Consider a vehicle taking turn on the horizontal curve with speed `v`. If the distance between wheels is `2m`, height of center of mass above road is `1 m` and radius of circle is `57.6 m`, find the maximum value of `v` for no overturning.

Two wires AC and BC are tied at C of small sphere of mass 5kg which revolves at a constant speed v in the horizontal circle of radius 1.6 m Find the maximum value of v

A vehicle of mass M is moving on a rough horizontal road with a momentum P If the coefficient of friction between the tyres and the road is mu is then the stopping distance is .

A loop of mass M and radius R is rolling on a smooth horizontal surface with speed 'v'. It's total kinetic energy is

A vehicle of mass m is moving on a rough horizontal road with momentum P . If the coefficient of friction between the tyres and the road br mu, then the stopping distance is:

A vehicle moves on a horizontal curved road of radius of curvature 50 m height of centre of gravity 1.5 m the distance between the two wheels 2 m and acceleration due to gravity 9.8 m//s ^(2) . Then the maximum velocity with which it can travel on the road will be

A car of mass m travelling at speed v moves on a horizontal track. The centre of mass of the car describes a circle of radius r . If 2a is the separation of the inner and outer wheels and h is the height of the centre of mass above the ground, show that the limiting speed beyond which the car will overturn in given by v^(2)=(gra)/h

The CG of a loaded truck is at a height of 3 m above the ground and the distance between its wheels is 3m. What is the maximum speed with which it can go round a curved road of radius 200 m without turning turtle ?