8 kg wheel has radius of gyration (1/4) m. The torque required to give it an angular acceleration of 4 `rad//s^(2)`, is

The moment of inertia of a body is 2.5 kg m^(2) . Calculate the torque required to produce an angular acceleration of 18 rad s^(-2) in the body.

A spherical shell has a radius of 1.90 m. An applied torque of 960 N-m gives the shell an angular acceleration of "6.20 rad/s"^2 about an axis passing through the centre of the shell. What are the mass of the shell ?

A spherical shell has a radius of 1.90 m. An applied torque of 960 N-m gives the shell an angular acceleration of "6.20 rad/s"^2 about an axis passing through the centre of the shell. What are the rotational inertia of the shell about that axis

If a wheel has mass 70 kg and radius of gyration 1 m, then the torque required an angular 1 m, then the torque required an angular acceleration of "2 rev"//s^(2) will be

The radius of a wheel of car is 0.4m . The car is accelerated from rest by an angular acceleration of 1.5 rad//s^(2) for 20 s . How much distance will the wheel cover in this time and what will be its linear velaocity ?

The torque acting is 2000 Nm with an angular acceleration of 2rad//s^(2) . The moment of inertia of body is

A torque tau applied to a dise of mass 2 kg and radius of gyration 15 cm produces an angular acceleration of 5 "rad"//sec^(2) . Find the value of tau .

A torque of 10^(8) dyne - cm is applied to a fly wheel of mass 10 kg and radius of gyration 50 cm . What is the resultant angular acceleration ?

A torque of 10 Nm is applied to a flywheel of mass 10 kg and radius of gyration 50 cm. What is the resulting angular acceleration ?

A wheel of radius 0.4m can rotate freely about its axis as shown in the figure. A string is wrapped over its rim and a mass of 4 kg is hung. An angular acceleration of 8 rad//s^(2) is produced in it due to the torque. Then, the moment of inertia of the wheel is ( g=10m//s^(2) )