If system is in equilibrium then find relation between `m_(1)` and `m_(2)`

Consider the system of masses and pulleys shown in fig. with massless string and fricitionless pulleys. (a) Give the necessary relation between masses m_(1) and m_(2) such that system is in equilibrium and does not move. (b) If m_(1)=6kg and m_(2)=8kg , calculate the magnitude and direction of the acceleration of m_(1) .

A uniform L shaped rod of mass 3 m is hinged at point O. length OB is two times the length OA. It is in equilibrium. Find (a). Relation between alpha and beta (b). Net hinge force.

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 .

The system is in equilibrium and at rest. Now mass m_(1) is removed from m_(2) . Find the time period and amplituded of resultant motion. Spring constant is K .

The system shown in fig is in equilibrium . Masses m_(1) and m_(2) are 2kg and 8kg, Respectively. Spring constants k_(1) and k_(2) ro 50Nm^(-1) and 70Nm^(-1) , respectively. If the compression in second spring is 0.5m. What is the compression in first spring?

The system shown in fig is in equilibrium . Masses m_(1) and m_(2) are 2kg and 8kg, Respectively. Spring constants k_(1) and k_(2) ro 50Nm^(-1) and 70Nm^(-1) , respectively. If the compression in second spring is 0.5m. What is the compression in first spring?

When force F applied on m_(1) and there is no friction between m_(1) and surface and the coefficient of friction between m_(1)and m_(2) is mu. What should be the minimum value of F so that there is on relative motion between m_(1) and m_(2)

Find m_(3) if the system is in equilibrium the incline is smooth and string and pulley are light

A mass m_(1) lies on fixed, smooth cylinder . An ideal cord attached to m_(1) passes over the cylinder and is connected to mass m_(2) as shown in the figure. (a) Find the value of theta ( shown in diagram ) for which the system is in equilibrium. (b) Given m_(1)=5 kg, m_(2)=4kg . The system is released from rest when theta =30^(@) . Find the magnitude of acceleration of mass m_(1) just after the system is released.

Find force F required to keep the system in equilibrium. The dimensions of the system are d = 0.3 m and a = 0.2 m . Assume the rods to be massless.