In the case of plane stress, where the in-plane principal strains are given by ε 1 and ε 2 , show that the third principal strain can be obtained from ε 3 = − v ( ε + ε 2 ) ( 1 − v ) where v is Poisson’s ratio for the material.

Question

Want to see more full solutions like this?

Answer 1

Textbook Question

Chapter 10, Problem 10.94RP

In the case of plane stress, where the in-plane principal strains are given by ε₁ and ε₂, show that the third principal strain can be obtained from

ε 3 = − v ( ε + ε 2 ) ( 1 − v )

where v is Poisson’s ratio for the material.

Expert Solution & Answer

To determine

To show that: The third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν).

Answer to Problem 10.94RP

The third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν)_ is proved.

Explanation of Solution

Given information:

The third principal strain ε3=−ν(ε1+ε2)(1−ν)

Explanation:

For the case of plane stress σ3=0.

Apply the normal strain in x direction as shown below.

ε1=1E(σ1−ν(σ2+σ3))

Here, E is the modulus of elasticity, σ1 is the normal stress in x direction, ν is the Poisson’s ratio, σ2 is the normal stress in y direction, and σ3 is the normal stress in z direction.

Substitute 0 for σ3.

ε1=1E(σ1−ν(σ2+0))=1E(σ1−νσ2)Eε1=σ1−νσ2

Multiply both sides of the Equation by ν.

νEε1=(σ1−νσ2)ν=νσ1−ν2σ2 (1)

Apply the normal strain in y direction as shown below.

ε2=1E(σ2−ν(σ1+σ3))

Substitute 0 for σ3.

ε2=1E(σ2−ν(σ1+0))=1E(σ2−νσ1)Eε2=σ2−νσ1 (2)

Apply the normal strain in z direction as shown below.

ε3=1E(σ3−ν(σ1+σ2))

Substitute 0 for σ3.

ε3=1E(0−ν(σ1+σ2))=1E(−ν(σ1+σ2)) (3)

Adding Equation (1) and (2).

νEε1+Eε2=(νσ1−ν2σ2)+(σ2−νσ1)=νσ1−ν2σ2+σ2−νσ1=σ2(1−ν2)E(νε1+ε2)=σ2(1−ν2)

σ2=E(1−ν2)(νε1+ε2)

Substitute E(1−ν2)(νε1+ε2) for σ2 in Equation (2).

Eε2=E(1−ν2)(νε1+ε2)−νσ1νσ1=E(1−ν2)(νε1+ε2)−Eε2

σ1=1ν(E(νε1+ε2)−(1−ν2)Eε2(1−ν2))=Eν(1−ν2)(νε1+ε2−ε2+ν2ε2)=Eν(1−ν2)(νε1+ν2ε2)=E(1−ν2)(ε1+νε2)

Substitute E(1−ν2)(νε1+ε2) for σ2 and E(1−ν2)(ε1+νε2) for σ1 in Equation (3).

ε3=1E(−ν(E(1−ν2)(ε1+νε2)+E(1−ν2)(νε1+ε2)))=−νEE(1−ν2)(ε1+νε2+νε1+ε2)=−ν(1−ν)(1+ν)((1+ν)ε1+(1+ν)ε2)=−ν(1+ν)(1−ν)(1+ν)(ε1+ε2)

ε3=−ν(1−ν)(ε1+ε2)

Therefore, the third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν)_ is proved.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Students have asked these similar questions

If the normal strain is defined in reference to the final length Δs′, that is,P= = lim Δs′S 0 aΔs′ - Δs Δs′ b instead of in reference to the original length, Eq. 2–2, show that the difference in these strains is represented as a second-order term, namely, P - P= = P P′.

Indicate the points on the stress-strain diagram which represent the proportional limit and the ultimate stress.

Determine the average normal strain that occurs along the diagonals AC and DB.

