(a) The validation of continuity equation.

Question

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Answer 1

Question

Chapter 4, Problem 4.30P

To determine

(a)

The validation of continuity equation.

Expert Solution

Answer to Problem 4.30P

The continuity equation is valid for the given velocity distribution.

Explanation of Solution

Given information:

Two dimensional converging nozzle velocity distribution in x direction, y direction and z direction is u=Uo1+xL, v=−UoyL, w=0 respectively. Here, the velocity in x -direction is u, velocity, the velocity in y -direction is v . the velocity in z direction is w.

Write the expression for two dimensional incompressible continuity Equation.

∂u∂x+∂v∂y=0 ... (I)

Here, the velocity of fluid along x and y directions are u and v respectively, Velocity component along x direction is ∂u∂x, Velocity component along y direction is ∂v∂y.

Calculation:

Substitute Uo1+xL for u, −UoyL for v, in Equation (I).

∂∂xUo 1+ x L +∂∂y−UoyL=0Uo 0+ 1 L +−Uo1L=0UoL−UoL=0

Conclusion:

The given distribution satisfies the two dimensional continuity equation..

To determine

(b)

The validation of Navier stokes equation.

Expert Solution

Answer to Problem 4.30P

Navier stokes equation is valid for the the given velocity distribution.

Explanation of Solution

Write the expression for two dimensional incompressible Navier stoke equation in x direction.

u∂u∂x+v∂u∂y=−1ρ∂p∂x+v∂2u∂x2+∂2v∂y2 ... (II)

Write the expression for two dimensional incompressible Navier stoke equation in y direction.

u∂v∂x+v∂v∂y=−1ρ∂p∂y+v∂2v∂x2+∂2v∂y2 ... (III)

Here, the velocity of fluid along x and y directions are u and v respectively, Velocity component along x direction is ∂u∂x, Velocity component along y direction is ∂v∂y

Write the expression for validation for Navier stokes equation in x-direction.

∂2p∂x∂y=∂∂x∂p∂y=0 ... (IV)

Write the expression for validation for Navier stokes equation in y-direction.

∂2p∂y∂x=∂∂y∂p∂x=0 ... (V)

Calculation:

Substitute Uo1+xL for u, −UoyL for v, 0 for ∂2u∂x2, 0 for ∂2u∂y2 in Equation (II).

U o 1+ x L ∂ U o 1+ x L ∂x + − U o y L ∂ U o 1+ x L ∂y =−1ρ∂p∂x+v0+0Uo 1+ x L U o L + − U o y L 0=−1ρ∂p∂x+0 U o 2 L 1+ x L +0=−1ρ∂p∂x−ρ U o 2 L1+xL=∂p∂x

∂p∂x=−ρUo2L1+xL ... (VI)

Substitute Uo1+xL for u, −UoyL for v, 0 for ∂2u∂x2, 0 for ∂2u∂y2 in Equation (III).

Uo 1+ x L ∂ − U o y L ∂x+−UoyL∂ − U o y L ∂y=−1ρ∂p∂y+v0+0Uo1+xL0+−UoyL−Uo1L=−1ρ∂p∂y+00+ U o 2 y L 2 =−1ρ∂p∂y−ρ U o 2 y L 2 =∂p∂y

∂p∂y=−ρUo2yL2 ... (VII)

Substitute −ρUo2yL2 for ∂p∂y in Equation (IV).

∂∂x−ρ U o 2 y L 2 =00=0

Hence the equation v=−UoyL has an exact solution to Navier stokes

Substitute −ρUo2L1+xL for ∂p∂x in Equation (V).

∂∂y −ρ U o 2 L 1+ x L =00=0

Hence the equation u=Uo1+xL has an exact solution to Navier stokes

Conclusion:

Navier stokes equation is valid for the given velocity distribution.

To determine

(c)

The pressure distribution p(x,y).

Expert Solution

Answer to Problem 4.30P

The pressure distribution p(x,y) is −ρUo2Lx+x22L+y22L+po

Explanation of Solution

Given information:

The pressure at the origin is pa.

Write the expression for pressure distribution in x direction.

px=∫∂p∂xdx ... (VIII)

Write the expression for pressure distribution in y direction.

py=∫∂p∂ydy ... (IX)

Write the expression for pressure distribution

p=px+py ... (X)

Calculation:

Substitute −ρUo2L1+xL for ∂p∂x in Equation (VIII).

px=∫ −ρ U o 2 L 1+ x L dx= −ρ U o 2 Lx+ x 2 2L ... (XI)

Substitute −ρUo2yL2 for ∂p∂y in Equation (IX).

py=∫ −ρ U o 2 y L 2 dy=−ρUo2 y 2 2 L 2 +C ... (XII)

Substitute pa for C in Equation (XII).

