A ball of mass m and radius r is released in viscous liquid. The value of its terminal velocity is proportional to

A spherical metal ball of mass m and radius (r ) is falling through a viscous medium. The value of its terminal velocity is proportional to

A ball of mass M and radius R is released on a rough inclined plane of inclination theta . Friction is not sufficient to prevent slipping. The coefficient friction between the ball and the plane is mu . Find (a). The linear acceleration of the ball down the plane. (b). the angular acceleration of the ball about its centre of mass.

A small lead ball is falling freely in a viscous liquid The velocity of the ball

A small steel ball of mass m and radius r is falling under gravity through a viscous liquid of coefficient of viscosity eta . If g is the value of acceleration due to gravity. Then the terminal velocity of the ball is proportional to (ignore buoyancy)

A marble of mass x and diameter 2r is gently released in a tall cylinder containing honey. If the marble displaces mass y(ltx) of the liquid, then the terminal velocity is proportional to

A ball of mass m and radius r rolls inside a hemispherical shell of radius R . It is released from rest from point A as shown in figure. The angular velocity of centre of the ball in position B about the centre of the shell is. .

A steel ball of mass m falls in a viscous liquid with terminal velocity v, then the steel ball of mass 8m will fall in the same liquid with terminal velocity

The terminal velocity of small sized spherical body of radius r falling veertically in a viscous liquid is given by a following proportionality

The viscous force acting on a solid ball of surface area. A moving with terminal velocity v is proportional to

Two spheres of equal masses but radii R and 2 R are allowed to fall in a liquid, the ratio of their terminal velocities is