Answer 2

Textbook Question

Chapter 10, Problem 10.94RP

In the case of plane stress, where the in-plane principal strains are given by ε₁ and ε₂, show that the third principal strain can be obtained from

ε 3 = − v ( ε + ε 2 ) ( 1 − v )

where v is Poisson’s ratio for the material.

Expert Solution & Answer

To determine

To show that: The third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν).

Answer to Problem 10.94RP

The third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν)_ is proved.

Explanation of Solution

Given information:

The third principal strain ε3=−ν(ε1+ε2)(1−ν)

Explanation:

For the case of plane stress σ3=0.

Apply the normal strain in x direction as shown below.

ε1=1E(σ1−ν(σ2+σ3))

Here, E is the modulus of elasticity, σ1 is the normal stress in x direction, ν is the Poisson’s ratio, σ2 is the normal stress in y direction, and σ3 is the normal stress in z direction.

Substitute 0 for σ3.

ε1=1E(σ1−ν(σ2+0))=1E(σ1−νσ2)Eε1=σ1−νσ2

Multiply both sides of the Equation by ν.

νEε1=(σ1−νσ2)ν=νσ1−ν2σ2 (1)

Apply the normal strain in y direction as shown below.

ε2=1E(σ2−ν(σ1+σ3))

Substitute 0 for σ3.

ε2=1E(σ2−ν(σ1+0))=1E(σ2−νσ1)Eε2=σ2−νσ1 (2)

Apply the normal strain in z direction as shown below.

ε3=1E(σ3−ν(σ1+σ2))

Substitute 0 for σ3.

ε3=1E(0−ν(σ1+σ2))=1E(−ν(σ1+σ2)) (3)

Adding Equation (1) and (2).

νEε1+Eε2=(νσ1−ν2σ2)+(σ2−νσ1)=νσ1−ν2σ2+σ2−νσ1=σ2(1−ν2)E(νε1+ε2)=σ2(1−ν2)

σ2=E(1−ν2)(νε1+ε2)

Substitute E(1−ν2)(νε1+ε2) for σ2 in Equation (2).

Eε2=E(1−ν2)(νε1+ε2)−νσ1νσ1=E(1−ν2)(νε1+ε2)−Eε2

σ1=1ν(E(νε1+ε2)−(1−ν2)Eε2(1−ν2))=Eν(1−ν2)(νε1+ε2−ε2+ν2ε2)=Eν(1−ν2)(νε1+ν2ε2)=E(1−ν2)(ε1+νε2)

Substitute E(1−ν2)(νε1+ε2) for σ2 and E(1−ν2)(ε1+νε2) for σ1 in Equation (3).

ε3=1E(−ν(E(1−ν2)(ε1+νε2)+E(1−ν2)(νε1+ε2)))=−νEE(1−ν2)(ε1+νε2+νε1+ε2)=−ν(1−ν)(1+ν)((1+ν)ε1+(1+ν)ε2)=−ν(1+ν)(1−ν)(1+ν)(ε1+ε2)

ε3=−ν(1−ν)(ε1+ε2)

Therefore, the third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν)_ is proved.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 3

Textbook Question

Chapter 10, Problem 10.94RP

In the case of plane stress, where the in-plane principal strains are given by ε₁ and ε₂, show that the third principal strain can be obtained from

ε 3 = − v ( ε + ε 2 ) ( 1 − v )

where v is Poisson’s ratio for the material.

Expert Solution & Answer

To determine

To show that: The third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν).

Answer to Problem 10.94RP

The third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν)_ is proved.

Explanation of Solution

Given information:

The third principal strain ε3=−ν(ε1+ε2)(1−ν)

Explanation:

For the case of plane stress σ3=0.

Apply the normal strain in x direction as shown below.

ε1=1E(σ1−ν(σ2+σ3))

Here, E is the modulus of elasticity, σ1 is the normal stress in x direction, ν is the Poisson’s ratio, σ2 is the normal stress in y direction, and σ3 is the normal stress in z direction.