−ρUo2y22L2+Pa

Substitute −ρUo2Lx+x22L for px and −ρUo2y22L2+Pa for py in Equation (X)

p= −ρ U o 2 Lx+ x 2 2L−ρUo2 y 2 2 L 2 +Pa=−ρUo2Lx+ x 2 2L+ y 2 2 L 2 +Pa

Conclusion:

The pressure field p(x,y) is −ρUo2Lx+x22L+y22L2+Pa.

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Answer 2

Question

Chapter 4, Problem 4.30P

To determine

(a)

The validation of continuity equation.

Expert Solution

Answer to Problem 4.30P

The continuity equation is valid for the given velocity distribution.

Explanation of Solution

Given information:

Two dimensional converging nozzle velocity distribution in x direction, y direction and z direction is u=Uo1+xL, v=−UoyL, w=0 respectively. Here, the velocity in x -direction is u, velocity, the velocity in y -direction is v . the velocity in z direction is w.

Write the expression for two dimensional incompressible continuity Equation.

∂u∂x+∂v∂y=0 ... (I)

Here, the velocity of fluid along x and y directions are u and v respectively, Velocity component along x direction is ∂u∂x, Velocity component along y direction is ∂v∂y.

Calculation:

Substitute Uo1+xL for u, −UoyL for v, in Equation (I).

∂∂xUo 1+ x L +∂∂y−UoyL=0Uo 0+ 1 L +−Uo1L=0UoL−UoL=0

Conclusion:

The given distribution satisfies the two dimensional continuity equation..

To determine

(b)

The validation of Navier stokes equation.

Expert Solution

Answer to Problem 4.30P

Navier stokes equation is valid for the the given velocity distribution.

Explanation of Solution

Write the expression for two dimensional incompressible Navier stoke equation in x direction.

u∂u∂x+v∂u∂y=−1ρ∂p∂x+v∂2u∂x2+∂2v∂y2 ... (II)

Write the expression for two dimensional incompressible Navier stoke equation in y direction.

u∂v∂x+v∂v∂y=−1ρ∂p∂y+v∂2v∂x2+∂2v∂y2 ... (III)

Here, the velocity of fluid along x and y directions are u and v respectively, Velocity component along x direction is ∂u∂x, Velocity component along y direction is ∂v∂y

Write the expression for validation for Navier stokes equation in x-direction.

∂2p∂x∂y=∂∂x∂p∂y=0 ... (IV)

Write the expression for validation for Navier stokes equation in y-direction.

∂2p∂y∂x=∂∂y∂p∂x=0 ... (V)

Calculation:

Substitute Uo1+xL for u, −UoyL for v, 0 for ∂2u∂x2, 0 for ∂2u∂y2 in Equation (II).

U o 1+ x L ∂ U o 1+ x L ∂x + − U o y L ∂ U o 1+ x L ∂y =−1ρ∂p∂x+v0+0Uo 1+ x L U o L + − U o y L 0=−1ρ∂p∂x+0 U o 2 L 1+ x L +0=−1ρ∂p∂x−ρ U o 2 L1+xL=∂p∂x

∂p∂x=−ρUo2L1+xL ... (VI)

Substitute Uo1+xL for u, −UoyL for v, 0 for ∂2u∂x2, 0 for ∂2u∂y2 in Equation (III).

Uo 1+ x L ∂ − U o y L ∂x+−UoyL∂ − U o y L ∂y=−1ρ∂p∂y+v0+0Uo1+xL0+−UoyL−Uo1L=−1ρ∂p∂y+00+ U o 2 y L 2 =−1ρ∂p∂y−ρ U o 2 y L 2 =∂p∂y

∂p∂y=−ρUo2yL2 ... (VII)

Substitute −ρUo2yL2 for ∂p∂y in Equation (IV).

∂∂x−ρ U o 2 y L 2 =00=0

Hence the equation v=−UoyL has an exact solution to Navier stokes

Substitute −ρUo2L1+xL for ∂p∂x in Equation (V).

∂∂y −ρ U o 2 L 1+ x L =00=0

Hence the equation u=Uo1+xL has an exact solution to Navier stokes

Conclusion:

Navier stokes equation is valid for the given velocity distribution.

To determine

(c)

The pressure distribution p(x,y).

Expert Solution

Answer to Problem 4.30P

The pressure distribution p(x,y) is −ρUo2Lx+x22L+y22L+po

Explanation of Solution

Given information:

The pressure at the origin is pa.

