In the figure shown, mass `2m` connected with a spring of force constant `k` is at rest and in equilibrium. A partical of mass `m` is released from height `4.5 mg//k` from `2m` . The partical stick to the block. Neglecting the duration of collision find time from the release of `m` to the moment when the spring has maximum compression.

In the figure shown, mass 2m connected with a spring of force constant k is at rest and in equilibrium. A particle of mass m is released from height 4.5 mg//k from 2m . The particle stick to the block. Neglecting the duration of collision find time from the release of m to the moment when the spring has maximum compression.

In the figure shown mass 2m is at rest and in equilibrium. A particle of mass m is released from height (4.5mg)/(k) from plate. The particle sticks to the plate. Neglecting the duration of collision. Starting from the when the particles sticks to plate to the time when the spring is in maximum compression for the first time is 2pisqrt((m)/(ak)) then find a .

In the figure shown mass 2m is at rest and in equilibrium. A particle of mass m is released from height (4.5mg)/(k) from palte. The particle sticks to the plate. Neglecting the duration of collision. Starting form the when the particles sticks to plate to the time when the spring is in maximum compression for the first time is 2pisqrt((m)/(ak)) then find a .

The block shown in figure is released from rest. Find out the speed of the block when the spring is compressed by 1 m

A block of mass m length force a verical of spring constant k If the block is polled down by a distance of 2mg//k from its equilibrium position and released for the subsequent in the spring to maximum compressed in it mg//k

A slab of mass 'm' is released from a height x to the top a spring of force constant k. The maximum compression of the spring is y. Then

A block of mass m is released from a height h from the top of a smooth surface. There is an ideal spring of spring constant k at the bottom of the track. Find the maximum compression in the spring (Wedge is fixed)

A block of mass m is released from a height h from the top of a smooth surface. There is an ideal spring of spring constant k at the bottom of the track. Find the maximum compression in the spring (Wedge is fixed)

A partical of mass m is driven by a machine that deleveres a constant power k watts. If the partical starts from rest the force on the partical at time t is

A partical of mass m is driven by a machine that deleveres a constant power k watts. If the partical starts from rest the force on the partical at time t is