Substitute 0 for σ3.

ε1=1E(σ1−ν(σ2+0))=1E(σ1−νσ2)Eε1=σ1−νσ2

Multiply both sides of the Equation by ν.

νEε1=(σ1−νσ2)ν=νσ1−ν2σ2 (1)

Apply the normal strain in y direction as shown below.

ε2=1E(σ2−ν(σ1+σ3))

Substitute 0 for σ3.

ε2=1E(σ2−ν(σ1+0))=1E(σ2−νσ1)Eε2=σ2−νσ1 (2)

Apply the normal strain in z direction as shown below.

ε3=1E(σ3−ν(σ1+σ2))

Substitute 0 for σ3.

ε3=1E(0−ν(σ1+σ2))=1E(−ν(σ1+σ2)) (3)

Adding Equation (1) and (2).

νEε1+Eε2=(νσ1−ν2σ2)+(σ2−νσ1)=νσ1−ν2σ2+σ2−νσ1=σ2(1−ν2)E(νε1+ε2)=σ2(1−ν2)

σ2=E(1−ν2)(νε1+ε2)

Substitute E(1−ν2)(νε1+ε2) for σ2 in Equation (2).

Eε2=E(1−ν2)(νε1+ε2)−νσ1νσ1=E(1−ν2)(νε1+ε2)−Eε2

σ1=1ν(E(νε1+ε2)−(1−ν2)Eε2(1−ν2))=Eν(1−ν2)(νε1+ε2−ε2+ν2ε2)=Eν(1−ν2)(νε1+ν2ε2)=E(1−ν2)(ε1+νε2)

Substitute E(1−ν2)(νε1+ε2) for σ2 and E(1−ν2)(ε1+νε2) for σ1 in Equation (3).

ε3=1E(−ν(E(1−ν2)(ε1+νε2)+E(1−ν2)(νε1+ε2)))=−νEE(1−ν2)(ε1+νε2+νε1+ε2)=−ν(1−ν)(1+ν)((1+ν)ε1+(1+ν)ε2)=−ν(1+ν)(1−ν)(1+ν)(ε1+ε2)

ε3=−ν(1−ν)(ε1+ε2)

Therefore, the third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν)_ is proved.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 4

Textbook Question

Chapter 10, Problem 10.94RP

In the case of plane stress, where the in-plane principal strains are given by ε₁ and ε₂, show that the third principal strain can be obtained from

ε 3 = − v ( ε + ε 2 ) ( 1 − v )

where v is Poisson’s ratio for the material.

Expert Solution & Answer

To determine

To show that: The third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν).

Answer to Problem 10.94RP

The third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν)_ is proved.

Explanation of Solution

Given information:

The third principal strain ε3=−ν(ε1+ε2)(1−ν)

Explanation:

For the case of plane stress σ3=0.

Apply the normal strain in x direction as shown below.

ε1=1E(σ1−ν(σ2+σ3))

Here, E is the modulus of elasticity, σ1 is the normal stress in x direction, ν is the Poisson’s ratio, σ2 is the normal stress in y direction, and σ3 is the normal stress in z direction.

Substitute 0 for σ3.

ε1=1E(σ1−ν(σ2+0))=1E(σ1−νσ2)Eε1=σ1−νσ2

Multiply both sides of the Equation by ν.

νEε1=(σ1−νσ2)ν=νσ1−ν2σ2 (1)

Apply the normal strain in y direction as shown below.

ε2=1E(σ2−ν(σ1+σ3))

Substitute 0 for σ3.

ε2=1E(σ2−ν(σ1+0))=1E(σ2−νσ1)Eε2=σ2−νσ1 (2)

Apply the normal strain in z direction as shown below.

ε3=1E(σ3−ν(σ1+σ2))

Substitute 0 for σ3.

ε3=1E(0−ν(σ1+σ2))=1E(−ν(σ1+σ2)) (3)

Adding Equation (1) and (2).

