A horizontal disc is oscillating in its own plane harmonically with amplitude a and period T. A body placed on the disc is about to slip on it. What is the coefficient of friction between the disc and the body?

A coin placed on a horizontal rotating disc, with its centre at 10 cm from the centre of the disc, is about to slip off when the disc performs 60 rpm. Find the coefficient of friction between the coin and the disc.

A coin is placed at the edge of a horizontal disc rotating about a vertical axis through its axis with a uniform angular speed 2 rad s^(-1) . The radius of the disc is 50 cm. Find the minimum coefficient of friction between disc and coin so that the coin does not slip. (Take g = 10 m//s^(2) )

A body of mass 2 kg is placed on rough horizontal plane. The coefficient of friction between body and plane is 0.2 Then,

A disc rotates about its aixs of symmetry in a horizontal plane at a steady rate of 3.5 revolutions per second A coin placed at a distance fo 1.25 cm form the axis of ratation remains at rest on the disc The coefficient of friction between the coin and the disc is : (g=10//s^(2))

A disc rotates at 60 rev//min around a vertical axis.A body lies on the disc at the distance of 20cm from the axis of rotation.What should be the minimum value of coefficient of friction between the body and the disc,so that the body will not slide off the disc

A disc of radius 4m is rotating about its fixed centre with a constant angular velocity 2(rad)/(s) (in the horizontal plane).A block is also rotating with the disc without slipping. If co-efficient of friction between the block and the disc is 0.4 ,then the maximum distance at which the block can rotate without

A uniform disc of mass m and radius R I rotated about an axis passing through its centre and perpendicular to its plane with an angular velocity omega_() . It is placed on a rough horizontal plane with the axis of the disc keeping vertical. Coefficnet of friction between te disc and the surface is mu , find (a). The time when disc stops rotating (b). The angle rotated by the disc before stopping.