Elastic Deformation of Materials

Question 1

How can we get from displacement to strain?

Answer 1

Differentiate

Question 2

How can we change strain for stress?

Answer 2

With Hooke’s law.

Question 3

If displacement is constant everywhere is there any strain?

Answer 3

No, the body has been translated.

Question 4

Define tensor shear strain.

Answer 4

Check

Question 5

Write out the general strain tensor.

Answer 5

Check

Question 6

Is the strain tensor symmetric?

Answer 6

Yes

Question 7

Is stress a tensor property of a material?

Answer 7

Yes

Question 8

Give an equation for stress using stress as a tensor.

Answer 8

F = ∑sigma A

Question 9

By resolving the turning moment on a small element cube, show that sigmaij=sigmaji.

Answer 9

Check

Question 10

Give an expression for hydrostatic stress in terms of normal stress.

Answer 10

Check

Question 11

Give an expression for hydrostatic pressure of a body in terms of normal stress.

Answer 11

Check (should be minus the hydrostatic stress).

Note, not the same as external pressure

Question 12

Relate stress and strain using the fact that the stress and strain tensors are symmetric.

Answer 12

Check, should get the compliance matrix.

Question 13

When working with the compliance matrix, are the shear strains simple or pure?

Answer 13

Simple, so must convert to pure for Mohr’s circle.

Question 14

State the Hooke’s law equations relating strain and stress by superposition of stress.

Answer 14

Check

Question 15

Derive the Hooke’s law relation between stress and sum of strains.

Answer 15

Check

Question 16

Give the Hooke’s law relation between stress and sum of strains.

Answer 16

Check

Question 17

In the Hooke’s law relation between stress and sum of strains, does epsilon mm have any physical meaning?

Answer 17

Yes, it is the fractional change in volume.

Question 18

Derive an expression for bulk modulus using Hooke’s law and hydrostatic pressure.

Answer 18

Check

Question 19

Show how for Hooke’s law relating shear stress and strain, Mohr’s circle can be used to turn it into a normal stress and strain problem.

Answer 19

Show.

Question 20

Derive the stress equilibrium equations.

Answer 20

Check

Question 21

Why do we need strain compatibility equations?

Answer 21

There are 6 components of strain at every point.
There are 3 components of displacement at every point.
The strain components then cannot be independent.

Question 22

Derive a strain compatibility equation.

Answer 22

Check

Question 23

What is the condition of displacement for the compatibility equations?

Answer 23

It must be single valued due to it being free of internal strain but an external force is applied.

Question 24

Is a dislocation a compatible dislocation?

Answer 24

No as the displacement field is not single valued.

Question 25

Derive the plane stress compatibility equation.

Answer 25

Check

Question 26

State the Airy stress function for an edge dislocation.

Answer 26

Check

Question 27

Define the Airy stress function in terms of plane stresses.

Answer 27

Check

Question 28

Is an edge dislocation a situation of plane stress or plane strain or both?

Answer 28

Plane strain only as by using Hooke’s law for stress in terms of strain, the sum of normal strain will always be non-zero so a stress will arise in every direction.

Question 29

State the Mohr’s circle equations.

Answer 29

Check

Question 30

For cylindrical polars, give the relation for normal strain between displacement and strain in the z direction.

Answer 30

Check

Question 31

For cylindrical polars, give the relation for normal strain between displacement and strain in the r direction.

Answer 31

Check

Question 32

For cylindrical polars, give the relation for circumferential strain and displacement in the r direction.

Answer 32

Check

Question 33

For cylindrical polars, give the relation for circumferential strain between displacement and strain in the theta direction.

Answer 33

Check

Question 34

Give expressions for shear strains in cylindrical polars.

Answer 34

Check

Question 35

Give the solution for displacement in cylindrically symmetric systems.

Answer 35

Check

Question 36

Solve the problem of a misfitting fibre in a rod generally finding the stresses in the fibre.

Answer 36

Check

Question 37

Give the expressions for the displacements in a spherically symmetric system of radial dilation.

Answer 37

Check

Question 38

Give the strains in a spherically symmetric system of radial dilation.

Answer 38

Check

Question 39

State the solution for a spherically symmetric system of radial dilation.

Answer 39

Check

Question 40

Solve the problem of a particle under pressure p generally finding the stresses and strain in the particle.

Answer 40

Check

Question 41

Derive an expression for the interaction energy of an elastically deformed particle.

Answer 41

Check (use the fact it has deformed elastically, don’t need to integrate).

Question 42

Calculate the strain energy density for the uniaxial deformation of a cube.

Answer 42

Check

Question 43

Show that in 6x6 matrix form the compliance matrices Cij=Ckl, thus the matrix is symmetric and only has 21 independent components.

Answer 43

Check

Question 44

Link stress and strain with the reduced compliance matrix.

Answer 44

Check

Question 45

Link stress and strain with the reduced stiffness matrix.

Answer 45

Check

Question 46

Since the reduced compliance matrix is symmetric, how can the Poisson’s ratios be related.

Answer 46

The component C12=C21

Question 47

Consider a thin wall pressure vessel radius r, wall thickness t and filled with gas pressure p. A small hole is made in the wall of the pressure vessel. What is the stress in the vicinity of the hole?

Answer 47

Find solution.

Question 48

Calculate the total energy for the uniaxial deformation of a cube.

Answer 48

Check

Question 49

Calculate the elastic strain energy stored in a sphere under pressure p.

Answer 49

Check

Question 50

Derive an expression for the elastic modulus when longitudinal loading of a fibre composite.

Answer 50

El = VfEf+VmEm

Question 51

Derive an expression for the elastic modulus when transverse loading of a fibre composite.

Answer 51

1/Et = Vf/Ef +Vm/Em

Question 52

When considering short fibre composites, what happens to the stress near the ends of the fibres?

Answer 52

It reduces.

Question 53

How do we account for the reduce in stress near the end of the fibres in short fibre composites in the expression for modulus?

Answer 53

With a reinforcement factor Ω

Question 54

What is the transfer length of a fibre in a composite?

Answer 54

The distance from the end of the fibre at which the stress increases to the long fibre value, epsilonEf.

Question 55

Give an equation for the transfer length in a short fibre composite.

Answer 55

Check

Question 56

Calculate the transfer length and longitudinal stiffness of an Al matrix containing 30% alumina fibres of 3µm diameter and 30µm length.

Answer 56

Check

Question 57

Go through an example of stress and strain when an anisotropic material is loaded off axis.

Answer 57

Do it!! On a previous question sheet.