The stramwise velocity component of steady, incompressible, laminar, flat plate boundary layer thickness δ is approximated by the simple linear expression, u = U y / δ for y < δ , and u = U for y > δ (Fig. 10-97). Generate expressions for displacement thickness momentum thickness as functions of δ , based on this linear approximation, Compare the approximate values of δ * / δ and θ / δ to the δ * / δ and θ / δ obtained from the Blasius solution. Answer: 0.500, 0.167 FIGURE P10-97

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Answer 1

Textbook Question

Chapter 10, Problem 97P

The stramwise velocity component of steady, incompressible, laminar, flat plate boundary layer thickness δ is approximated by the simple linear expression, u = U y / δ for y < δ , and u=U for y > δ (Fig. 10-97). Generate expressions for displacement thickness momentum thickness as functions of δ , based on this linear approximation, Compare the approximate values of δ * / δ and θ / δ to the δ * / δ and θ / δ obtained from the Blasius solution.

Answer: 0.500, 0.167

Chapter 10, Problem 97P, The stramwise velocity component of steady, incompressible, laminar, flat plate boundary layer
FIGURE P10-97

Expert Solution & Answer

To determine

The comparison between different ratio when approximation method and blasius methods are used simultaneously.

Answer to Problem 97P

The approximation value for δ*δ is 0.5.

The approximation value for θδ is 0.167.

The blasius solution for δ*δ is 0.35.

The blasius solution for θδ is 0.135.

Explanation of Solution

Given information:

Write the expression for velocity profile if y<δ.

u=Uyδ ...... (I)

Here, boundary layer thickness is δ, velocity function is u, maximum velocity of the laminar flow over the flat plate is U.

Write the expression for velocity profile if y>δ.

u=U ...... (II)

Here, maximum velocity of the laminar flow over the flat plate is U.

Write the expression for displacement thickness.

δ*=∫0δ(1− u y<δ U)dy+∫δ∞(1− u y>δU)dy ...... (III)

Write the expression for momentum thickness.

θ=∫0δu y<δU(1− u y<δ U)dy+∫δ∞uy>δU(1− u y>δU)dy ...... (IV)

Write the expression for Blasius solution for boundary layer thickness.

δ=4.91x Rex ...... (V)

Here, any location on flat plate is x, Reynolds number is Rex.

Write the expression for Blasius solution for displacement thickness.

δ*=1.72x Rex ...... (VI)

Write the expression for Blasius solution for momentum thickness.

θ=0.664x Rex ...... (VII)

Write the expression for the ratio of displacement thickness to boundary layer thickness.

R=δ*δ ...... (VIII)

Write the expression for momentum thickness to boundary layer thickness.

S=θδ ...... (IX)

Calculation:

Substitute Uyδ for uy<δ, and U for uy>δ in Equation (III).

δ*=∫0δ( 1− ( Uy δ ) U )dy+∫δ∞(1− U U)dy=∫0δ(1−yδ)dy+∫δ∞(0)dy=[y−y22δ]0δ=δ−δ22δ

δ*=δ2

The displacement thickness δ* is δ2.

Substitute Uyδ for uy<δ, and U for uy>δ in Equation (IV).

θ=∫0δ Uy δ U( 1− Uy δ U )dy+∫δ∞UU(1− U U)dy=∫0δyδ(1−yδ)dy+∫δ∞UU(0)dy=∫0δyδ(1−yδ)dy+0

θ=[ y 2 2δ− y 3 3 δ 2 ]0δ=( δ 2 2δ− δ 3 3 δ 2 )−0=δ2−δ3=δ6

The momentum thickness θ is δ6.

Substitute δ2 for δ* in Equation (VIII).

R=( δ 2 )δ=δ2δ=120.5

Ratio of displacement thickness to boundary layer thickness is 0.5.

Substitute δ6 for θ in Equation (IX).

S=( δ 6 )δ=δ6δ=16=0.167

Ratio of displacement thickness to boundary layer thickness is 0.167.

Divide Equation (VI) with Equation (V) when blasius solution is considered.

δ*δ=( 1.72x Re x )( 4.91x Re x )=1.724.91=0.35

Divide Equation (VII) with Equation (V) when blasius solution is considered.

θδ=( 0.664x Re x )( 4.91x Re x )=0.6644.91=0.135

Conclusion:

The approximation value for δ*δ is 0.5.

The approximation value for θδ is 0.167.

The blasius solution for δ*δ is 0.35.

