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Monday, March 14, 2016

STRENGTH OF MATERIAL -2 (UNIT-1)
Energy Methods
Strain Energy
Strain Energy of the member is defined as the internal work done in defoming the body by the action of externally applied forces. This energy in elastic bodies is known as elastic strain energy :
Strain Energy in uniaxial Loading
Fig .1
Let as consider an infinitesimal element of dimensions as shown in Fig .1. Let the element be subjected to normal stress sx.
The forces acting on the face of this element is sx. dy. dz
where
dydz = Area of the element due to the application of forces, the element deforms to an amount = Îx dx
  Îx = strain in the material in x – direction
       
Assuming the element material to be as linearly elastic the stress is directly proportional to strain as shown in Fig . 2.
Fig .2
From Fig .2 the force that acts on the element increases linearly from zero until it attains its full value.
Hence average force on the element is equal to ½ sx . dy. dz.
\ Therefore the workdone by the above force
Force = average force x deformed length
           = ½ sx. dydz . Îx . dx
For a perfectly elastic body the above work done is the internal strain energy “du”.
where dv = dxdydz
   = Volume of the element
By rearranging the above equation we can write
The equation (4) represents the strain energy in elastic body per unit volume of the material its strain energy – density ‘uo' .
From Hook's Law for elastic bodies, it may be recalled that
In the case of a rod of uniform cross – section subjected at its ends an equal and opposite forces of magnitude P as shown in the Fig .3.
Fig .3
Modulus of resilience :
Fig .4
Suppose ‘ sx‘ in strain energy equation is put equal to sy i.e. the stress at proportional limit or yield point. The resulting strain energy gives an index of the materials ability to store or absorb energy without permanent deformation
So 
The quantity resulting from the above equation is called the Modulus of resilience
The modulus of resilience is equal to the area under the straight line portion ‘OY' of the stress – strain diagram as shown in Fig .4 and represents the energy per unit volume that the material can absorb without yielding. Hence this is used to differentiate materials for applications where energy must be absorbed by members.
Modulus of Toughness :
Fig .5
Suppose ‘Î' [strain] in strain energy expression is replaced by ÎR strain at rupture, the resulting strain energy density is called modulus of toughness
From the stress – strain diagram, the area under the complete curve gives the measure of modules of toughness. It is the materials.
Ability to absorb energy upto fracture. It is clear that the toughness of a material is related to its ductility as well as to its ultimate strength and that the capacity of a structure to withstand an impact Load depends upon the toughness of the material used.
ILLUSTRATIVE PROBLEMS
  1. Three round bars having the same length ‘L' but different shapes are shown in fig below. The first bar has a diameter ‘d' over its entire length, the second had this diameter over one – fourth of its length, and the third has this diameter over one eighth of its length. All three bars are subjected to the same load P. Compare the amounts of strain energy stored in the bars, assuming the linear elastic behavior.
Solution :
From the above results it may be observed that the strain energy decreases as the volume of the bar increases.
  1. Suppose a rod AB must acquire an elastic strain energy of 13.6 N.m using E = 200 GPa. Determine the required yield strength of steel. If the factor of safety w.r.t. permanent deformation is equal to 5.
Solution :
Factor of safety = 5
Therefore, the strain energy of the rod should be u = 5 [13.6] = 68 N.m
Strain Energy density
The volume of the rod is
Yield Strength :
As we know that the modulus of resilience is equal to the strain energy density when maximum stress is equal to sx .
It is important to note that, since energy loads are not linearly related to the stress they produce, factor of safety associated with energy loads should be applied to the energy loads and not to the stresses.
Strain Energy in Bending :
Fig .6
Consider a beam AB subjected to a given loading as shown in figure.
Let
M = The value of bending Moment at a distance x from end A.
From the simple bending theory, the normal stress due to bending alone is expressed as.
ILLUSTRATIVE PROBLEMS
  1. Determine the strain energy of a prismatic cantilever beam as shown in the figure by taking into account only the effect of the normal stresses.
Solution : The bending moment at a distance x from end
A is defined as
Substituting the above value of M in the expression of strain energy we may write
Problem 2 :
  1. Determine the expression for strain energy of the prismatic beam AB for the loading as shown in figure below. Take into account only the effect of normal stresses due to bending.
  2. Evaluate the strain energy for the following values of the beam
P = 208 KN ; L = 3.6 m = 3600 mm
A = 0.9 m = 90mm ; b = 2.7m = 2700 mm
E = 200 GPa ; I = 104 x 108 mm4
Solution:
a.
Bending Moment : Using the free – body diagram of the entire beam, we may determine the values of reactions as follows:
RA = Pb/ L RB = Pa / L
For Portion AD of the beam, the bending moment is
For Portion DB, the bending moment at a distance v from end B is
Strain Energy :
Since strain energy is a scalar quantity, we may add the strain energy of portion AD to that of DB to obtain the total strain energy of the beam.
b. Substituting the values of P, a, b, E, I, and L in the expression above.
Problem
3) Determine the modulus of resilience for each of the following materials.
a. Stainless steel .             E = 190 GPa    sy = 260MPa
b. Malleable constantan   E = 165GPa     sy = 230MPa
c. Titanium                          E = 115GPa     sy = 830MPa
d. Magnesium                    E = 45GPa      sy = 200MPa
4) For the given Loading arrangement on the rod ABC determine
(a). The strain energy of the steel rod ABC when
P = 40 KN.
(b). The corresponding strain energy density in portions AB and BC of the rod.