νEε1+Eε2=(νσ1−ν2σ2)+(σ2−νσ1)=νσ1−ν2σ2+σ2−νσ1=σ2(1−ν2)E(νε1+ε2)=σ2(1−ν2)

σ2=E(1−ν2)(νε1+ε2)

Substitute E(1−ν2)(νε1+ε2) for σ2 in Equation (2).

Eε2=E(1−ν2)(νε1+ε2)−νσ1νσ1=E(1−ν2)(νε1+ε2)−Eε2

σ1=1ν(E(νε1+ε2)−(1−ν2)Eε2(1−ν2))=Eν(1−ν2)(νε1+ε2−ε2+ν2ε2)=Eν(1−ν2)(νε1+ν2ε2)=E(1−ν2)(ε1+νε2)

Substitute E(1−ν2)(νε1+ε2) for σ2 and E(1−ν2)(ε1+νε2) for σ1 in Equation (3).

ε3=1E(−ν(E(1−ν2)(ε1+νε2)+E(1−ν2)(νε1+ε2)))=−νEE(1−ν2)(ε1+νε2+νε1+ε2)=−ν(1−ν)(1+ν)((1+ν)ε1+(1+ν)ε2)=−ν(1+ν)(1−ν)(1+ν)(ε1+ε2)

ε3=−ν(1−ν)(ε1+ε2)

Therefore, the third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν)_ is proved.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!

Answer 5

Textbook Question

Answer 6

Textbook Question

Answer 7

Expert Solution & Answer

To determine

To show that: The third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν).

Answer to Problem 10.94RP

The third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν)_ is proved.

Explanation of Solution

Given information:

The third principal strain ε3=−ν(ε1+ε2)(1−ν)

Explanation:

For the case of plane stress σ3=0.

Apply the normal strain in x direction as shown below.

ε1=1E(σ1−ν(σ2+σ3))

Here, E is the modulus of elasticity, σ1 is the normal stress in x direction, ν is the Poisson’s ratio, σ2 is the normal stress in y direction, and σ3 is the normal stress in z direction.

Substitute 0 for σ3.

ε1=1E(σ1−ν(σ2+0))=1E(σ1−νσ2)Eε1=σ1−νσ2

Multiply both sides of the Equation by ν.

νEε1=(σ1−νσ2)ν=νσ1−ν2σ2 (1)

Apply the normal strain in y direction as shown below.

ε2=1E(σ2−ν(σ1+σ3))

Substitute 0 for σ3.

ε2=1E(σ2−ν(σ1+0))=1E(σ2−νσ1)Eε2=σ2−νσ1 (2)

Apply the normal strain in z direction as shown below.

ε3=1E(σ3−ν(σ1+σ2))

Substitute 0 for σ3.

ε3=1E(0−ν(σ1+σ2))=1E(−ν(σ1+σ2)) (3)

Adding Equation (1) and (2).

νEε1+Eε2=(νσ1−ν2σ2)+(σ2−νσ1)=νσ1−ν2σ2+σ2−νσ1=σ2(1−ν2)E(νε1+ε2)=σ2(1−ν2)

σ2=E(1−ν2)(νε1+ε2)

Substitute E(1−ν2)(νε1+ε2) for σ2 in Equation (2).

Eε2=E(1−ν2)(νε1+ε2)−νσ1νσ1=E(1−ν2)(νε1+ε2)−Eε2

σ1=1ν(E(νε1+ε2)−(1−ν2)Eε2(1−ν2))=Eν(1−ν2)(νε1+ε2−ε2+ν2ε2)=Eν(1−ν2)(νε1+ν2ε2)=E(1−ν2)(ε1+νε2)

Substitute E(1−ν2)(νε1+ε2) for σ2 and E(1−ν2)(ε1+νε2) for σ1 in Equation (3).

