A mass M is suspended as shown in string, spring, pulley system. Assure ideal conditions. The system is in equilibrium. The extension produced in the spring is ` (xMg)/k` the value of 'x' is

A mass M is suspended as shown in fig. The system is in equilibrium. Assume pulleys to be massless. K is the force constant of the spring. The extension produced in the spring is given by

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

A mass M is suspended as shown in fig. The system is in equilibrium. Assume pulleys to be massless. K is the force constant of the spring. Find the net tension force acting on the lower support.

A mass M is suspended as shown in fig. The system is in equilibrium. Assume pulleys to be massless. K is the force constant of the spring. If each of the pullies A and B has mass M, then find the net tension force acting on the lower support. Asumme pulleys to be frictionaless.

Two masses m and M are attached to the strings as shown in the figure. If the system is in equilibrium, then

All surfaces shown in figure are smooth system is released with the spring unstretched In equilibrium, compression in the spring will be

All surfaces shown in figure are smooth system is released with the spring unstretched In equilibrium, compression in the spring will be

The pulleys and strings shown in fig are smooth and of negligible mass. For the system to remain in equilibrium the angle theta should be:

In an elevator a system is arranged as shown in figure. Initially elevator is at rest and the system is in equilibrium with middle spring unstretched. When the elevator accelerated upwards, it was found that for the new equilibrium position (with respect to lift), the further extension i the top spring is 1.5 times that of the further compression in the bottom spring, irrespective of the value of acceleration (a) Find the value of (m_1)/(m_2) in terms of spring constants for this happen. (b) if k_1=k_2=k_3=500(N)/(m) and m_1=2 kg and acceleration of the elevator is 2.5(m)/(s^2) , find the tension in the middle spring in the final equilibrium with respect to lift.

An ideal string pulley system is shown in the figure and system is released from rest choose correct option