The basket in a front loading automatic clothes dryer rotates about a horizontal axis. The basket rotates so that the force exerted by the basket on clothes located at the basket's edge is zero at the top of the path. If the radius of the basket is 0.65 m, how fast must the basket turn to accomplish this ?

An automatic tumble dryer has a 0.65 m diameter basket that rotates about a horizontal axis. As the basket turns, the clothes fall away from the basket at a point 60^(@) from the vertical what is the rate of rotation of dryer drum ? Take g=10 m//s^(2)

A horizontal disc of radius R rotates with a constant angular velocity omega about a stationary vertical axis passing through its edge. Along the circumference of the disc a particle of mass m moves with a velocity that is constant relative to the disc. At the moment when the particle is at the maximum distance from the rotation axis, the resultant of the inertial forces F_(i n) acting on the particle in the reference frame fixed to the disc turns into zero. Find: (a) the acceleration w^' of the particle relative to the disc, (b) the dependence of F_(i n) on the distance from the rotation axis.

A man of mass m_1 stands on the edge of a horizontal uniform disc of mass m_2 and radius R which is capable of rotating freely about a stationary vertical axis passing through its centre. At a certain moment the man starts moving along the edge of the disc, he shifts over an angle varphi^' relative to the disc and then stops. In the process of motion the velocity of the man varies with time as v^'(t) . Assuming the dimensions of the man to be negligible, find: (a) the angle through which the disc had turned by the moment the man stopped, (b) the force moment (relative to the rotation axis) with which the man acted on the disc in the process of motion.

A hot- air balloon consists of a basket, one passenger, and some carge. Let the total mass be M. Even though there is an upward lift force on the balloon, the balloon is initially acceleration downwards at a rate of g//3 . (a) Draw a free-body diagram for the descending balloon. (b) Find the upward lift force in terms of the initial total weight Mg. (c ) The passenger notices that he is heading straight for a waterfall and decides he needs to go up. What fraction of the total weight must he drop overboard so that the balloon accelerates upward at a rate of g//2 ? Assume that the upward lift force remains the same.

A horizontally oriented uniform rod AB of mass m=1.40kg and length l_0=100cm rotates freely about a stationary vertical axis OO^' passing through its end A. The point A is located at the middle of the axis OO^' whose length is equal to l=55cm . At what angular velocity of the rod the horizontal component of the force acting on the lower end of the axis OO^' is equal to zero? What is in this case the horizontal component of the force acting on the upper end of the axis?

A horizontally oriented uniform disc of mass M and radius R rotates freely about a stationary vertical axis passing through its centre. The disc has a radial guide along which can slide without friction a small body of mass m . A light thread running down through the hollow axle of the disc is tied to the body initially the body was located at the edge of the disc and the whole system rotated with ann angular velocity omega_(0) . Then by means of a force F applied to the lower and of the thread the body was slowly pulled to the rotation axis. find: (a). The angular velocity of the system in its final state. (b). The work performed by the force F.

A disc of mass m and radius R is free to rotate in a horizontal plane about a vertical smooth fixed axis passing through its centre. There is a smooth groove along the diameter of the disc and two small balls of mass m//2 each are placed in it on either side of the centre of the disc as shown in Fig. The disc is given an initial angular velocity omega_(0) and released. The net work done by forces exerted by the disc on the ball for the duration ball remains on the disc is