A hollow vertical cylinder of radius R is rotated with angular velocity `omega` about an axis through its centre. What is the minimum coefficient of static friction between block M and cylinder wall necessary to keep the block suspended on the inside of the cylinder ?

A uniform cylinder of radius R is spinned about it axis to the angular velocity omega_(0) and then placed into a corner,. The coeficient of friction between the corner walls and the cylinder is mu_(k) How many turns will the cylinder accomplish before it stops?

A block of mass m is supported on a rough wall by applying a force in figure Coefficient of static friction between block and wall is mu For what range of value of p , the block remain in static equilibrium ?

A horizontal disk is rotating with angular velocity omega about a vertical axis passing through its centre. A ball is placed at the centre of groove and pushed slightly. The velocity of the ball when it comes out of the groove -

A solid cylinder of mass M and radius R rotates about its axis with angular speed omega . Its rotational kinetic energy is

A solid sphere of radius r and mass m rotates about an axis passing through its centre with angular velocity omega . Its K.E . Is

A person stands in contact against a wall of cylindrical drum of radius r, rotating with an angular velocity omega . If mu is the coefficient of friction between the wall and the person, the minimum rotational speed which enables the person to remain stuck to the wall is

An insect of mass m=3kg is inside a vertical drum of radius 2m that is rotating with an angular velocity of 5rads^(-1) . The insect doesn't fall off. Then, the minimum coefficient of friction required is

A solid cylinder of mass m is kept in balance on a fixed incline of angle alpha=37^@ with the help of a thread fastened to its jacket. The cylinder does not slip. The values of minimum coefficient of static friction between cylinder and incline in the case when F is minimum.

There are two blocks of masses m_(1) and m_(2) , m_(1) is placed on m_(2) on a table which is rotating with an angular velocity omega about the vertical axis . The coefficent of friction between the block is mu_(1) and between m_(2) and table is mu_(2) (mu_(1) lt mu_(2)) if block are placed at distance R from the axis of ratation , for relative sliding between the surface in contact , find the a. friction force at the contacting surface b. maximum angular speed omega

A cylinder of mass m radius R is spined to a clockwise angular velocity omega_(o) and then gently placed on an inclined plane for which coefficient of friction mu = tan theta, theta is the angle of inclined plane with the horizontal. The centre of mass of cylinder will remain stationary for time