A car weighs `1800 kg`. The distance between its front and back axles is `1.8 m`. Its centre of gravity is `1.05 m` behind the front axle. Determine the force exerted by the level ground on each front wheel and each back wheel.

The distance between the inner and outer wheels of a car is 1.75 m and its centre of gravity is 0-50 m above the ground. What is the maximum speed with which the car can negotiate a curve of radius of 40 m without overturning ?

The centre of gravity of a car is at a height h and the distance between its wheel is 2a. The car moves on a level curve of radius r with speed v . Let N_(1) and N_(2) be the normal reactions on the inner and outer wheels of the car. Then

The dipole moment of a short bar magnet is 1.25 A-m^(2) . The magnetic field on its axis at a distance of 0.5 metre from the centre of the magnet is

Two conductors each of length 12 m lie parallel to each other in air. The centre to center distance between two conductors is 15 xx 10^(-2) m and the current in each conductor is 300 amperes. Determine the force in newton tending to pull the conductors together.

A 3m along ladder weighing 20 kg leans on a frictionless wall. Its feet rest on the floor 1 m from the wall. Find the rection forces of the wall and the floor.

A 3m along ladder weighing 20 kg leans on a frictionless wall. Its feet rest on the floor 1 m from the wall. Find the rection forces of the wall and the floor.

A car travels from A to B and returns to its original position. The distance between A and B is 2000 m. The car takes 5 min to travel from A to B but takes 8 min to travel back from B to A. Is the speed of the car greater while going from A to B or while travelling back from B to A?

Figure shows a pulley of mass m and radius r with two blocks of masses m_(1) and m_(2) attached with a light and unstretchable string. Find the acceleration of the blocks, tensions in the string and the force exerted by the pulley on the celling from which it is hanging. Assume no slipping between the string and the wheel.

A bicycle is traveling downhill at a high speed. Suddenly, the cyclist sees that a bridge ahead has collapsed, so she has to stop. What is the maximum magnitude of acceleration the bicycle can have if it is not to flip over its front wheel—in particular, if its rear wheel is not to leave the ground? The slope makes an angle of 37^@ with the horizontal. On level ground, the centre of mass of the woman–bicycle system is at a point 1.0 m above the ground, 1.0 m horizontally behind the axle of the front wheel, and 35.0 cm in front of the rear axle. Assume that the tires do not skid.

The diameter of the front and the rear wheels of a tractor are 63 cm and 1.54 m respectively. The rear wheel is rotating at 24(6)/(11) revolutions per minute. Find : the revolutions per minute made by the front wheel.