Write the expression for pressure distribution in x direction.

px=∫∂p∂xdx ... (VIII)

Write the expression for pressure distribution in y direction.

py=∫∂p∂ydy ... (IX)

Write the expression for pressure distribution

p=px+py ... (X)

Calculation:

Substitute −ρUo2L1+xL for ∂p∂x in Equation (VIII).

px=∫ −ρ U o 2 L 1+ x L dx= −ρ U o 2 Lx+ x 2 2L ... (XI)

Substitute −ρUo2yL2 for ∂p∂y in Equation (IX).

py=∫ −ρ U o 2 y L 2 dy=−ρUo2 y 2 2 L 2 +C ... (XII)

Substitute pa for C in Equation (XII).

−ρUo2y22L2+Pa

Substitute −ρUo2Lx+x22L for px and −ρUo2y22L2+Pa for py in Equation (X)

p= −ρ U o 2 Lx+ x 2 2L−ρUo2 y 2 2 L 2 +Pa=−ρUo2Lx+ x 2 2L+ y 2 2 L 2 +Pa

Conclusion:

The pressure field p(x,y) is −ρUo2Lx+x22L+y22L2+Pa.

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Answer 3

Question

Chapter 4, Problem 4.30P

To determine

(a)

The validation of continuity equation.

Expert Solution

Answer to Problem 4.30P

The continuity equation is valid for the given velocity distribution.

Explanation of Solution

Given information:

Two dimensional converging nozzle velocity distribution in x direction, y direction and z direction is u=Uo1+xL, v=−UoyL, w=0 respectively. Here, the velocity in x -direction is u, velocity, the velocity in y -direction is v . the velocity in z direction is w.

Write the expression for two dimensional incompressible continuity Equation.

∂u∂x+∂v∂y=0 ... (I)

Here, the velocity of fluid along x and y directions are u and v respectively, Velocity component along x direction is ∂u∂x, Velocity component along y direction is ∂v∂y.

Calculation:

Substitute Uo1+xL for u, −UoyL for v, in Equation (I).

∂∂xUo 1+ x L +∂∂y−UoyL=0Uo 0+ 1 L +−Uo1L=0UoL−UoL=0

Conclusion:

The given distribution satisfies the two dimensional continuity equation..

To determine

(b)

The validation of Navier stokes equation.

Expert Solution

Answer to Problem 4.30P

Navier stokes equation is valid for the the given velocity distribution.

Explanation of Solution

Write the expression for two dimensional incompressible Navier stoke equation in x direction.

u∂u∂x+v∂u∂y=−1ρ∂p∂x+v∂2u∂x2+∂2v∂y2 ... (II)

Write the expression for two dimensional incompressible Navier stoke equation in y direction.

u∂v∂x+v∂v∂y=−1ρ∂p∂y+v∂2v∂x2+∂2v∂y2 ... (III)

Here, the velocity of fluid along x and y directions are u and v respectively, Velocity component along x direction is ∂u∂x, Velocity component along y direction is ∂v∂y

Write the expression for validation for Navier stokes equation in x-direction.

∂2p∂x∂y=∂∂x∂p∂y=0 ... (IV)

Write the expression for validation for Navier stokes equation in y-direction.

∂2p∂y∂x=∂∂y∂p∂x=0 ... (V)

Calculation:

Substitute Uo1+xL for u, −UoyL for v, 0 for ∂2u∂x2, 0 for ∂2u∂y2 in Equation (II).

U o 1+ x L ∂ U o 1+ x L ∂x + − U o y L ∂ U o 1+ x L ∂y =−1ρ∂p∂x+v0+0Uo 1+ x L U o L + − U o y L 0=−1ρ∂p∂x+0 U o 2 L 1+ x L +0=−1ρ∂p∂x−ρ U o 2 L1+xL=∂p∂x

∂p∂x=−ρUo2L1+xL ... (VI)

Substitute Uo1+xL for u, −UoyL for v, 0 for ∂2u∂x2, 0 for ∂2u∂y2 in Equation (III).

Uo 1+ x L ∂ − U o y L ∂x+−UoyL∂ − U o y L ∂y=−1ρ∂p∂y+v0+0Uo1+xL0+−UoyL−Uo1L=−1ρ∂p∂y+00+ U o 2 y L 2 =−1ρ∂p∂y−ρ U o 2 y L 2 =∂p∂y

∂p∂y=−ρUo2yL2 ... (VII)

Substitute −ρUo2yL2 for ∂p∂y in Equation (IV).

∂∂x−ρ U o 2 y L 2 =00=0

Hence the equation v=−UoyL has an exact solution to Navier stokes

Substitute −ρUo2L1+xL for ∂p∂x in Equation (V).

∂∂y −ρ U o 2 L 1+ x L =00=0

Hence the equation u=Uo1+xL has an exact solution to Navier stokes

Conclusion:

Navier stokes equation is valid for the given velocity distribution.

To determine

(c)

The pressure distribution p(x,y).

Expert Solution

Answer to Problem 4.30P

The pressure distribution p(x,y) is −ρUo2Lx+x22L+y22L+po

Explanation of Solution

Given information:

The pressure at the origin is pa.

