[" The arle of a pulley of mass "1kg" is attached to the ne of an ellstic strine "],[" messectional area 10"m^(2)" and Young's modulus "2times10^(5)Nm^(-2)" ,whastic strine ere "],[" ciling.A rope of negligible mass is placed on the pulley such that its left the "],[" strund and its right end is hanging freely,from the pulley which is at rest in "],[" the free end "A" of the rope is subjected.Goullum "],[" the rope and the pulley can be neglected.(Gpulyull) "],[],[]

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

A string of negligible mass passes over a pulley of mass m which is clamped. It supports a block of mass M at its lower free end. What is force exerted on pulley by the support ?

A light rope is passed over a pulley such that at its one end a block is attached , and on the other end a boy is climbing up with acceleration g/2 relative to rope. Mass of the block is 30 kg and that of the boy is 40 kg. Find the tension and acceleration of the rope .

A light rope is passed over a pulley such that at its one end a block is attached , and on the other end a boy is climbing up with acceleration g/2 relative to rope. Mass of the block is 30 kg and that of the boy is 40 kg. Find the tension and acceleration of the rope .

On a pulley of mass M hangs a rope with two masses m_(1) and m_(2) (m_(1) gt m_(2) ) tied at the ends as shown in the figure. The pulley rotates without any friction, whereas the friction between the rope and the pulley is large enough to prevent any slipping. Which of the following plots best represents the difference between the tensions in the rope on the two sides of the pulley as a function of the mass of the pulley ?

A pulley-rope-mass arrangement is shown in fig. Find the acceleration of block m_(1) when the masses are set free to move. Assume that the pulley and the ropes are ideal.