Consider Example 8, taking the coefficient of friction, `mu`, to be 0.5 and calculate the maximm compression of the spring.

A block of mass m is attached to one end of a mass less spring of spring constant k. the other end of spring is fixed to a wall the block can move on a horizontal rough surface. The coefficient of friction between the block and the surface is mu then the compession of the spring for which maximum extension of the spring becomes half of maximum compression is .

Two blocks each having mass m is attached to each other with a spring having force constant k. The system is placed on a rough horizontal surface having coefficient of friction mu . The maximum initial compression, that can be given to the spring so that when released the blocks do not move is

Free end of an ideal spring of spring constant 100 N/m is at a distance 1 m from a vertical block of mass 2 kg moving on rough surface with initial speed 8 m/s as shown in figure. If coefficient of friction is 0.7, then maximum compression in spring is (g = 10 ms^-2)

The arrangement shown in figure is at rest. An ideal spring of natural length l_0 having spring constant k=220Nm^-1 , is connected to block A. Blocks A and B are connected by an ideal string passing through a friction less pulley. The mass of each block A and B is equal to m=2kg when the spring was in natural length, the whole system is given an acceleration veca as shown. If coefficient of friction of both surfaces is mu=0.25 , then find the maximum extension in 10(m) of the spring. (g=10ms^-2) .

The coefficient of friction between two surface is 0.2. The maximum angle of friction is

A force of 10N is acting on a block of 20kg on horizontal surface with coefficient of friction mu=0.2 . Calculate the work done by the force.

Consider the figure shown here of a moving cart C. if the coefficient of friction between the block A and the cart is mu , then calculate the minimum acceleration a of the cart C so that the block A does not fall.

. In the figure shown, AB = BC = 2m . Friction coefficient everywhere is mu=0.2. Find the maximum compression of the spring.

A car is taking turn on a circular path of radius R. If the coefficient of friction between the tyres and road is mu , the maximum velocity for no slipping is

Blocks A and B in the Fig are connected by a bar of negligible weight .Mass of each block is 170 kg and mu_(A) = 0.2 and mu_(B) = 0.4 where mu_(A) and mu_(B) are the coefficient of limiting friction between bloock and plane calculate the force developed in the bar (g = 10 ms^(-2))