In the shown figure inside a fixed hollow cylinder with vetical axis a pendulumm is rotating in a conical path with its axis same as that of the cylinder with uniform angular velocity. Radius of culinder is 30cm, length of string is 50cm and mass of bob is 400gm. The bob makes contact with the inner fricitonless wall of the cylinder while moving

Let the moment of inertia of a hollow cylinder of length 30 cm (inner radius 10 cm and outer radius 20 cm ), about its axis be I. the radius of a thin cylinder of the same about its axis is also I is :

A solid cylinder of mass 2 kg and radius 0.2m is rotating about its own axis without friction with angular velocity 3 rads/s. A particle of mass 0.5 kg and moving with a velocity 5 m/s strikes the cylinder and sticks to it as shown in figure. The angular momentum of the cylinder before collision will be?

A uniform cylinder of radius r and mass m can rotate freely about a fixed horizontal axis. A thin cord of length l and mass m_(0) is would on the cylinder in a single layer. Find the angular acceleration of the cylinder as a function of the length x of the hanging part of the end. the wound part of the cord is supposed to have its centre of gravity on the cylinder axis is shown in figure.

A block of mass 10 kg in contact against the inner wall of a hollow cylindrical drum of radius 1m. The coefficient of friction between the block and the inner wall of the cylinder is 0.1. The minimum angular velocity needed for the cylinder to keep the block stationary when the cylinder is vertical and rotating about its axis, will be (g=10 m//s^(2))

In a gravity free space, a hollow cylinder of radius 4R and mass M is being rotated by a constant angular velocity omega clockwise w.r.t. an inertial frame of reference. Another hollow cylinder of radius R and mass m is rotating inside this cylinder, such that it touches the inner surface of larger cylinder without slipping and its centre of mass appears stationery from inertial frame Dynamic friction coefficient between cylinders is mu . If the normal reaction between cylinders is denoted by N , answer the following questions. What is the angular velocity of smaller cylinder.

In a gravity free space, a hollow cylinder of radius 4R and mass M is being rotated by a constant angular velocity omega clockwise w.r.t. an inertial frame of reference. Another hollow cylinder of radius R and mass m is rotating inside this cylinder, such that it touches the inner surface of larger cylinder without slipping and its centre of mass appears stationery from inertial frame Dynamic friction coefficient between cylinders is mu . If the normal reaction between cylinders is denoted by N , answer the following questions. What is the value of N

A cylinder of mass 5kg and radius 10cm is moving on a horizontal surface with speed. 5m//s and angular speed about axis through C.M. 10rad//s . Find the angular momentum of the cylinder about point of contact.

A semicircular track of radius R=62.5cm is cut in a block. Mass of block having track, is M=1kg and rests over a smooth horizontal floor. A cylinder of radius r=10 cm and mass m=0.5kg is hanging by thread such that axes of cylinder and track are in same level and surface of cylinder is in contact with the track as shown in figure When the thread is burnt, cylinder starts to move down the track. Sufficient friction exists between surface of cylinder and track, so that cylinder does not slip. Calculate velocity of the block when it reaches bottom of the track. Also find force applied by block on the floor at that moment. (g=10m//s^(2))

A very long, solid insulating cylinder with radius R has a cylindrical hole with radius a bored along its entire length. The axis of the hole is at a distance b from the axis of the cylinder, where altbltR (as shown in figure). The solid material of the cylinder has a uniform volume charge density rho . Find the magnitude and direction of the electric field inside the hole, and show that this is uniform over the entire hole. .

A uniform disc of mass m and radius R rotates about a fixed vertical axis passing through its centre with angular velocity omega . A particle of same mass m and having velocity of 2omegaR towards centre of the disc collides with the disc moving horizontally and sticks to its rim. Then