A load of `10 kN` is supported from a pulley which in turn is supported by a rope of sectional area `1xx10^(3)mm^(2)` and modulus of elasticity `10^(3)Nmm^(-2)`, as shown in figure. Neglecting the friction at the pulley, determine the deflection of the load.

A load of 10 KN is supported from a pulley , which in turn is supported by a rope of cross-sectional area 10^(3) mm^(2) and modulus of elasticity 10^(3) Nmm^(-2) as shown in the figure. Neglecting friction at the pulley , then downward deflection of the load (in mm) is

A load of 10 KN is supported from a pulley , which in turn is supported by a rope of cross-sectional area 10^(3) mm^(2) and modulus of elasticity 10^(3) Nmm^(-2) as shown in the figure. Neglecting friction at the pulley , then downward deflection of the load (in mm) is

The axle of a pulley of mass 1 kg is attached to the end of an elastic string of length 1m , cross- sectional area 10^(-3) m^(2) and young's modulus 2xx10^(5) Nm^(-2) ,whose other end is fixed to the ceiling. A rope of negligible mass is placed on the pulley such that its left end is fixed to the ground and its right end is hanging freely , from the pulley which is at rest in equilibrium . Now, the rope and the pulley can be neglected. (Given, g = 10 ms^(-2) ) The elongation of the string before applying force is

The axle of a pulley of mass 1 kg is attached to the end of an elastic string of length 1m , cross- sectional area 10^(-3) m^(2) and young's modulus 2xx10^(5) Nm^(-2) ,whose other end is fixed to the ceiling. A rope of negligible mass is placed on the pulley such that its left end is fixed to the ground and its right end is hanging freely , from the pulley which is at rest in equilibrium . Now, the rope and the pulley can be neglected. (Given, g = 10 ms^(-2) ) The elongation of the string before applying force is

The axle of a pulley of mass 1 kg is attached to the end of an elastic string of length 1m , cross- sectional area 10^(-3) m^(2) and young's modulus 2xx10^(5) Nm^(-2) ,whose other end is fixed to the ceiling. A rope of negligible mass is placed on the pulley such that its left end is fixed to the ground and its right end is hanging freely , from the pulley which is at rest in equilibrium . Now, the rope and the pulley can be neglected. (Given, g = 10 ms^(-2) ) The elongation of the string before applying force is

The axle of a pulley of mass 1 kg is attached to the end of an elastic string of length 1m , cross- sectional area 10^(-3) m^(2) and young's modulus 2xx10^(5) Nm^(-2) ,whose other end is fixed to the ceiling. A rope of negligible mass is placed on the pulley such that its left end is fixed to the ground and its right end is hanging freely , from the pulley which is at rest in equilibrium . Now, the rope and the pulley can be neglected. (Given, g = 10 ms^(-2) ) The elongation of the string before applying force is

The figure shows two creates that are connected by a steel wire that passes over a pulley. The unstretched length of the wire is 1.5 m, and its cross - sectional area is 1.3xx10^(-5)m^(2) . The pulley is frictionless and massless. When the crates are accelerating, determine the change in length of the wire. Ignore the mass of the wire.

A load o f 1 kg weight is a attached to one end of a steel wire o f area of cross-section 3mm^(2) and Young's modulus 10^(11) N//m^(2) . The other end is suspended vertically from a hook on a wall , then the load is pulled horizontally and released .When the load passes through its lowest position the fraction al change in lenght is (Take g = 10m//s^(2))

A load of 1 kg weight is a attached to one end of a steel wire of area of cros-section 3 mm^(2) and Young's modulus 10^11 Nm^-2 . The other end is suspended vertically from a hook on a wall, then the load is pulled horizontally and released. When the load passes through its lowest position the fractional change in length is (10ms^-2)