Figure shows a three blocks are connected by strings. Its free body diagrams and find forces of interaction

Figure shows two blocks connected by a light inextensible string as shown in figure. A force of 10 N is applied on the bigger block at 60^(@) with horizontal, then the tension in the st ring connection the two masses is -

A two block system is shown in figure . We shall draw complete free body diagram and find normal reaction between m_(1) and m_(2) and between m_(2) and ground .

Draw the free body diagram of following also find the tension in each string

A car is moving with constant speed on a rough banked road. Figure shows the free body diagram of car in three situation A, B & C respectively:

Figure shows three blocks of mass m each hanging on a string passing over a pulley. Calculate the tension in the string connecting A to B and B to C?

A block of mass 1 kg is plase on a rough incilined plane at angle theta = 45^(@) will horizontal . The block is connected with a straigh as straight as shown in figure if mu = 3//4 find the tension in string

Three blocks of masses m, 3m and 5m are connected by massless strings and pulled by a force F on a frictionless surface as shown in the figure below. The tension P in the first string is 16N. If the point of application of F is changed as given below. The values of P' and Q' shall be

Blocks A, B and C are placed as shown in Fig and connected by the rops of negligible mass . Both A and B weigh 25.0 N each , and the coefficient of kinetic friction between each and the surface is 0.35 blocks C descends with constant velocity . a. Draw two separate free- body diagrams showing the forces acting on A and B b. Find the tension in the rope connecting blocks A and B c. What is the weight of blocks C? d. If the rope connecting A and B were cut, what would be the acceleration of C?

The tension in the string connected between blocks is

Two blocks A and B are connected by a massless string (shown in figure) A force of 30 N is applied on block B. The distance travelled by centre of mass in 2s starting from rest is :