A car takes a turn on a slippery road at a safe speed of 9.8 m/s .If the coefficient of friction is 0.2 the manimum radius of the are in which the car takes a trun is

A car turns a corner on a slippery road at a constant speed of 10 m /s . If the coefficient of friction is 0.5, the minimum radius of the arc in meter in which the car turns is

A car turns a corner on a slippery road at a constant speed of s m /10 . If the coefficient of friction is 0.5, the minimum radius of the arc in meter in which the car turns is

A car turns a corner on a slippery road at a canstant speed of 12m//s . If the co0efficient is 0.4 , the minimum radius of the arc in metres in which the car truns is.

A car turns a corner on a slippery road at a speed of 12ms^(-1) . If the coefficient of friction is 0.4, the (in m) in which the car turns is

A bus turns a slippery road having coefficient of friction of 0*5 with a speed of 110 m/s .The minimum radius of the arc in which bus turns is [ Take g = 10 m/s^(2)]

A bus turns a slippery road having coefficient of friction of 0*5 with a speed of 10 m/s .The minimum radius of the arc in which bus turns is [ Take g = 10 m/s^(2)]

Consider a car moving along a straight horizontal road with a speed of 36 km/h. If the coefficient of static friction between road and tyers is 0.4, the shortest distance in which the car can be stopped is (Take g=10 m//s2)

Consider a car moving along a straight horizontal road with a speed of 36 km/h. If the coefficient of static friction between road and tyers is 0.4, the shortest distance in which the car can be stopped is (Take g=10 m//s2)

A car is taking turn on a circular path of radius R. If the coefficient of friction between the tyres and road is mu , the maximum velocity for no slipping is