ε3=1E(−ν(E(1−ν2)(ε1+νε2)+E(1−ν2)(νε1+ε2)))=−νEE(1−ν2)(ε1+νε2+νε1+ε2)=−ν(1−ν)(1+ν)((1+ν)ε1+(1+ν)ε2)=−ν(1+ν)(1−ν)(1+ν)(ε1+ε2)

ε3=−ν(1−ν)(ε1+ε2)

Therefore, the third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν)_ is proved.

Answer 8

Expert Solution & Answer

To determine

To show that: The third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν).

Answer to Problem 10.94RP

The third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν)_ is proved.

Explanation of Solution

Given information:

The third principal strain ε3=−ν(ε1+ε2)(1−ν)

Explanation:

For the case of plane stress σ3=0.

Apply the normal strain in x direction as shown below.

ε1=1E(σ1−ν(σ2+σ3))

Here, E is the modulus of elasticity, σ1 is the normal stress in x direction, ν is the Poisson’s ratio, σ2 is the normal stress in y direction, and σ3 is the normal stress in z direction.

Substitute 0 for σ3.

ε1=1E(σ1−ν(σ2+0))=1E(σ1−νσ2)Eε1=σ1−νσ2

Multiply both sides of the Equation by ν.

νEε1=(σ1−νσ2)ν=νσ1−ν2σ2 (1)

Apply the normal strain in y direction as shown below.

ε2=1E(σ2−ν(σ1+σ3))

Substitute 0 for σ3.

ε2=1E(σ2−ν(σ1+0))=1E(σ2−νσ1)Eε2=σ2−νσ1 (2)

Apply the normal strain in z direction as shown below.

ε3=1E(σ3−ν(σ1+σ2))

Substitute 0 for σ3.

ε3=1E(0−ν(σ1+σ2))=1E(−ν(σ1+σ2)) (3)

Adding Equation (1) and (2).

νEε1+Eε2=(νσ1−ν2σ2)+(σ2−νσ1)=νσ1−ν2σ2+σ2−νσ1=σ2(1−ν2)E(νε1+ε2)=σ2(1−ν2)

σ2=E(1−ν2)(νε1+ε2)

Substitute E(1−ν2)(νε1+ε2) for σ2 in Equation (2).

Eε2=E(1−ν2)(νε1+ε2)−νσ1νσ1=E(1−ν2)(νε1+ε2)−Eε2

σ1=1ν(E(νε1+ε2)−(1−ν2)Eε2(1−ν2))=Eν(1−ν2)(νε1+ε2−ε2+ν2ε2)=Eν(1−ν2)(νε1+ν2ε2)=E(1−ν2)(ε1+νε2)

Substitute E(1−ν2)(νε1+ε2) for σ2 and E(1−ν2)(ε1+νε2) for σ1 in Equation (3).

ε3=1E(−ν(E(1−ν2)(ε1+νε2)+E(1−ν2)(νε1+ε2)))=−νEE(1−ν2)(ε1+νε2+νε1+ε2)=−ν(1−ν)(1+ν)((1+ν)ε1+(1+ν)ε2)=−ν(1+ν)(1−ν)(1+ν)(ε1+ε2)

ε3=−ν(1−ν)(ε1+ε2)

Therefore, the third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν)_ is proved.

Answer 9

Expert Solution & Answer

Answer 10

Expert Solution & Answer

Answer 11

To determine

To show that: The third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν).

Answer 12

Answer to Problem 10.94RP

The third principal strain can be obtained from ε3=−ν(ε1+ε2)(1−ν)_ is proved.

Answer 13

Explanation of Solution

Given information:

The third principal strain ε3=−ν(ε1+ε2)(1−ν)

Explanation:

For the case of plane stress σ3=0.

Apply the normal strain in x direction as shown below.

ε1=1E(σ1−ν(σ2+σ3))

Here, E is the modulus of elasticity, σ1 is the normal stress in x direction, ν is the Poisson’s ratio, σ2 is the normal stress in y direction, and σ3 is the normal stress in z direction.