The blasius solution for θδ is 0.135.

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Answer 2

Textbook Question

Chapter 10, Problem 97P

The stramwise velocity component of steady, incompressible, laminar, flat plate boundary layer thickness δ is approximated by the simple linear expression, u = U y / δ for y < δ , and u=U for y > δ (Fig. 10-97). Generate expressions for displacement thickness momentum thickness as functions of δ , based on this linear approximation, Compare the approximate values of δ * / δ and θ / δ to the δ * / δ and θ / δ obtained from the Blasius solution.

Answer: 0.500, 0.167

Chapter 10, Problem 97P, The stramwise velocity component of steady, incompressible, laminar, flat plate boundary layer
FIGURE P10-97

Expert Solution & Answer

To determine

The comparison between different ratio when approximation method and blasius methods are used simultaneously.

Answer to Problem 97P

The approximation value for δ*δ is 0.5.

The approximation value for θδ is 0.167.

The blasius solution for δ*δ is 0.35.

The blasius solution for θδ is 0.135.

Explanation of Solution

Given information:

Write the expression for velocity profile if y<δ.

u=Uyδ ...... (I)

Here, boundary layer thickness is δ, velocity function is u, maximum velocity of the laminar flow over the flat plate is U.

Write the expression for velocity profile if y>δ.

u=U ...... (II)

Here, maximum velocity of the laminar flow over the flat plate is U.

Write the expression for displacement thickness.

δ*=∫0δ(1− u y<δ U)dy+∫δ∞(1− u y>δU)dy ...... (III)

Write the expression for momentum thickness.

θ=∫0δu y<δU(1− u y<δ U)dy+∫δ∞uy>δU(1− u y>δU)dy ...... (IV)

Write the expression for Blasius solution for boundary layer thickness.

δ=4.91x Rex ...... (V)

Here, any location on flat plate is x, Reynolds number is Rex.

Write the expression for Blasius solution for displacement thickness.

δ*=1.72x Rex ...... (VI)

Write the expression for Blasius solution for momentum thickness.

θ=0.664x Rex ...... (VII)

Write the expression for the ratio of displacement thickness to boundary layer thickness.

R=δ*δ ...... (VIII)

Write the expression for momentum thickness to boundary layer thickness.

S=θδ ...... (IX)

Calculation:

Substitute Uyδ for uy<δ, and U for uy>δ in Equation (III).

δ*=∫0δ( 1− ( Uy δ ) U )dy+∫δ∞(1− U U)dy=∫0δ(1−yδ)dy+∫δ∞(0)dy=[y−y22δ]0δ=δ−δ22δ

δ*=δ2

The displacement thickness δ* is δ2.

Substitute Uyδ for uy<δ, and U for uy>δ in Equation (IV).

θ=∫0δ Uy δ U( 1− Uy δ U )dy+∫δ∞UU(1− U U)dy=∫0δyδ(1−yδ)dy+∫δ∞UU(0)dy=∫0δyδ(1−yδ)dy+0

θ=[ y 2 2δ− y 3 3 δ 2 ]0δ=( δ 2 2δ− δ 3 3 δ 2 )−0=δ2−δ3=δ6

The momentum thickness θ is δ6.

Substitute δ2 for δ* in Equation (VIII).

R=( δ 2 )δ=δ2δ=120.5

Ratio of displacement thickness to boundary layer thickness is 0.5.

Substitute δ6 for θ in Equation (IX).

S=( δ 6 )δ=δ6δ=16=0.167

Ratio of displacement thickness to boundary layer thickness is 0.167.

Divide Equation (VI) with Equation (V) when blasius solution is considered.

δ*δ=( 1.72x Re x )( 4.91x Re x )=1.724.91=0.35

Divide Equation (VII) with Equation (V) when blasius solution is considered.

θδ=( 0.664x Re x )( 4.91x Re x )=0.6644.91=0.135

Conclusion:

The approximation value for δ*δ is 0.5.

The approximation value for θδ is 0.167.

The blasius solution for δ*δ is 0.35.

The blasius solution for θδ is 0.135.

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Answer 3

Textbook Question

Chapter 10, Problem 97P

The stramwise velocity component of steady, incompressible, laminar, flat plate boundary layer thickness δ is approximated by the simple linear expression, u = U y / δ for y < δ , and u=U for y > δ (Fig. 10-97). Generate expressions for displacement thickness momentum thickness as functions of δ , based on this linear approximation, Compare the approximate values of δ * / δ and θ / δ to the δ * / δ and θ / δ obtained from the Blasius solution.