Write the expression for pressure distribution in x direction.

px=∫∂p∂xdx ... (VIII)

Write the expression for pressure distribution in y direction.

py=∫∂p∂ydy ... (IX)

Write the expression for pressure distribution

p=px+py ... (X)

Calculation:

Substitute −ρUo2L1+xL for ∂p∂x in Equation (VIII).

px=∫ −ρ U o 2 L 1+ x L dx= −ρ U o 2 Lx+ x 2 2L ... (XI)

Substitute −ρUo2yL2 for ∂p∂y in Equation (IX).

py=∫ −ρ U o 2 y L 2 dy=−ρUo2 y 2 2 L 2 +C ... (XII)

Substitute pa for C in Equation (XII).

−ρUo2y22L2+Pa

Substitute −ρUo2Lx+x22L for px and −ρUo2y22L2+Pa for py in Equation (X)

p= −ρ U o 2 Lx+ x 2 2L−ρUo2 y 2 2 L 2 +Pa=−ρUo2Lx+ x 2 2L+ y 2 2 L 2 +Pa

Conclusion:

The pressure field p(x,y) is −ρUo2Lx+x22L+y22L2+Pa.

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Answer 4

Question

Chapter 4, Problem 4.30P

To determine

(a)

The validation of continuity equation.

Expert Solution

Answer to Problem 4.30P

The continuity equation is valid for the given velocity distribution.

Explanation of Solution

Given information:

Two dimensional converging nozzle velocity distribution in x direction, y direction and z direction is u=Uo1+xL, v=−UoyL, w=0 respectively. Here, the velocity in x -direction is u, velocity, the velocity in y -direction is v . the velocity in z direction is w.

Write the expression for two dimensional incompressible continuity Equation.

∂u∂x+∂v∂y=0 ... (I)

Here, the velocity of fluid along x and y directions are u and v respectively, Velocity component along x direction is ∂u∂x, Velocity component along y direction is ∂v∂y.

Calculation:

Substitute Uo1+xL for u, −UoyL for v, in Equation (I).

∂∂xUo 1+ x L +∂∂y−UoyL=0Uo 0+ 1 L +−Uo1L=0UoL−UoL=0

Conclusion:

The given distribution satisfies the two dimensional continuity equation..

To determine

(b)

The validation of Navier stokes equation.

Expert Solution

Answer to Problem 4.30P

Navier stokes equation is valid for the the given velocity distribution.

Explanation of Solution

Write the expression for two dimensional incompressible Navier stoke equation in x direction.

u∂u∂x+v∂u∂y=−1ρ∂p∂x+v∂2u∂x2+∂2v∂y2 ... (II)

Write the expression for two dimensional incompressible Navier stoke equation in y direction.

u∂v∂x+v∂v∂y=−1ρ∂p∂y+v∂2v∂x2+∂2v∂y2 ... (III)

Here, the velocity of fluid along x and y directions are u and v respectively, Velocity component along x direction is ∂u∂x, Velocity component along y direction is ∂v∂y

Write the expression for validation for Navier stokes equation in x-direction.

∂2p∂x∂y=∂∂x∂p∂y=0 ... (IV)

Write the expression for validation for Navier stokes equation in y-direction.

∂2p∂y∂x=∂∂y∂p∂x=0 ... (V)

Calculation:

Substitute Uo1+xL for u, −UoyL for v, 0 for ∂2u∂x2, 0 for ∂2u∂y2 in Equation (II).

U o 1+ x L ∂ U o 1+ x L ∂x + − U o y L ∂ U o 1+ x L ∂y =−1ρ∂p∂x+v0+0Uo 1+ x L U o L + − U o y L 0=−1ρ∂p∂x+0 U o 2 L 1+ x L +0=−1ρ∂p∂x−ρ U o 2 L1+xL=∂p∂x

∂p∂x=−ρUo2L1+xL ... (VI)

Substitute Uo1+xL for u, −UoyL for v, 0 for ∂2u∂x2, 0 for ∂2u∂y2 in Equation (III).

Uo 1+ x L ∂ − U o y L ∂x+−UoyL∂ − U o y L ∂y=−1ρ∂p∂y+v0+0Uo1+xL0+−UoyL−Uo1L=−1ρ∂p∂y+00+ U o 2 y L 2 =−1ρ∂p∂y−ρ U o 2 y L 2 =∂p∂y

∂p∂y=−ρUo2yL2 ... (VII)

Substitute −ρUo2yL2 for ∂p∂y in Equation (IV).

∂∂x−ρ U o 2 y L 2 =00=0

Hence the equation v=−UoyL has an exact solution to Navier stokes

Substitute −ρUo2L1+xL for ∂p∂x in Equation (V).

