Consider an Indian rubber cube having modulus of rigidity of `2xx10^(7)` dyne `cm^(-2)` and of side 8 cm. If one side of the rubber is fixed, while a tangential force equal to the weight of 300 kg is applied to the opposite face, then find out the shearing strain produced and distance through which the strain side moves .

A rubber cube of side 5 cm has one side fixed while a tangential force equal to 1800 N is applied to opposite face. Find the shearing strain and the lateral displacement of the strained face. Modulus of rigidity for rubber is 2.4 xx 10^(6) N//m^(2) .

A tangential force equal to the weight of 500kg is applied to the opposite face of a cube of aluminium of side 10cm has its one face fixed. Find the shearing strain produced. Rigidity modulus of aluminium is 2.5 xx 10^(10 ) Nm^(-2)

A metallic cube of side 10 cm is subjected to a shearing force of 300 kgf. The top force is displaced through 0.25 cm with respect ot the bottom ? Calculate the shearing strain produced .

A cube of side 40 cm has its upper face displaced by 0.1 mm by a tangential force of 8 Kn. The shearing modulus of cube is :-

The edges of an aluminum cube are 10 cm long. One face of the cube is firmly fixed to a vertical wall. A mass of 100 kg is then attached to the opposite face of the cube. Shear modulus of aluminum is 25 xx 10^(9) Pa , the vertical deflection in the face to which mass is attached is

The edges of an aluminum cube are 10 cm long. One face of the cube is firmly fixed to a vertical wall. A mass of 100 kg is then attached to the opposite face of the cube. Shear modulus of aluminum is 25 xx 10^(9) Pa , the vertical deflection in the face to which mass is attached is

The Young's modulus of a rope of 10 m length and having diameter of 2 cm is 20xx10^(11) dyne cm^(-2) . If the elongation produced in the rope is 1 cm, the force applied on the rope is

A rectangular metallic bar one metre long, one cm deep and one cm broad is placed on a smooth table. The Young's modulus and modulus of rigidity of metal of the bar are 2 xx 10^(11) N//m^(2) and 8 xx 10^(10) N //m^(2) respectively. If the bar is rigidity clamped at one end is pulled at the other end with a force 5000 N applied normaly to its end cross-section, calculate the elongation of the bar and the work done in elongating the bar.

One of the square faces of a metal slab of side 50 cm and thickness 20 cm is rigidly fixed on a horizontal surface. If a tangential force of 30 N is applied to the top face and it is known that the shear modulus of the material is 4 xx 10^(10) N//m^(2) , then the displacement (in m) of the top face is

A rectangular metallic bar one metre long, one cm deep and one cm broad is placed on a smooth table. The Young's modulus and modulus of rigidity of metal of the bar are 2 xx 10^(11) N//m^(2) and 8 xx 10^(10) N //m^(2) respectively. If now the base of the bar is rigidly clamped to the table, how will you apply a force of 500N, to produce shearing strain in the bar? Calculate the angle of deformation and the horizontal displacement produced in the top layer of the bar.