There are two ideal springs of force constants `K_1` and `K_2` respectively. When both springs are relaxed the separation between free ends is L. Now the particle of mass m attached to free end of left spring is displaced by distance 2L towards left and then released. assuming the surface to be frictionless. `((K_(1))/(K_(2))=4/3)`. (Neglect size of the block)

The maximum compression produced in right spring will be

There are two ideal springs of force constants K_1 and K_2 respectively. When both springs are relaxed the separation between free ends is L. Now the particle of mass m attached to free end of left spring is displaced by distance 2L towards left and then released. assuming the surface to be frictionless. ((K_(1))/(K_(2))=4/3) . (Neglect size of the block) The time interval after which mass 'm' hits the right spring will be

There are two ideal springs of force constants K_1 and K_2 respectively. When both springs are relaxed the separation between free ends is L. Now the particle of mass m attached to free end of left spring is displaced by distance 2L towards left and then released. assuming the surface to be frictionless. ((K_(1))/(K_(2))=4/3) . (Neglect size of the block) Suppose mass m hits the right spring and sticks to it. The extension in left spring when mass ‘m’ is in equilibrium position during its motion is :

A mass M is suspended by two springs of force constants K_(1) and K_(2) respectively as shown in the diagram. The total elongation (stretch) of the two springs is

Two springs of spring constants K_(1) and K_(2) are joined in series. The effective spring constant of the combination is given by

Two springs have force constants k_(A) and k_(B) such that k_(B)=2k_(A) . The four ends of the springs are stretched by the same force. If energy stored in spring A is E , then energy stored in spring B is.

Two spring of spring constant k_(1) and k_(2) are joined in series The effective spring constant of the combination is given by

Two spring have force constants k_(1) and k_(2) respectively. They are attached to a mass m and two fixed supports as shwon in figure. If the surface is frictionless, fing the time period of oscillations. What is the spring factore of this combination.

A spring of force constant K rests on a smooth floor, with one end fixed to a wall. A block of mass m hits the free end of the spring with velocity v. The maximum force exerted by the spring on the wall is

Four massless springs whose force constants are 2k, 2k, k and 2k respectively are attached to a mass M kept on a frictionless plane (as shown in figure). If the mass M is displaced in the horizontal direction.