Answer: 0.500, 0.167

Chapter 10, Problem 97P, The stramwise velocity component of steady, incompressible, laminar, flat plate boundary layer
FIGURE P10-97

Expert Solution & Answer

To determine

The comparison between different ratio when approximation method and blasius methods are used simultaneously.

Answer to Problem 97P

The approximation value for δ*δ is 0.5.

The approximation value for θδ is 0.167.

The blasius solution for δ*δ is 0.35.

The blasius solution for θδ is 0.135.

Explanation of Solution

Given information:

Write the expression for velocity profile if y<δ.

u=Uyδ ...... (I)

Here, boundary layer thickness is δ, velocity function is u, maximum velocity of the laminar flow over the flat plate is U.

Write the expression for velocity profile if y>δ.

u=U ...... (II)

Here, maximum velocity of the laminar flow over the flat plate is U.

Write the expression for displacement thickness.

δ*=∫0δ(1− u y<δ U)dy+∫δ∞(1− u y>δU)dy ...... (III)

Write the expression for momentum thickness.

θ=∫0δu y<δU(1− u y<δ U)dy+∫δ∞uy>δU(1− u y>δU)dy ...... (IV)

Write the expression for Blasius solution for boundary layer thickness.

δ=4.91x Rex ...... (V)

Here, any location on flat plate is x, Reynolds number is Rex.

Write the expression for Blasius solution for displacement thickness.

δ*=1.72x Rex ...... (VI)

Write the expression for Blasius solution for momentum thickness.

θ=0.664x Rex ...... (VII)

Write the expression for the ratio of displacement thickness to boundary layer thickness.

R=δ*δ ...... (VIII)

Write the expression for momentum thickness to boundary layer thickness.

S=θδ ...... (IX)

Calculation:

Substitute Uyδ for uy<δ, and U for uy>δ in Equation (III).

δ*=∫0δ( 1− ( Uy δ ) U )dy+∫δ∞(1− U U)dy=∫0δ(1−yδ)dy+∫δ∞(0)dy=[y−y22δ]0δ=δ−δ22δ

δ*=δ2

The displacement thickness δ* is δ2.

Substitute Uyδ for uy<δ, and U for uy>δ in Equation (IV).

θ=∫0δ Uy δ U( 1− Uy δ U )dy+∫δ∞UU(1− U U)dy=∫0δyδ(1−yδ)dy+∫δ∞UU(0)dy=∫0δyδ(1−yδ)dy+0

θ=[ y 2 2δ− y 3 3 δ 2 ]0δ=( δ 2 2δ− δ 3 3 δ 2 )−0=δ2−δ3=δ6

The momentum thickness θ is δ6.

Substitute δ2 for δ* in Equation (VIII).

R=( δ 2 )δ=δ2δ=120.5

Ratio of displacement thickness to boundary layer thickness is 0.5.

Substitute δ6 for θ in Equation (IX).

S=( δ 6 )δ=δ6δ=16=0.167

Ratio of displacement thickness to boundary layer thickness is 0.167.

Divide Equation (VI) with Equation (V) when blasius solution is considered.

δ*δ=( 1.72x Re x )( 4.91x Re x )=1.724.91=0.35

Divide Equation (VII) with Equation (V) when blasius solution is considered.

θδ=( 0.664x Re x )( 4.91x Re x )=0.6644.91=0.135

Conclusion:

The approximation value for δ*δ is 0.5.

The approximation value for θδ is 0.167.

The blasius solution for δ*δ is 0.35.

The blasius solution for θδ is 0.135.

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Answer 4

Textbook Question

Chapter 10, Problem 97P

The stramwise velocity component of steady, incompressible, laminar, flat plate boundary layer thickness δ is approximated by the simple linear expression, u = U y / δ for y < δ , and u=U for y > δ (Fig. 10-97). Generate expressions for displacement thickness momentum thickness as functions of δ , based on this linear approximation, Compare the approximate values of δ * / δ and θ / δ to the δ * / δ and θ / δ obtained from the Blasius solution.

Answer: 0.500, 0.167

Chapter 10, Problem 97P, The stramwise velocity component of steady, incompressible, laminar, flat plate boundary layer
FIGURE P10-97

Expert Solution & Answer

To determine

The comparison between different ratio when approximation method and blasius methods are used simultaneously.

Answer to Problem 97P

The approximation value for δ*δ is 0.5.

