A cone of radius r and height h is kept on a turntable rotating with an angular velocity. The friction between te table and the cone is sufficient so that the cone does not slide. The distance between the axis of the cone and the axis of turntable is `R(Rgtgtr)`. the maximum value of `omega` for which the cone does not topple is `sqrt((xgr)/(Rh))`, calculate x.

A chain of mass 'm' and radius 'r' is placed onto a cone of semi vertical angle theta . Cone rotated with angular velocity omega . Find the tension in the chain if it does not slide on the cone.

A particle of mass m is placed over a horizontal circular table rotating with an angular velocity omega about a vertical axis passing through its centre. The distance of the object from the axis is r . Find the force of friction f between the particle and the table.

A cylinder with radius R spins about its horizontal axis with angular speed omega . There is a small block lying on the inner surface of the cylinder. The coefficient of friction between the block and the cylinder is mu . Find the value of omega for which the block does not slip, i.e., stays at rest with respect to the cylinder.

A block of mass m is kept on horizontal turn table at x distance from the centre. If coefficient of friction between block and surface of turn table is mu , then maximum angular speed of the table so that block does not slip

A rough horizontal plate rotates with angular velocity omega about a fixed verticle axis. A particle or mass m lies on the plate at a distance (5a)/(4) from this axis. The coefficient of friction between the plate and the particle is (1)/(3) . The largest value of omega^(2) for which the oparticle will continue to be at rest on the revolving plate is

Two equal masses m are attached by a string. One mass lies at radial distance r from the centre of a horizontal turntable which rotates with constant angular velocity omega=2 rad s(1) , while the second hangs from the string inside the tumtable's hollow spindle (see fig.) The coefficient of static friction between the turntable and the mass lying on it is mu_(s)=0.5 . The maximum and minimum values of radius such that the mass lying on the turntable does not slide are r_("max")+r_("min") in meter is

A coin kept at a distance of 5 cm from the centre of a turntable of radius 1.5 m just begins to slip when the turntable rotates at a speed of 90 r.p.m. Calculate the coefficient of static friction between the coin and the turntable [g = 9.8 m//s^(2)]

A block of mass m is kept on the edge of a horizontal turn table of radius R which is rotating with constant angular verticle omega (along with the block ) about its axis . If coefficient of friction is mu , find the friction force between block and table.

A uniform circular ring of radius R is first rotated about its horizontal axis with an angular velocity omega_0 and then carefully placed on a rough horizontal surface as shown. The coefficient of friction between the surface and the rings mu . Time after which its angular speed is reduced to 0.5 omega_0 is