A wheel of radius 20 cm has forces applied to it as shown in the figure. The torque produced by the forces 4N at A, 8N at B, 6N at C, and 9N at D at angles indicated is :

Forces are applied on a wheel of radius 20 cm as shown in the figure. The torque produced by the forces 4 N at A, 8N at B, 6 N at C and 9N at D at angles indicated is

Forces are applied on a wheel of radius 20 cm as shown in the figure. The torque produced by the forces 4 N at A, 8N at B, 6 N at C and 9N at D at angles indicated is

A wheel of radius 20 cm has four forces applied to it as shown in fig. Then, the torque produced by these forces about O is. .

A wheel of radius 10 cm can rotate freely about its centre as shown in figure. A string is wrapped over its rim and is pulled by a force of 5.0 N. It is found that the torque produces an angular acceleration 2.0 rad s^-2 in the wheel. Calculate the moment of inertia of the wheel.

A wheel of radius 10 cm can rotate freely about its centre as shown in figure. A string is wrapped over its rim and is pulled by a force of 5.0 N. It is found that the torque produces an angular acceleration 2.0 rad s^-2 in the wheel. Calculate the moment of inertia of the wheel.

A wheel of radius 10 cm can rotate freely about its centre as shown in figure. A stirng is wrapped over its rim and is ulle dby a force of 5.0 N. It is found that the torque roduces an angular acceleration 2.0 rad/s^2 in the wheel. Calculate the moment of inertia of the wheel.

A clockwise torque of 6N-m is applied to the circular cylinder as shown in the figure. There is no friction between the cylinder and the block.

A clockwise torque of 6N-m is applied to the circular cylinder as shown in the figure. There is no friction between the cylinder and the block.

A horizontal force F is applied such that the block remains stationary because N will produce torque. The torque produced by friction force is equal and opposite the torque produce due to normal reaction (N). .