The approximation value for θδ is 0.167.

The blasius solution for δ*δ is 0.35.

The blasius solution for θδ is 0.135.

Explanation of Solution

Given information:

Write the expression for velocity profile if y<δ.

u=Uyδ ...... (I)

Here, boundary layer thickness is δ, velocity function is u, maximum velocity of the laminar flow over the flat plate is U.

Write the expression for velocity profile if y>δ.

u=U ...... (II)

Here, maximum velocity of the laminar flow over the flat plate is U.

Write the expression for displacement thickness.

δ*=∫0δ(1− u y<δ U)dy+∫δ∞(1− u y>δU)dy ...... (III)

Write the expression for momentum thickness.

θ=∫0δu y<δU(1− u y<δ U)dy+∫δ∞uy>δU(1− u y>δU)dy ...... (IV)

Write the expression for Blasius solution for boundary layer thickness.

δ=4.91x Rex ...... (V)

Here, any location on flat plate is x, Reynolds number is Rex.

Write the expression for Blasius solution for displacement thickness.

δ*=1.72x Rex ...... (VI)

Write the expression for Blasius solution for momentum thickness.

θ=0.664x Rex ...... (VII)

Write the expression for the ratio of displacement thickness to boundary layer thickness.

R=δ*δ ...... (VIII)

Write the expression for momentum thickness to boundary layer thickness.

S=θδ ...... (IX)

Calculation:

Substitute Uyδ for uy<δ, and U for uy>δ in Equation (III).

δ*=∫0δ( 1− ( Uy δ ) U )dy+∫δ∞(1− U U)dy=∫0δ(1−yδ)dy+∫δ∞(0)dy=[y−y22δ]0δ=δ−δ22δ

δ*=δ2

The displacement thickness δ* is δ2.

Substitute Uyδ for uy<δ, and U for uy>δ in Equation (IV).

θ=∫0δ Uy δ U( 1− Uy δ U )dy+∫δ∞UU(1− U U)dy=∫0δyδ(1−yδ)dy+∫δ∞UU(0)dy=∫0δyδ(1−yδ)dy+0

θ=[ y 2 2δ− y 3 3 δ 2 ]0δ=( δ 2 2δ− δ 3 3 δ 2 )−0=δ2−δ3=δ6

The momentum thickness θ is δ6.

Substitute δ2 for δ* in Equation (VIII).

R=( δ 2 )δ=δ2δ=120.5

Ratio of displacement thickness to boundary layer thickness is 0.5.

Substitute δ6 for θ in Equation (IX).

S=( δ 6 )δ=δ6δ=16=0.167

Ratio of displacement thickness to boundary layer thickness is 0.167.

Divide Equation (VI) with Equation (V) when blasius solution is considered.

δ*δ=( 1.72x Re x )( 4.91x Re x )=1.724.91=0.35

Divide Equation (VII) with Equation (V) when blasius solution is considered.

θδ=( 0.664x Re x )( 4.91x Re x )=0.6644.91=0.135

Conclusion:

The approximation value for δ*δ is 0.5.

The approximation value for θδ is 0.167.

The blasius solution for δ*δ is 0.35.

The blasius solution for θδ is 0.135.

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Answer 5

Textbook Question

Answer 6

Textbook Question

Answer 7

Expert Solution & Answer

To determine

The comparison between different ratio when approximation method and blasius methods are used simultaneously.

Answer to Problem 97P

The approximation value for δ*δ is 0.5.

The approximation value for θδ is 0.167.

The blasius solution for δ*δ is 0.35.

The blasius solution for θδ is 0.135.

Explanation of Solution

Given information:

Write the expression for velocity profile if y<δ.

u=Uyδ ...... (I)

Here, boundary layer thickness is δ, velocity function is u, maximum velocity of the laminar flow over the flat plate is U.

Write the expression for velocity profile if y>δ.

u=U ...... (II)

Here, maximum velocity of the laminar flow over the flat plate is U.

Write the expression for displacement thickness.

δ*=∫0δ(1− u y<δ U)dy+∫δ∞(1− u y>δU)dy ...... (III)

Write the expression for momentum thickness.

θ=∫0δu y<δU(1− u y<δ U)dy+∫δ∞uy>δU(1− u y>δU)dy ...... (IV)

Write the expression for Blasius solution for boundary layer thickness.

δ=4.91x Rex ...... (V)

Here, any location on flat plate is x, Reynolds number is Rex.

Write the expression for Blasius solution for displacement thickness.

