Find acceleration of 5kg bock. All stirng and pulley are ideal. `(g=10ms^(-2))`

Consider the situation shown in figure .Both the pulleys and the string and light and all the surfaces are smooth. (a) Find the acceleration of 1kg block. (b) Find the tension in the string. (g = 10 m//s^(2)) .

The acceleration of block is( g=10 ms-2)

The system shown in the figure is in equilibrium and all the blocks are at rest. Assume that the masses of the strings, the pulley and the spring and negligible with respect to the masses of the blocks and friction is absent. Find the acceleration of block C, just after cutting the spring 1. [g=10ms^(-2)]

Wedge of 10 kg is free to move on horizontal surface. At the given instant, acceleration of wedge is (string and pulleys are ideal)

Three blocks A , B and C , whose masses are 9kg , 9kg and 18kg respectively as shown in the figure, are released from rest. The co-efficient of friction between block A and the horizontal surface is 0.5 & the co-efficient of friction between block B and the horizontal surface is 0.5 . Find the acceleration of block C just release [Take g=10m//s^(2) ]. All strings and pulleys are ideal

A boy whose mass is 50 kg stands on a spring balance inside a lift. The lift starts to ascent with an acceleration of 2ms^(-2) . The reading of the machine or balance (g=10ms^(-2)) is

Find the acceleration of the 6 kg block in the figure. All the surfaces and pulleys are smooth. Also the strings are inextensible and light. [Take g = 10 m//s^(2) ] .

If block B shown in figure-l.78(a) is going down with acceleration 5 m//s^(2) , find the acceleration of the block A. All pulleys and strings are ideal. Radii ratio for the two step pulleys are 1 : 3 : 5 and 1 :2 .

In the figure-2.205 shown in blocks A, B and C has masses m_(A)= 5 kg, m_(B) = 5 kg and m_(C )= 10kg respectively, find the acceleration of the three blocks. Assume all pulleys and strings are ideal. (Take g = 10m//s^(2) )

In given arrangement, 10 kg and 20 kg blocks are kept at rest on two fixed inclined planes. All strings and pulleys are ideal. Value (s) of m for which system remain in equilibrium are (g=10m//s^(2))