Mechanics of Materials, SI Edition
Mechanics of Materials, SI Edition
9th Edition
ISBN: 9781337093354
Author: Barry J. Goodno, James M. Gere
Publisher: Cengage Learning
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Textbook Question
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Chapter 7, Problem 7.7.31P

Solve Problem 7.7-13 by using Mohr’s circle for plane strain.

Expert Solution & Answer
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To determine

The principle strains and maximum shear strain.

Answer to Problem 7.7.31P

The maximum principle strain is 568.47 × 10 6 .

The minimum principle strain is 18.47 × 10 6 .

The maximum shear strain is 586.94 × 10 6 .

The minimum shear strain is 586.94 × 10 6 .

Explanation of Solution

Given information:

The normal strain along x-axis is 480 × 10 6 , normal strain along y-axis is 70 × 10 6 ,and shear strain along xy-plane is 420 × 10 6 and orientation of element is 75 ° .

Explanation:

The following are the steps to draw the Mohr’s circle

  1. Draw the x-axis as normal strain and y-axis as shear strain and indicate the origin as point O ( 0 , 0 ) .
  2. Write the expression to locate the center point C of the circle from the origin O(ie., OC).
  3. OC = ε a v g = ε x + ε y 2 ……(I)

    Here, the normal strain along x-axis is ε x , normal strain along y-axis is ε y , and average strain is ε a v g .

  4. Mark the center point O: ( ε a v g , 0 ) .
  5. Write the expression for the radius of Mohr’s circle
  6. R = ( ε x ε a v g ) 2 + ( γ x y 2 ) 2 .....(II)

Here, the radius of the Mohr’s circle is R and shear strain along xy-plane is γ x y .

Write the expression for principle angle.

   α = tan 1 ( γ x y 2 ε x ε a v g ) .....(III)

Here, principle plane angle is α .

Write the expression for angle of oriented strain plane.

   β = α + 180 ° 2 θ .....(IV)

Here, angle of oriented strain plane is β and θ is the orientation of element.

Write the expression for the strain at point D.

   ( ε x ) 1 = ε a v g R cos β .....(V)

Here, the strain at point D is ( ε x ) 1

Write the expression for the strain at point D .

   ( ε x ) 2 = ε a v g + R cos β ...... (VI)

Here, the strain at point D is ( ε x ) 2 .

Write the expression for the shear strain at point D.

   ( γ x y ) 1 2 = R sin β ...... (VII)

Here, the shear strain at point D ( γ x y ) 1

Write the expression for the shear strain at point D

   ( γ x y ) 2 2 = R sin β ...... (VIII)

Here, the shear strain at point D

   ( γ x y ) 2 .

Write the expression for the maximum principle strain.

   ε 1 = ε a v g + R ...... (IX)

Here, the maximum principle strain is ε 1 .

Write the expression for the minimum principle strain.

   ε 2 = ε a v g R ...... (X)

Here, the minimum principle strain is ε 2 .

Write the expression for maximum shear strain.

   γ max = 2 R ...... (XI)

Here, maximum shear strain is. γ max .

Write the expression for minimum shear strain.

   γ min = 2 R ...... (XII)

Here, minimum shear strain is. γ min .

Write the expression for the maximum principle strain plane angle.

   2 θ p 1 = 180 ° α ...... (XIII)

Here, maximum shear strain plane angle is θ p 1 .

Write the expression for the minimum principle strain plane angle.

   2 θ p 2 = 180 ° + 2 θ p 1 ...... (XIV)

Here, minimum shear strain plane angle is θ p 2 .

Write the expression for maximum shear strain plane angle.

   2 θ s 1 = 90 ° α ...... (XV)

Here, maximum shear strain plane angle is θ s 1 .

Write the expression for minimum shear strain plane angle.

   2 θ s 2 = 90 ° + 2 θ s 1 ...... (XVI)

Here, minimum shear strain plane angle is θ s 2 .

Calculation:

Substitute 480 × 10 6 for ε x , and 70 × 10 6 for ε y in Equation (I).

   ε a v g = ( 480 × 10 6 ) + ( 70 × 10 6 ) 2 = 550 × 10 6 2 = 275 × 10 6

Substitute 480 × 10 6 for ε x , 275 × 10 6 for ε a v g and 420 × 10 6 for γ x y in Equation (II).

