in Fig. P6.76 consists of two...Ch. 6.9 - Prob. 77P Ch. 6.9 - Prob. 78P Ch. 6.9 - An incompressible, viscous fluid is placed between...Ch. 6.9 - Two immiscible, incompressible, viscous fluids...Ch. 6.9 - Prob. 81P Ch. 6.9 - A viscous fluid (specific weight = 80 lb/ft3;...Ch. 6.9 - A flat block is pulled along a horizontal flat...Ch. 6.9 - A viscosity motor/pump is shown in Fig. P6.84. The...Ch. 6.9 - A vertical shaft passes through a bearing and is...Ch. 6.9 - A viscous fluid is contained between two long...Ch. 6.9 - Verify that the momentum correction factor β for...Ch. 6.9 - Verify that the kinetic energy correction factor α...Ch. 6.9 - A simple flow system to be used for steady-flow...Ch. 6.9 - (a) Show that for Poiseuille flow in a tube of...Ch. 6.9 - An infinitely long, solid, vertical cylinder of...Ch. 6.9 - We will see in Chapter 8 that the pressure drop in...Ch. 6.9 - A liquid (viscosity = 0.002 N · s/m2; density =...Ch. 6.9 - Fluid with kinematic viscosity ν flows down an...Ch. 6.9 - Blood flows at volume rate Q in a circular tube of...Ch. 6.9 - An incompressible Newtonian fluid flows steadily...Ch. 6.9 - Prob. 97P Ch. 6.9 - Prob. 98P Ch. 6.9 - Prob. 99P Ch. 6.10 - Prob. 101P Ch. 6.10 - Prob. 102P Ch. 6.11 - Prob. 1LLP Ch. 6.11 - Prob. 2LLP Ch. 6.11 - Prob. 3LLP

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The pressure at point x = 2 m and y = 2 m .

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