δ*=1.72x Rex ...... (VI)

Write the expression for Blasius solution for momentum thickness.

θ=0.664x Rex ...... (VII)

Write the expression for the ratio of displacement thickness to boundary layer thickness.

R=δ*δ ...... (VIII)

Write the expression for momentum thickness to boundary layer thickness.

S=θδ ...... (IX)

Calculation:

Substitute Uyδ for uy<δ, and U for uy>δ in Equation (III).

δ*=∫0δ( 1− ( Uy δ ) U )dy+∫δ∞(1− U U)dy=∫0δ(1−yδ)dy+∫δ∞(0)dy=[y−y22δ]0δ=δ−δ22δ

δ*=δ2

The displacement thickness δ* is δ2.

Substitute Uyδ for uy<δ, and U for uy>δ in Equation (IV).

θ=∫0δ Uy δ U( 1− Uy δ U )dy+∫δ∞UU(1− U U)dy=∫0δyδ(1−yδ)dy+∫δ∞UU(0)dy=∫0δyδ(1−yδ)dy+0

θ=[ y 2 2δ− y 3 3 δ 2 ]0δ=( δ 2 2δ− δ 3 3 δ 2 )−0=δ2−δ3=δ6

The momentum thickness θ is δ6.

Substitute δ2 for δ* in Equation (VIII).

R=( δ 2 )δ=δ2δ=120.5

Ratio of displacement thickness to boundary layer thickness is 0.5.

Substitute δ6 for θ in Equation (IX).

S=( δ 6 )δ=δ6δ=16=0.167

Ratio of displacement thickness to boundary layer thickness is 0.167.

Divide Equation (VI) with Equation (V) when blasius solution is considered.

δ*δ=( 1.72x Re x )( 4.91x Re x )=1.724.91=0.35

Divide Equation (VII) with Equation (V) when blasius solution is considered.

θδ=( 0.664x Re x )( 4.91x Re x )=0.6644.91=0.135

Conclusion:

The approximation value for δ*δ is 0.5.

The approximation value for θδ is 0.167.

The blasius solution for δ*δ is 0.35.

The blasius solution for θδ is 0.135.

Answer 8

Expert Solution & Answer

To determine

The comparison between different ratio when approximation method and blasius methods are used simultaneously.

Answer to Problem 97P

The approximation value for δ*δ is 0.5.

The approximation value for θδ is 0.167.

The blasius solution for δ*δ is 0.35.

The blasius solution for θδ is 0.135.

Explanation of Solution

Given information:

Write the expression for velocity profile if y<δ.

u=Uyδ ...... (I)

Here, boundary layer thickness is δ, velocity function is u, maximum velocity of the laminar flow over the flat plate is U.

Write the expression for velocity profile if y>δ.

u=U ...... (II)

Here, maximum velocity of the laminar flow over the flat plate is U.

Write the expression for displacement thickness.

δ*=∫0δ(1− u y<δ U)dy+∫δ∞(1− u y>δU)dy ...... (III)

Write the expression for momentum thickness.

θ=∫0δu y<δU(1− u y<δ U)dy+∫δ∞uy>δU(1− u y>δU)dy ...... (IV)

Write the expression for Blasius solution for boundary layer thickness.

δ=4.91x Rex ...... (V)

Here, any location on flat plate is x, Reynolds number is Rex.

Write the expression for Blasius solution for displacement thickness.

δ*=1.72x Rex ...... (VI)

Write the expression for Blasius solution for momentum thickness.

θ=0.664x Rex ...... (VII)

Write the expression for the ratio of displacement thickness to boundary layer thickness.

R=δ*δ ...... (VIII)

Write the expression for momentum thickness to boundary layer thickness.

S=θδ ...... (IX)

Calculation:

Substitute Uyδ for uy<δ, and U for uy>δ in Equation (III).

δ*=∫0δ( 1− ( Uy δ ) U )dy+∫δ∞(1− U U)dy=∫0δ(1−yδ)dy+∫δ∞(0)dy=[y−y22δ]0δ=δ−δ22δ

δ*=δ2

The displacement thickness δ* is δ2.

Substitute Uyδ for uy<δ, and U for uy>δ in Equation (IV).

θ=∫0δ Uy δ U( 1− Uy δ U )dy+∫δ∞UU(1− U U)dy=∫0δyδ(1−yδ)dy+∫δ∞UU(0)dy=∫0δyδ(1−yδ)dy+0

θ=[ y 2 2δ− y 3 3 δ 2 ]0δ=( δ 2 2δ− δ 3 3 δ 2 )−0=δ2−δ3=δ6

The momentum thickness θ is δ6.