∂∂y −ρ U o 2 L 1+ x L =00=0

Hence the equation u=Uo1+xL has an exact solution to Navier stokes

Conclusion:

Navier stokes equation is valid for the given velocity distribution.

To determine

(c)

The pressure distribution p(x,y).

Expert Solution

Answer to Problem 4.30P

The pressure distribution p(x,y) is −ρUo2Lx+x22L+y22L+po

Explanation of Solution

Given information:

The pressure at the origin is pa.

Write the expression for pressure distribution in x direction.

px=∫∂p∂xdx ... (VIII)

Write the expression for pressure distribution in y direction.

py=∫∂p∂ydy ... (IX)

Write the expression for pressure distribution

p=px+py ... (X)

Calculation:

Substitute −ρUo2L1+xL for ∂p∂x in Equation (VIII).

px=∫ −ρ U o 2 L 1+ x L dx= −ρ U o 2 Lx+ x 2 2L ... (XI)

Substitute −ρUo2yL2 for ∂p∂y in Equation (IX).

py=∫ −ρ U o 2 y L 2 dy=−ρUo2 y 2 2 L 2 +C ... (XII)

Substitute pa for C in Equation (XII).

−ρUo2y22L2+Pa

Substitute −ρUo2Lx+x22L for px and −ρUo2y22L2+Pa for py in Equation (X)

p= −ρ U o 2 Lx+ x 2 2L−ρUo2 y 2 2 L 2 +Pa=−ρUo2Lx+ x 2 2L+ y 2 2 L 2 +Pa

Conclusion:

The pressure field p(x,y) is −ρUo2Lx+x22L+y22L2+Pa.

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Answer 5

Chapter 4, Problem 4.30P

To determine

(a)

The validation of continuity equation.

Expert Solution

Answer to Problem 4.30P

The continuity equation is valid for the given velocity distribution.

Explanation of Solution

Given information:

Two dimensional converging nozzle velocity distribution in x direction, y direction and z direction is u=Uo1+xL, v=−UoyL, w=0 respectively. Here, the velocity in x -direction is u, velocity, the velocity in y -direction is v . the velocity in z direction is w.

Write the expression for two dimensional incompressible continuity Equation.

∂u∂x+∂v∂y=0 ... (I)

Here, the velocity of fluid along x and y directions are u and v respectively, Velocity component along x direction is ∂u∂x, Velocity component along y direction is ∂v∂y.

Calculation:

Substitute Uo1+xL for u, −UoyL for v, in Equation (I).

∂∂xUo 1+ x L +∂∂y−UoyL=0Uo 0+ 1 L +−Uo1L=0UoL−UoL=0

Conclusion:

The given distribution satisfies the two dimensional continuity equation..

To determine

(b)

The validation of Navier stokes equation.

Expert Solution

Answer to Problem 4.30P

Navier stokes equation is valid for the the given velocity distribution.

Explanation of Solution

Write the expression for two dimensional incompressible Navier stoke equation in x direction.

u∂u∂x+v∂u∂y=−1ρ∂p∂x+v∂2u∂x2+∂2v∂y2 ... (II)

Write the expression for two dimensional incompressible Navier stoke equation in y direction.

u∂v∂x+v∂v∂y=−1ρ∂p∂y+v∂2v∂x2+∂2v∂y2 ... (III)

Here, the velocity of fluid along x and y directions are u and v respectively, Velocity component along x direction is ∂u∂x, Velocity component along y direction is ∂v∂y

Write the expression for validation for Navier stokes equation in x-direction.

∂2p∂x∂y=∂∂x∂p∂y=0 ... (IV)

Write the expression for validation for Navier stokes equation in y-direction.

∂2p∂y∂x=∂∂y∂p∂x=0 ... (V)

Calculation:

Substitute Uo1+xL for u, −UoyL for v, 0 for ∂2u∂x2, 0 for ∂2u∂y2 in Equation (II).

U o 1+ x L ∂ U o 1+ x L ∂x + − U o y L ∂ U o 1+ x L ∂y =−1ρ∂p∂x+v0+0Uo 1+ x L U o L + − U o y L 0=−1ρ∂p∂x+0 U o 2 L 1+ x L +0=−1ρ∂p∂x−ρ U o 2 L1+xL=∂p∂x

∂p∂x=−ρUo2L1+xL ... (VI)

Substitute Uo1+xL for u, −UoyL for v, 0 for ∂2u∂x2, 0 for ∂2u∂y2 in Equation (III).

Uo 1+ x L ∂ − U o y L ∂x+−UoyL∂ − U o y L ∂y=−1ρ∂p∂y+v0+0Uo1+xL0+−UoyL−Uo1L=−1ρ∂p∂y+00+ U o 2 y L 2 =−1ρ∂p∂y−ρ U o 2 y L 2 =∂p∂y

∂p∂y=−ρUo2yL2 ... (VII)

Substitute −ρUo2yL2 for ∂p∂y in Equation (IV).