   R = ( 480 × 10 6 275 × 10 6 ) 2 + ( 420 × 10 6 2 ) 2 = ( 205 × 10 6 ) 2 + ( 210 × 10 6 ) 2 = 293.47 × 10 6

Substitute 480 × 10 6 for ε x , 275 × 10 6 for ε a v g and 420 × 10 6 for γ x y in Equation (III).

   α = tan 1 ( 420 × 10 6 2 ) 480 × 10 6 275 × 10 6 = tan 1 1.04 = 45.69 °

Substitute 45.69 ° for α and 75 ° for θ in Equation (IV).

   β = 45.69 ° + 180 ° 2 ( 75 ° ) = 225.69 ° 150 ° = 75.69 °

Substitute 275 × 10 6 for ε a v g , 293.47 × 10 6 for R and 75.69 ° for β in Equation (V).

   ( ε x ) 1 = 275 × 10 6 ( 293.47 × 10 6 cos 75.69 ° ) = 275 × 10 6 72.54 × 10 6 = 202.46 × 10 6

Substitute 275 × 10 6 for ε a v g , 293.47 × 10 6 for R and 75.69 ° for β in Equation (VI).

   ( ε x ) 2 = 275 × 10 6 + ( 293.47 × 10 6 cos 75.69 ° ) = 275 × 10 6 + 72.54 × 10 6 = 347.54 × 10 6

Substitute 293.47 × 10 6 for R and 75.69 ° for β in Equation (VII).

   ( γ x y ) 1 2 = ( 293.47 × 10 6 sin 75.69 ° ) ( γ x y ) 1 = ( 2 × 28436 × 10 6 ) = 568.72 × 10 6

Substitute 293.47 × 10 6 for R and 75.69 ° for β in Equation (VIII).

   ( γ x y ) 2 2 = ( 293.47 × 10 6 sin 75.69 ° ) ( γ x y ) 2 = ( 2 × 28436 × 10 6 ) = 568.72 × 10 6

Substitute 275 × 10 6 for ε a v g and 293.47 × 10 6 for R in Equation (IX).

   ε 1 = 275 × 10 6 + 293.47 × 10 6 = 568.47 × 10 6

Substitute 275 × 10 6 for ε a v g and 293.47 × 10 6 for R in Equation (X).

   ε 2 = 275 × 10 6 293.47 × 10 6 = 18.47 × 10 6

Substitute 293.47 × 10 6 for R in Equation (VI).

   γ max = 2 ( 293.47 × 10 6 ) = 586.94 × 10 6

Substitute 337.08 × 10 6 for R in Equation (VII).

   γ min = 2 ( 293.47 × 10 6 ) = 586.94 × 10 6

Substitute 45.69 ° for α in Equation (VIII).

   2 θ p 1 = 180 ° ( 45.69 ° ) θ p 1 = 134.31 ° 2 = 67.15 °

Substitute 67.15 ° for θ p 1 in Equation (IX)

   2 θ p 2 = 180 ° + 67.15 ° θ p 2 = 247.15 ° 2 = 123.57 °

Substitute 45.69 ° for α in Equation (X).

   2 θ s 1 = 90 ° 45.69 ° θ s 1 = 44.31 ° 2 = 22.15 °

Substitute 22.15 ° for θ s 1 in Equation (XI).

   2 θ s 1 = 90 ° + 22.15 ° θ s 1 = 112.15 ° 2 = 56.07 °

The following figure shows the Mohr ‘circle.

  Mechanics of Materials, SI Edition, Chapter 7, Problem 7.7.31P , additional homework tip  1

     Figure-(1)

The following figure shows the strain on oriented plane.

  Mechanics of Materials, SI Edition, Chapter 7, Problem 7.7.31P , additional homework tip  2

     Figure-(2)

Conclusion:

The maximum principle strain is 568.47 × 10 6 .

The minimum principle strain is 18.47 × 10 6 .

The maximum shear strain is 586.94 × 10 6 .

The minimum shear strain is 586.94 × 10 6 .

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Chapter 7 Solutions

Mechanics of Materials, SI Edition

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