355264 A boy throws a ball with speed \(u\) in a well of depth 14 \(m\) as shown. On bounce with bottom of the well the speed of the ball gets halved. What should be the minimum value of \(u\) such that the ball may be able to reach his hand again? Assume that his hands are at 1 \(m\) height from top of the well while throwing and catching.

355265 Assertion :
There is no loss in energy in elastic collision.
Reason :
Linear momentum is conserved in elastic collision

355266 For shown situation, if collision between block \({A}\) and \({B}\) is perfectly elastic, then find the maximum energy stored in spring is.

355267 The friction coefficient between the horizontal surface and blocks \({A}\) and \({B}\) are \({\dfrac{1}{15}}\) and \({\dfrac{2}{15}}\) respectively. The collision between the blocks is perfectly elastic. Find the separation between the two blocks when they come to rest.

355268 Six steel balls of identical size are lined up along a straight frictionless groove. Two similar balls moving with a speed \(v\) along the groove collide with this row on the extreme left hand then-

355264 A boy throws a ball with speed \(u\) in a well of depth 14 \(m\) as shown. On bounce with bottom of the well the speed of the ball gets halved. What should be the minimum value of \(u\) such that the ball may be able to reach his hand again? Assume that his hands are at 1 \(m\) height from top of the well while throwing and catching.

355265 Assertion :
There is no loss in energy in elastic collision.
Reason :
Linear momentum is conserved in elastic collision

355266 For shown situation, if collision between block \({A}\) and \({B}\) is perfectly elastic, then find the maximum energy stored in spring is.

355267 The friction coefficient between the horizontal surface and blocks \({A}\) and \({B}\) are \({\dfrac{1}{15}}\) and \({\dfrac{2}{15}}\) respectively. The collision between the blocks is perfectly elastic. Find the separation between the two blocks when they come to rest.

355268 Six steel balls of identical size are lined up along a straight frictionless groove. Two similar balls moving with a speed \(v\) along the groove collide with this row on the extreme left hand then-

355264 A boy throws a ball with speed \(u\) in a well of depth 14 \(m\) as shown. On bounce with bottom of the well the speed of the ball gets halved. What should be the minimum value of \(u\) such that the ball may be able to reach his hand again? Assume that his hands are at 1 \(m\) height from top of the well while throwing and catching.

355265 Assertion :
There is no loss in energy in elastic collision.
Reason :
Linear momentum is conserved in elastic collision

355266 For shown situation, if collision between block \({A}\) and \({B}\) is perfectly elastic, then find the maximum energy stored in spring is.

355267 The friction coefficient between the horizontal surface and blocks \({A}\) and \({B}\) are \({\dfrac{1}{15}}\) and \({\dfrac{2}{15}}\) respectively. The collision between the blocks is perfectly elastic. Find the separation between the two blocks when they come to rest.

355268 Six steel balls of identical size are lined up along a straight frictionless groove. Two similar balls moving with a speed \(v\) along the groove collide with this row on the extreme left hand then-

355264 A boy throws a ball with speed \(u\) in a well of depth 14 \(m\) as shown. On bounce with bottom of the well the speed of the ball gets halved. What should be the minimum value of \(u\) such that the ball may be able to reach his hand again? Assume that his hands are at 1 \(m\) height from top of the well while throwing and catching.

355265 Assertion :
There is no loss in energy in elastic collision.
Reason :
Linear momentum is conserved in elastic collision

355266 For shown situation, if collision between block \({A}\) and \({B}\) is perfectly elastic, then find the maximum energy stored in spring is.

355267 The friction coefficient between the horizontal surface and blocks \({A}\) and \({B}\) are \({\dfrac{1}{15}}\) and \({\dfrac{2}{15}}\) respectively. The collision between the blocks is perfectly elastic. Find the separation between the two blocks when they come to rest.

355268 Six steel balls of identical size are lined up along a straight frictionless groove. Two similar balls moving with a speed \(v\) along the groove collide with this row on the extreme left hand then-

355264 A boy throws a ball with speed \(u\) in a well of depth 14 \(m\) as shown. On bounce with bottom of the well the speed of the ball gets halved. What should be the minimum value of \(u\) such that the ball may be able to reach his hand again? Assume that his hands are at 1 \(m\) height from top of the well while throwing and catching.

355265 Assertion :
There is no loss in energy in elastic collision.
Reason :
Linear momentum is conserved in elastic collision

355266 For shown situation, if collision between block \({A}\) and \({B}\) is perfectly elastic, then find the maximum energy stored in spring is.

355267 The friction coefficient between the horizontal surface and blocks \({A}\) and \({B}\) are \({\dfrac{1}{15}}\) and \({\dfrac{2}{15}}\) respectively. The collision between the blocks is perfectly elastic. Find the separation between the two blocks when they come to rest.

355268 Six steel balls of identical size are lined up along a straight frictionless groove. Two similar balls moving with a speed \(v\) along the groove collide with this row on the extreme left hand then-