∂∂x−ρ U o 2 y L 2 =00=0

Hence the equation v=−UoyL has an exact solution to Navier stokes

Substitute −ρUo2L1+xL for ∂p∂x in Equation (V).

∂∂y −ρ U o 2 L 1+ x L =00=0

Hence the equation u=Uo1+xL has an exact solution to Navier stokes

Conclusion:

Navier stokes equation is valid for the given velocity distribution.

To determine

(c)

The pressure distribution p(x,y).

Expert Solution

Answer to Problem 4.30P

The pressure distribution p(x,y) is −ρUo2Lx+x22L+y22L+po

Explanation of Solution

Given information:

The pressure at the origin is pa.

Write the expression for pressure distribution in x direction.

px=∫∂p∂xdx ... (VIII)

Write the expression for pressure distribution in y direction.

py=∫∂p∂ydy ... (IX)

Write the expression for pressure distribution

p=px+py ... (X)

Calculation:

Substitute −ρUo2L1+xL for ∂p∂x in Equation (VIII).

px=∫ −ρ U o 2 L 1+ x L dx= −ρ U o 2 Lx+ x 2 2L ... (XI)

Substitute −ρUo2yL2 for ∂p∂y in Equation (IX).

py=∫ −ρ U o 2 y L 2 dy=−ρUo2 y 2 2 L 2 +C ... (XII)

Substitute pa for C in Equation (XII).

−ρUo2y22L2+Pa

Substitute −ρUo2Lx+x22L for px and −ρUo2y22L2+Pa for py in Equation (X)

p= −ρ U o 2 Lx+ x 2 2L−ρUo2 y 2 2 L 2 +Pa=−ρUo2Lx+ x 2 2L+ y 2 2 L 2 +Pa

Conclusion:

The pressure field p(x,y) is −ρUo2Lx+x22L+y22L2+Pa.

Answer 6

Chapter 4, Problem 4.30P

To determine

(a)

The validation of continuity equation.

Expert Solution

Answer to Problem 4.30P

The continuity equation is valid for the given velocity distribution.

Explanation of Solution

Given information:

Two dimensional converging nozzle velocity distribution in x direction, y direction and z direction is u=Uo1+xL, v=−UoyL, w=0 respectively. Here, the velocity in x -direction is u, velocity, the velocity in y -direction is v . the velocity in z direction is w.

Write the expression for two dimensional incompressible continuity Equation.

∂u∂x+∂v∂y=0 ... (I)

Here, the velocity of fluid along x and y directions are u and v respectively, Velocity component along x direction is ∂u∂x, Velocity component along y direction is ∂v∂y.

Calculation:

Substitute Uo1+xL for u, −UoyL for v, in Equation (I).

∂∂xUo 1+ x L +∂∂y−UoyL=0Uo 0+ 1 L +−Uo1L=0UoL−UoL=0

Conclusion:

The given distribution satisfies the two dimensional continuity equation..

Answer 7

Chapter 4, Problem 4.30P

To determine

(a)

The validation of continuity equation.

Answer 8

Expert Solution

Answer to Problem 4.30P

The continuity equation is valid for the given velocity distribution.

Answer 9

Expert Solution

Answer 10

Expert Solution

Answer 11

Expert Solution

Answer 12

Explanation of Solution

Given information:

Two dimensional converging nozzle velocity distribution in x direction, y direction and z direction is u=Uo1+xL, v=−UoyL, w=0 respectively. Here, the velocity in x -direction is u, velocity, the velocity in y -direction is v . the velocity in z direction is w.

Write the expression for two dimensional incompressible continuity Equation.

∂u∂x+∂v∂y=0 ... (I)

Here, the velocity of fluid along x and y directions are u and v respectively, Velocity component along x direction is ∂u∂x, Velocity component along y direction is ∂v∂y.

Calculation:

Substitute Uo1+xL for u, −UoyL for v, in Equation (I).

∂∂xUo 1+ x L +∂∂y−UoyL=0Uo 0+ 1 L +−Uo1L=0UoL−UoL=0

Conclusion:

The given distribution satisfies the two dimensional continuity equation..

Answer 13

To determine

(b)

The validation of Navier stokes equation.

Expert Solution

Answer to Problem 4.30P

Navier stokes equation is valid for the the given velocity distribution.

