Consider a vortex filament of strength Γ in the shape of a closed circular loop of radius R. Obtain an expression for the velocity induced at the center of the loop in terms of Γ and R.

Question

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Answer 1

Textbook Question

Chapter 5, Problem 5.1P

Consider a vortex filament of strength Γ in the shape of a closed circular loop of radius R. Obtain an expression for the velocity induced at the center of the loop in terms of Γ and R.

Expert Solution & Answer

To determine

An expression for the velocity induced at the center of the loop.

Answer to Problem 5.1P

V→= Γ2R k^ .

Explanation of Solution

Using Biot savrat law;

dV→ = Γ4πdl→×r→|r→|3

Now,

Velocity induced at the center;

V→= ∫ Γ 4π d l → × r → | r → | 3 ⇒V→= ∫02πRΓ 4π ( dl×R ) |R| 3 k^⇒V→=Γ4π1R2∫02πRdl⇒V→= Γ4π×1R2×2πR k^V→= Γ2R k^

Therefore, the obtained expression is V→= Γ2R k^ .

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Answer 2

Textbook Question

Chapter 5, Problem 5.1P

Consider a vortex filament of strength Γ in the shape of a closed circular loop of radius R. Obtain an expression for the velocity induced at the center of the loop in terms of Γ and R.

Expert Solution & Answer

To determine

An expression for the velocity induced at the center of the loop.

Answer to Problem 5.1P

V→= Γ2R k^ .

Explanation of Solution

Using Biot savrat law;

dV→ = Γ4πdl→×r→|r→|3

Now,

Velocity induced at the center;

V→= ∫ Γ 4π d l → × r → | r → | 3 ⇒V→= ∫02πRΓ 4π ( dl×R ) |R| 3 k^⇒V→=Γ4π1R2∫02πRdl⇒V→= Γ4π×1R2×2πR k^V→= Γ2R k^

Therefore, the obtained expression is V→= Γ2R k^ .

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Answer 3

Textbook Question

Chapter 5, Problem 5.1P

Consider a vortex filament of strength Γ in the shape of a closed circular loop of radius R. Obtain an expression for the velocity induced at the center of the loop in terms of Γ and R.

Expert Solution & Answer

To determine

An expression for the velocity induced at the center of the loop.

Answer to Problem 5.1P

V→= Γ2R k^ .

Explanation of Solution

Using Biot savrat law;

dV→ = Γ4πdl→×r→|r→|3

Now,

Velocity induced at the center;

V→= ∫ Γ 4π d l → × r → | r → | 3 ⇒V→= ∫02πRΓ 4π ( dl×R ) |R| 3 k^⇒V→=Γ4π1R2∫02πRdl⇒V→= Γ4π×1R2×2πR k^V→= Γ2R k^

Therefore, the obtained expression is V→= Γ2R k^ .

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Answer 4

Textbook Question

Chapter 5, Problem 5.1P

Consider a vortex filament of strength Γ in the shape of a closed circular loop of radius R. Obtain an expression for the velocity induced at the center of the loop in terms of Γ and R.

Expert Solution & Answer

To determine

An expression for the velocity induced at the center of the loop.

Answer to Problem 5.1P

V→= Γ2R k^ .

Explanation of Solution

Using Biot savrat law;

dV→ = Γ4πdl→×r→|r→|3

Now,

Velocity induced at the center;

V→= ∫ Γ 4π d l → × r → | r → | 3 ⇒V→= ∫02πRΓ 4π ( dl×R ) |R| 3 k^⇒V→=Γ4π1R2∫02πRdl⇒V→= Γ4π×1R2×2πR k^V→= Γ2R k^

Therefore, the obtained expression is V→= Γ2R k^ .

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Answer 5

Textbook Question

Answer 6

Textbook Question

Answer 7

Expert Solution & Answer

To determine

An expression for the velocity induced at the center of the loop.

Answer to Problem 5.1P

V→= Γ2R k^ .

Explanation of Solution

Using Biot savrat law;

dV→ = Γ4πdl→×r→|r→|3

Now,

Velocity induced at the center;

V→= ∫ Γ 4π d l → × r → | r → | 3 ⇒V→= ∫02πRΓ 4π ( dl×R ) |R| 3 k^⇒V→=Γ4π1R2∫02πRdl⇒V→= Γ4π×1R2×2πR k^V→= Γ2R k^

Therefore, the obtained expression is V→= Γ2R k^ .

Answer 8

Expert Solution & Answer

To determine

An expression for the velocity induced at the center of the loop.

Answer to Problem 5.1P

V→= Γ2R k^ .

Explanation of Solution

Using Biot savrat law;

dV→ = Γ4πdl→×r→|r→|3

Now,

Velocity induced at the center;

V→= ∫ Γ 4π d l → × r → | r → | 3 ⇒V→= ∫02πRΓ 4π ( dl×R ) |R| 3 k^⇒V→=Γ4π1R2∫02πRdl⇒V→= Γ4π×1R2×2πR k^V→= Γ2R k^

Therefore, the obtained expression is V→= Γ2R k^ .

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

To determine

An expression for the velocity induced at the center of the loop.

Answer 12

Answer to Problem 5.1P

V→= Γ2R k^ .

Answer 13

Explanation of Solution

Using Biot savrat law;

dV→ = Γ4πdl→×r→|r→|3

Now,

Velocity induced at the center;

V→= ∫ Γ 4π d l → × r → | r → | 3 ⇒V→= ∫02πRΓ 4π ( dl×R ) |R| 3 k^⇒V→=Γ4π1R2∫02πRdl⇒V→= Γ4π×1R2×2πR k^V→= Γ2R k^

Therefore, the obtained expression is V→= Γ2R k^ .

Answer 14

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Consider a vortex filament of strength Γ in the shape of a closed circular loop of radius R. Obtain an expression for the velocity induced at the center of the loop in terms of Γ and R.

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Answer to Problem 5.1P

Explanation of Solution

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