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 displaceement of the strained face, modulus of rigidity for rubber is `2.4xx10^(6)N//m^(2)`

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 rubber cord of a catapult has cross-section area 1 mm^(2) and a total unstretched length 10 cm. It is stretched to 12 cm and then released to project a partical of mass 5 g. Calculate the velocity of projection (Y for rubber is 5xx10^(8)N//m^(2) )

A square lead slab of side 50 cm and thickness 10 cm is subject to a shearing force on its narrow face) of 9.0 xx 10 ^(4) N. The lower edge is riveted to the floor. How much will the upper edge be displaced ? Shear modulus of lead G=5.8 xx 10 ^(9) N//m^(2)

A metallic rod of length 1m has one end free and other end rigidly clamped. Longitudinal stationary waves are set up in the rod in such a way that there are total six antinodes present along the rod. The amplitude of an antinode is 4 xx 10^(-6) m . young's modulus and density of the rod are 6.4 xx 10^(10) N//m^(2) and 4 xx 10^(3) Kg//m^(3) respectively. Consider the free end to be at origin and at t=0 particles at free end are at positive extreme. The magnitude of strain at midpoint of the rod at t = 1 sec is

A metallic rod of length 1m has one end free and other end rigidly clamped. Longitudinal stationary waves are set up in the rod in such a way that there are total six antinodes present along the rod. The amplitude of an antinode is 4 xx 10^(-6) m . young's modulus and density of the rod are 6.4 xx 10^(10) N//m^(2) and 4 xx 10^(3) Kg//m^(3) respectively. Consider the free end to be at origin and at t=0 particles at free end are at positive extreme. The equation describing displacements of particles about their mean positions is.

A metallic rod of length 1m has one end free and other end rigidly clamped. Longitudinal stationary waves are set up in the rod in such a way that there are total six antinodes present along the rod. The amplitude of an antinode is 4 xx 10^(-6) m . young's modulus and density of the rod are 6.4 xx 10^(10) N//m^(2) and 4 xx 10^(3) Kg//m^(3) respectively. Consider the free end to be at origin and at t=0 particles at free end are at positive extreme. The equation describing stress developed in the rod is

A square Nickel slab of side 50 cm and thickness 10 cm is subject to a shearing force (on its narrow face) of 9.0 xx 10 ^(4) N. The lower edge is riveted to the floor. How much will the upper edge be displaced ? Shear modulus of Nickel G=77 xx 10 ^(9) Nm^(-2)

A square lead slab of side 40 cm and thickness 10 cm is subject to a shearing force (on its narrow face) of 9.0 xx 10 ^(4) N. The lower edge is riveted to the floor. How much will the upper edge be displaced ? Shear modulus of lead G=5.6 xx 10 ^(9) N//m ^(2)

The edge of an aluminium cube is 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. The shear modulus of aluminium is 25 Gpa. What is the vertical deflection of this face ?

The edge of an aluminium cube is 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. The shear modulus of aluminium is 25 GPa. What is the vertical deflection of this face ?