If extension in the spring at equilibrium position is 6 cm then acceleration of block if it is released by further stretching 4 cm.

A block tied between two identical springs is in equilibrium. If upper spring is cut then the acceleration of the block just after cut is 6m//s^(2) downwards. Now, if instead of upper spring, lower spring is being cut then the acceleration of the block just after the cut will be.

A block tied between identical springs is in equilibrium. If upper spring is cut, then the acceleration of the block just after cut is 5 ms^(1) Now if instead of upper string lower spring is cut, then the acceleration of the block just after the cut will be (Take g=10 m//s^(2) ).

A block of mass m is suddenly released from the top of a spring of stiffness constant k. a. Find the acceleration of block just after release. b. What is the compression in the spring at equilibrium. c. What is the maximum compression in the spring. d. Find the acceleration of block at maximum compression in the spring.

Consider the situation shown in figure. Mass of block A is m and that of blcok B is 2m. The force constant of string is k. Friction is absent everywhere. System is released from rest with the spring unstretched. Find (a) The maximum extension of the spring x_(m) (b) The speed of block A when the extension in the springt is x=(x_(m))/(2) (c ) The net acceleration of block B when extension in the spring is x=(x_(m))/(4).

The block of mass m_1 shown in figure is fastened to the spring and the block of mass m_2 is placed asgainst ilt. A. Find the compression of the spring in the equilibrium position. b.The blocks are pushed a further distance (2/k)(m_1+m_2)gsintheta against the spring and released. Find the position where the two blocks separate.

A rectangular tank having base 15 cm xx 20 cm is filled with water (density rho = 1000 kg//m^(3)) up to 20 cm and force constant K = 280 N//m is fixed to the bottom of the tank so that the spring remains vertical. This system is in an elevator moving downwards with acceleration a = 2 m//s^(2) . A cubical block of side l = 10 cm and mass m = 2 kg is gently placed over the spring and released gradually, as shown in the figure. a. Calculate compression of the spring in equilibrium position. b. If the block is slightly pushed down from equilibrium position and released, calculate frequency of its vertical oscillations.

A block of mass m is released from rest onto a spring. A having stiffness k_A=mg//2h as shown in figure. If the block compresses spring B through a distance h, find the: a. stiffness of the spring B b. equilibrium position of the block c. maximum velocity of the block d. maximum acceleration of the block

A block of mass m is released from rest onto a spring. A having stiffness k_A=mg//2h as shown in figure. If the block compresses spring B through a distance h, find the: a. stiffness of the spring B b. equilibrium position of the block c. maximum velocity of the block d. maximum acceleration of the block

A spring has natural length 40 cm and spring constant 500 N//m . A block of mass 1 kg is attached at one end of the spring and other end of the spring is attached to a ceiling. The block is relesed from the position, where the spring has length 45 cm .

A block A of mass m is attached at one end of a light spring and the other end of the spring is connected to another block B of mass 2m through a light string as shown in the figure. A is held and B is in static equilibrium. Now A is released. The acceleration of A just after that instant is a . In the next case, B is held and A is in static equilibrium. Now when B is released, its acceleration immediately after the releas is b . The value of a//b is (pulley, string and the spring are massless).