A cylinder of `150 mm` radius rotates concentrically inside a fixed cylinder of `155 mm` radius. Both culinders are `300 mm` long. Determine the viscosity of the liquid which fills the space between the cylinders if a torque of `0.98 n-m` is required to maintain an angular velocity of `60 r.p.m.`

A solid cylinder of radius 0.5 m and mass 50 kg is rotating at 300 rpm. Then the torque which will bring it to rest in 5 seconds is

A cylinder of mass M, radius r_(1) and lenglth l is kept inside another cylinder of radius r_(2) and length l. The space between them is filled with a liquid of viscosity eta . The inner cylinder starts rotating with angular velocity omega while the other cylinder is at rest. Find time when inner cylinder stops.

A solid cylinder of mass 20 kg rotates about its axis with angular velocity of 100 radian s^(-1) . The radius of the cylinder is 0.25m . The magnitude of the angular momentum of the cylinder about its axis of rotation is

A long cylinder of radius R_1 is displaced along its axis with a constant velocity v_0 inside a stationary co-axial cylinder of radius R_2 . The space between the cylinders is filled with viscous liquid. Find the velocity of the liquid as a function of the distance r from the axis of the cylinders. The flow is laminar.

The axis of the uniform cylinder in figure is fixed. The cylinder is initially at rest. The block of mass M is initially moving to the friction and with speed v_(1) . It passes over the cylinder to the dashed position. When it first makes contact with the cylinder, it slips on the cylinder, but the friciton is large enough so that slipping ceases before M loses contacts wtih the cylinder. the cylinder has a radius R and a rotaitonal intertia I If omega is final angular velocity of the cylinder, then

A light thread with a body of mass m tied to its end is wound on a uniform solid cylinder of mass M and radius R . At a moment t=0 the system is set in motion. Assuming the friction in the axle of the cylinder to be negligible, find the time dependence of (a) the angular velocity of the cylinder and (b) the kinetic energy of the whole system ( M=2m ).

A particle of mass m moves along the internal smooth surface of a vertical cylinder of the radius R. Find the force with which the particle acts on the cylinder wall if at the initial moment of time its velocity equals v_(0) . And forms an angle alpha with the horizontal.

A solid cylinder of mass 'M' and radius 'R' is rotating along its axis with angular velocity omega without friction. A particle of mass 'm' moving with velocity v collides aganist the cylinder and sticks to its rim. After the impact calculate angular velocity of cylinder .

Consider a disk of mass m , radius R lying on a liquid layer of thickness T and coefficient of viscosity eta as shown in the fig. The torque required to rotate the disk at a constant angular velocity Omega given the viscosity is uniformly eta .