Explanation of Solution

Write the expression for two dimensional incompressible Navier stoke equation in x direction.

u∂u∂x+v∂u∂y=−1ρ∂p∂x+v∂2u∂x2+∂2v∂y2 ... (II)

Write the expression for two dimensional incompressible Navier stoke equation in y direction.

u∂v∂x+v∂v∂y=−1ρ∂p∂y+v∂2v∂x2+∂2v∂y2 ... (III)

Here, the velocity of fluid along x and y directions are u and v respectively, Velocity component along x direction is ∂u∂x, Velocity component along y direction is ∂v∂y

Write the expression for validation for Navier stokes equation in x-direction.

∂2p∂x∂y=∂∂x∂p∂y=0 ... (IV)

Write the expression for validation for Navier stokes equation in y-direction.

∂2p∂y∂x=∂∂y∂p∂x=0 ... (V)

Calculation:

Substitute Uo1+xL for u, −UoyL for v, 0 for ∂2u∂x2, 0 for ∂2u∂y2 in Equation (II).

U o 1+ x L ∂ U o 1+ x L ∂x + − U o y L ∂ U o 1+ x L ∂y =−1ρ∂p∂x+v0+0Uo 1+ x L U o L + − U o y L 0=−1ρ∂p∂x+0 U o 2 L 1+ x L +0=−1ρ∂p∂x−ρ U o 2 L1+xL=∂p∂x

∂p∂x=−ρUo2L1+xL ... (VI)

Substitute Uo1+xL for u, −UoyL for v, 0 for ∂2u∂x2, 0 for ∂2u∂y2 in Equation (III).

Uo 1+ x L ∂ − U o y L ∂x+−UoyL∂ − U o y L ∂y=−1ρ∂p∂y+v0+0Uo1+xL0+−UoyL−Uo1L=−1ρ∂p∂y+00+ U o 2 y L 2 =−1ρ∂p∂y−ρ U o 2 y L 2 =∂p∂y

∂p∂y=−ρUo2yL2 ... (VII)

Substitute −ρUo2yL2 for ∂p∂y in Equation (IV).

∂∂x−ρ U o 2 y L 2 =00=0

Hence the equation v=−UoyL has an exact solution to Navier stokes

Substitute −ρUo2L1+xL for ∂p∂x in Equation (V).

∂∂y −ρ U o 2 L 1+ x L =00=0

Hence the equation u=Uo1+xL has an exact solution to Navier stokes

Conclusion:

Navier stokes equation is valid for the given velocity distribution.

Answer 14

To determine

(b)

The validation of Navier stokes equation.

Answer 15

Expert Solution

Answer to Problem 4.30P

Navier stokes equation is valid for the the given velocity distribution.

Answer 16

Expert Solution

Answer 17

Expert Solution

Answer 18

Expert Solution

Answer 19

Explanation of Solution

Write the expression for two dimensional incompressible Navier stoke equation in x direction.

u∂u∂x+v∂u∂y=−1ρ∂p∂x+v∂2u∂x2+∂2v∂y2 ... (II)

Write the expression for two dimensional incompressible Navier stoke equation in y direction.

u∂v∂x+v∂v∂y=−1ρ∂p∂y+v∂2v∂x2+∂2v∂y2 ... (III)

Here, the velocity of fluid along x and y directions are u and v respectively, Velocity component along x direction is ∂u∂x, Velocity component along y direction is ∂v∂y

Write the expression for validation for Navier stokes equation in x-direction.

∂2p∂x∂y=∂∂x∂p∂y=0 ... (IV)

Write the expression for validation for Navier stokes equation in y-direction.

∂2p∂y∂x=∂∂y∂p∂x=0 ... (V)

Calculation:

Substitute Uo1+xL for u, −UoyL for v, 0 for ∂2u∂x2, 0 for ∂2u∂y2 in Equation (II).

U o 1+ x L ∂ U o 1+ x L ∂x + − U o y L ∂ U o 1+ x L ∂y =−1ρ∂p∂x+v0+0Uo 1+ x L U o L + − U o y L 0=−1ρ∂p∂x+0 U o 2 L 1+ x L +0=−1ρ∂p∂x−ρ U o 2 L1+xL=∂p∂x

∂p∂x=−ρUo2L1+xL ... (VI)

Substitute Uo1+xL for u, −UoyL for v, 0 for ∂2u∂x2, 0 for ∂2u∂y2 in Equation (III).

Uo 1+ x L ∂ − U o y L ∂x+−UoyL∂ − U o y L ∂y=−1ρ∂p∂y+v0+0Uo1+xL0+−UoyL−Uo1L=−1ρ∂p∂y+00+ U o 2 y L 2 =−1ρ∂p∂y−ρ U o 2 y L 2 =∂p∂y

∂p∂y=−ρUo2yL2 ... (VII)

Substitute −ρUo2yL2 for ∂p∂y in Equation (IV).

∂∂x−ρ U o 2 y L 2 =00=0

Hence the equation v=−UoyL has an exact solution to Navier stokes

Substitute −ρUo2L1+xL for ∂p∂x in Equation (V).

