A spring is compressed between two toy carts of masses `m_1` and `m_2` When the toy carts are released, then spring exerts equal and opposite average force for the same time on both the toy carts. If there is no friction between the toy carts and the ground, then the velocity of toy carts are

A spring is compressed between two toy carts of masses m_(1) and m_(2) . When the toy carts are released then spring exerts equal and opposite average force on each for the same time t. Assume that there is no friction between the toy carts and the ground, the velocities of toy carts are

A spring is compressed between two toy carts of mass m_(1) and m_(2) . When the toy carts are released, the springs exert equal and opposite average forces for the same time on each toy cart. If v_(1) and v_(2) are the velocities of the toy carts and there is no friction between the toy carts and the ground, then :

A spring is compressed between two toy carts to masses m_1 and m_2 . When the toy carts are released, the spring exerts on each toy cart equal and opposite forces for the same small time t. If the coefficients of friction mu between the ground and the toy carts are equal, then the magnitude of displacements of the toy carts are in the ratio

A spring is compressed by a toy cart of mass 150g. On releasing the cart, it moves with a speed of 0.2 m//s . Calculate the elastic potential energy of the spring.

A boy of mass 50 kg jumps with horizontal velocity of 1 m/s on to a stationary cart. If mass of the cart will be [Assume friction between the wheels the cart and road is zero ]

A vessel with a hole in its bottom is fastened on a cart. The mass of the vessel and the cart is M and the area of the vessel base is A . What force F should the cart be puuled with so that maximum amount of water remains in the vessel ? The dimensions of the vessel are shown in the figure . Assume where is no friction between cart and ground and vessel is fixed with cart . ( rho is density of water )

The block of mass m is in contact with a moving cart as shown in the figure.The coefficient of friction between the block and the cart is . The acceleration a of the cart that will prevent the block from falling is

In the figure shown a cart moves on a smooth horizontal surface due to an external constant force of magnitude F . The initial mass of the cart is M_(0) and velocity is zero. Sand falls on to the cart with negligible velocity at constant rate mu kg//s and sticks to the cart. The velocity of the cart at time t is :

Momentum is the ability of imparting or tending to motion to other bodies. The total momentum of a system remains conserved if no external force is acting it. This is calculated by the formula, vecp=mvecv . Consider a situation where a cart carrying five boys is moving without friction due to inertia along a straight horizontal road, with a speed of 10m//s . After travelling certain distance, a boy jumps from the cart with a speed of 2m//s with respect to the cart in opposite direction to it. Then, second boy jumps with the same speed w.r.t. the cart, but in a perpendicular direction to the cart. The mass of the cart is 100 kg and mass of each boy is 20 kg. If, in the first case, the second boy jumps out of the cart in a direction perpendicular to the motion of cart as seen from ground, then the speed of

A man of mass m is standing on the flat top of a cart of mass 2m . The length and height of the cart is L and H respectively and it is at rest on a smooth horizontal ground. The man starts running from end A, speeds up and jumps out of the cart at point B with a velocity u relative to the cart in horizontal direction. Calculate the total horizontal distance covered by the man by the time he lands on the ground.