A mass of mass 60 kg hangs himself from a massless spring balance. Which itself suspneded from an ideal string-pulley system as shown in the figure. The stirng AB can bear maximum 900 N. Choose correct statement.

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

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

A mass of 10 kg is suspended from a spring balance. It is pulled aside by a horizontal string so that it makes an angle of 60^(@) with the vertical. The new rading of the balance is

A mass of 10 kg is suspended from a spring balance, it is pulled aside by a horizontal string so that it makes an angle 60^(@) with the vertical. The new reading of the balance is:

A mass of 10 kg is suspended from a spring balance. It is pulled aside by a horizontal string so that it makes an angle of 60^(@) with the vertical. The new rading of the balance is

Two block of mass 2kg are connected by a massless ideal spring of spring contant K=10N//m . The upper block is suspended from roof by a light string A . The system shown is in equilibrium. The string A is now cut, the acceleration of upper block just after the string A is cut will be (g=10m//s^(2) .

Two block of mass 2kg are connected by a massless ideal spring of spring contant K=10N//m . The upper block is suspended from roof by a light string A . The system shown is in equilibrium. The string A is now cut, the acceleration of upper block just after the string A is cut will be (g=10m//s^(2) .

Two block of mass 2kg are connected by a massless ideal spring of spring contant K=10N//m . The upper block is suspended from roof by a light string A . The system shown is in equilibrium. The string A is now cut, the acceleration of upper block just after the string A is cut will be (g=10m//s^(2) .

Consider the situation shown in the figure. A mass is hanging from a inextensible string which is passing over a pulley. The pulley itself is attached to a massless spring of stiffness k as shown in the figure. Find the time period of vertical oscillations of mass m if pulley is slightly displaced from its mean position. Assume that string does not slip over pulley.