Find minimum value of `l` so that truck can avoid the dead end, without toppling the block kept on it.

A block of mass M= 4 kg of height and breath b is placed on a rough plank of same mass M . A light inextensible string is connected to the upper end of the block and passed through a light smooth pulley as shown in figure. A mass m =1 kg is hung to the other end of the string. a. What should be the minimum value of coefficient of friction between the block and the plank so that, there is no slipping between the block and the wedge? b. Find the minimum value of b//h so that the block does not topple over the plank, friction is absent between the plank and the ground.

A block of mass m is dropped onto a spring of constant k from a height h . The second end of the spring is attached to a second block of mass M as shown in figure. Find the minimum value of h so that the block M bounces off the ground. If the block of mass m sticks to the spring immediately after it comes into contact with it.

Find the maximum speed at which a truck can safely travel without toppling over, on a curve of radius 250m . The height of the centre of gravity of the truck above the ground is 1.5m and the distance between the wheels is 1.5m , the truck being horizontal.

A uniform box of height 2 m and having a square base of side 1 m , weight 150 kg , is kept on one end on the floor of a truck. The maximum speed with which the truck can round a curve of radius 20 m without causing the block to tip over is (assume that friction is sufficient is no sliding).

Two blocks A and B are lying on the table as shown in the figure. The coefficient of friciton between block A and block B is mu . The coefficient of friction between block B and ground also mu . An external force F is applied in the direction shown. The maximum value of the force F that can be applied without moving the blocks.

A rectangulat block of refractive index mu is placed on a printed page lying on a horizontal surface as shown in Fig. , Find the minimum value of mu so that the letter L on the page is not visible from any of the vertical sides.

There block A B ,and C of equal mass m are placed one over the other on a frictionless surface (table) as shown in figure The coefficient of friction between any blocks A ,B and C is mu The maximum value of mass of block D so that the blocks A,B and C move without slipping over each other is

Two block A of 6 kg and B of 4 kg are placed in contact with each other as shown in figure There is no friction A and ground and between both the blocks .The coefficient of friction between B and ground is 0.5 A horizontal force F is applied on A find the minimum and maximum value of F which can be applied so that both blocks can move combinely without any relative between them.

Figure shows a block P of mass m resting on a smooth floor at a distance l from a rigid wall. Block is pushed towards right by a distance 3l/2 and released. When block passes from its mean position another block of mass m_(1) is dropped over it, find the minimum value of m_(1) so that the combined block just collides with the left wall.

A block A of mass M kept on a rough horizontal surface is connected to a dielectric slab of mass M//6 and dielectric constant k by means of a light and inextensible string passing over a fixed pulley as shown in the figure. The dielectric can completely fill the space between the parallel plate capacitor of plate area l xx l and separation between the plates d kept in vertical position. Initially switch S is open and length of the dielectric inside the capacitor is b . The coefficient of friction between the block A and the surface is mu=1//4 . Igonore any other friction. (Given (Mgd)/(epsilon_(0)l(k-1))=24 .) Find the minimum value of the emf = V of the battery so that after closing the switch the block A will move.