∂∂y −ρ U o 2 L 1+ x L =00=0

Hence the equation u=Uo1+xL has an exact solution to Navier stokes

Conclusion:

Navier stokes equation is valid for the given velocity distribution.

Answer 20

To determine

(c)

The pressure distribution p(x,y).

Expert Solution

Answer to Problem 4.30P

The pressure distribution p(x,y) is −ρUo2Lx+x22L+y22L+po

Explanation of Solution

Given information:

The pressure at the origin is pa.

Write the expression for pressure distribution in x direction.

px=∫∂p∂xdx ... (VIII)

Write the expression for pressure distribution in y direction.

py=∫∂p∂ydy ... (IX)

Write the expression for pressure distribution

p=px+py ... (X)

Calculation:

Substitute −ρUo2L1+xL for ∂p∂x in Equation (VIII).

px=∫ −ρ U o 2 L 1+ x L dx= −ρ U o 2 Lx+ x 2 2L ... (XI)

Substitute −ρUo2yL2 for ∂p∂y in Equation (IX).

py=∫ −ρ U o 2 y L 2 dy=−ρUo2 y 2 2 L 2 +C ... (XII)

Substitute pa for C in Equation (XII).

−ρUo2y22L2+Pa

Substitute −ρUo2Lx+x22L for px and −ρUo2y22L2+Pa for py in Equation (X)

p= −ρ U o 2 Lx+ x 2 2L−ρUo2 y 2 2 L 2 +Pa=−ρUo2Lx+ x 2 2L+ y 2 2 L 2 +Pa

Conclusion:

The pressure field p(x,y) is −ρUo2Lx+x22L+y22L2+Pa.

Answer 21

To determine

(c)

The pressure distribution p(x,y).

Answer 22

Expert Solution

Answer to Problem 4.30P

The pressure distribution p(x,y) is −ρUo2Lx+x22L+y22L+po

Answer 23

Expert Solution

Answer 24

Expert Solution

Answer 25

Expert Solution

Answer 26

Explanation of Solution

Given information:

The pressure at the origin is pa.

Write the expression for pressure distribution in x direction.

px=∫∂p∂xdx ... (VIII)

Write the expression for pressure distribution in y direction.

py=∫∂p∂ydy ... (IX)

Write the expression for pressure distribution

p=px+py ... (X)

Calculation:

Substitute −ρUo2L1+xL for ∂p∂x in Equation (VIII).

px=∫ −ρ U o 2 L 1+ x L dx= −ρ U o 2 Lx+ x 2 2L ... (XI)

Substitute −ρUo2yL2 for ∂p∂y in Equation (IX).

py=∫ −ρ U o 2 y L 2 dy=−ρUo2 y 2 2 L 2 +C ... (XII)

Substitute pa for C in Equation (XII).

−ρUo2y22L2+Pa

Substitute −ρUo2Lx+x22L for px and −ρUo2y22L2+Pa for py in Equation (X)

p= −ρ U o 2 Lx+ x 2 2L−ρUo2 y 2 2 L 2 +Pa=−ρUo2Lx+ x 2 2L+ y 2 2 L 2 +Pa

Conclusion:

The pressure field p(x,y) is −ρUo2Lx+x22L+y22L2+Pa.

Answer 27

Ch. 4 - Prob. 4.1P Ch. 4 - Flow through the converging nozzle in Fig. P4.2...Ch. 4 - Prob. 4.3P Ch. 4 - Prob. 4.4P Ch. 4 - Prob. 4.5P Ch. 4 - Prob. 4.6P Ch. 4 - Prob. 4.7P Ch. 4 - P4.8 When a valve is opened, fluid flows in...Ch. 4 - An idealized incompressible flow has the proposed...Ch. 4 - A two-dimensional, incompressible flow has the...

(a) The validation of continuity equation.

Videos

(a)

The validation of continuity equation.

Answer to Problem 4.30P

Explanation of Solution

(b)

The validation of Navier stokes equation.

Answer to Problem 4.30P

Explanation of Solution

(c)

The pressure distribution p(x,y).

Answer to Problem 4.30P

Explanation of Solution

Want to see more full solutions like this?

Chapter 4 Solutions

(a) The validation of continuity equation.

Videos

(a) The validation of continuity equation.

Answer to Problem 4.30P

Explanation of Solution

(b) The validation of Navier stokes equation.

Answer to Problem 4.30P

Explanation of Solution

(c) The pressure distribution p(x,y).

Answer to Problem 4.30P

Explanation of Solution

Want to see more full solutions like this?

Chapter 4 Solutions

(a)

The validation of continuity equation.

(b)

The validation of Navier stokes equation.

(c)

The pressure distribution p(x,y).