Substitute δ2 for δ* in Equation (VIII).

R=( δ 2 )δ=δ2δ=120.5

Ratio of displacement thickness to boundary layer thickness is 0.5.

Substitute δ6 for θ in Equation (IX).

S=( δ 6 )δ=δ6δ=16=0.167

Ratio of displacement thickness to boundary layer thickness is 0.167.

Divide Equation (VI) with Equation (V) when blasius solution is considered.

δ*δ=( 1.72x Re x )( 4.91x Re x )=1.724.91=0.35

Divide Equation (VII) with Equation (V) when blasius solution is considered.

θδ=( 0.664x Re x )( 4.91x Re x )=0.6644.91=0.135

Conclusion:

The approximation value for δ*δ is 0.5.

The approximation value for θδ is 0.167.

The blasius solution for δ*δ is 0.35.

The blasius solution for θδ is 0.135.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

To determine

The comparison between different ratio when approximation method and blasius methods are used simultaneously.

Answer 12

Answer to Problem 97P

The approximation value for δ*δ is 0.5.

The approximation value for θδ is 0.167.

The blasius solution for δ*δ is 0.35.

The blasius solution for θδ is 0.135.

Answer 13

Explanation of Solution

Given information:

Write the expression for velocity profile if y<δ.

u=Uyδ ...... (I)

Here, boundary layer thickness is δ, velocity function is u, maximum velocity of the laminar flow over the flat plate is U.

Write the expression for velocity profile if y>δ.

u=U ...... (II)

Here, maximum velocity of the laminar flow over the flat plate is U.

Write the expression for displacement thickness.

δ*=∫0δ(1− u y<δ U)dy+∫δ∞(1− u y>δU)dy ...... (III)

Write the expression for momentum thickness.

θ=∫0δu y<δU(1− u y<δ U)dy+∫δ∞uy>δU(1− u y>δU)dy ...... (IV)

Write the expression for Blasius solution for boundary layer thickness.

δ=4.91x Rex ...... (V)

Here, any location on flat plate is x, Reynolds number is Rex.

Write the expression for Blasius solution for displacement thickness.

δ*=1.72x Rex ...... (VI)

Write the expression for Blasius solution for momentum thickness.

θ=0.664x Rex ...... (VII)

Write the expression for the ratio of displacement thickness to boundary layer thickness.

R=δ*δ ...... (VIII)

Write the expression for momentum thickness to boundary layer thickness.

S=θδ ...... (IX)

Calculation:

Substitute Uyδ for uy<δ, and U for uy>δ in Equation (III).

δ*=∫0δ( 1− ( Uy δ ) U )dy+∫δ∞(1− U U)dy=∫0δ(1−yδ)dy+∫δ∞(0)dy=[y−y22δ]0δ=δ−δ22δ

δ*=δ2

The displacement thickness δ* is δ2.

Substitute Uyδ for uy<δ, and U for uy>δ in Equation (IV).

θ=∫0δ Uy δ U( 1− Uy δ U )dy+∫δ∞UU(1− U U)dy=∫0δyδ(1−yδ)dy+∫δ∞UU(0)dy=∫0δyδ(1−yδ)dy+0

θ=[ y 2 2δ− y 3 3 δ 2 ]0δ=( δ 2 2δ− δ 3 3 δ 2 )−0=δ2−δ3=δ6

The momentum thickness θ is δ6.

Substitute δ2 for δ* in Equation (VIII).

R=( δ 2 )δ=δ2δ=120.5

Ratio of displacement thickness to boundary layer thickness is 0.5.

Substitute δ6 for θ in Equation (IX).

S=( δ 6 )δ=δ6δ=16=0.167

Ratio of displacement thickness to boundary layer thickness is 0.167.

Divide Equation (VI) with Equation (V) when blasius solution is considered.

δ*δ=( 1.72x Re x )( 4.91x Re x )=1.724.91=0.35

Divide Equation (VII) with Equation (V) when blasius solution is considered.

θδ=( 0.664x Re x )( 4.91x Re x )=0.6644.91=0.135

Conclusion:

The approximation value for δ*δ is 0.5.

The approximation value for θδ is 0.167.

The blasius solution for δ*δ is 0.35.

The blasius solution for θδ is 0.135.

Answer 14

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