A lift of mass 1000 kg is suspended by steel wire of maximum safe stress `1.4 xx 10^(8) N//m^(2)`. Find the minimum diameter of the wire, if the maximum acceleration of the lift is `1.2 ms^(-2)`

A bob of mass 10 kg is attached to wire 0.3 m long. Its breaking stress is 4.8 xx 10^(7) N//m^(2) . The area of cross section of the wire is 10^(-6) m^(2) . The maximum angular velocity with which it can be rotated in a horizontal circle

A bob of mass 10 kg is attached to wire 0.3 m long. Its breaking stress is 4.8 xx 10^(7) N//m^(2) . The area of cross section of the wire is 10^(-6) m^(2) . The maximum angular velocity with which it can be rotated in a horizontal circle

A bob of mass 10 kg is attached to a wire 0.3 m long. Its breaking stress is 4.8xx10^(7) N//m^(2) . Then area of cross-section of the wire is 10^(-6) m^(2) . What is the maximum angular velocity with which it can be rotated in a horizontal circle?

A lift of mass 200 kg is moving upward with an acceleration of 3m//s^(2) . If g=10 m//s^(2) then the tension of string of the lift will be :

If the elastic limit of copper is 1.5xx10^(8) N//m^(2) ,determine the minimum diameter a copper wire can have under a load of 10.0 kg force , if its elastic limit is not to be exceeded.

A substance breaks down under a stress of 10^(5) Pa . If the density of the wire is 2 xx 10^(3) kg//m^(3) , find the minimum length of the wire which will break under its own weight (g= 10 ms^(-12)) .

The maximum stress that can be applied to the material of a wire used to suspend an elevator is 1.3 xx 10^(8) Nm^(-2) . If the mass of the elevator is 900 kg and it moves up with an acceleration of 2.2 ms^(-2) , what is the minimum diameter of the wire?

A disc of mass 1 kg and radius 10 cm is suspended by vertical wire at its centre. If the time period is 3.2 s. Find the modulus of torison.

A mass of 1 kg is suspended by means of a thread. The system is (i) lifted up with an acceleration of 4.9ms^(2) (ii) lowered with an acceleration of 4.9ms^(-2) . The ratio of tension in the first and second case is

A lift of mass 1000 kg is going up. The variation in the speed of lift is shown in figure. Then the minimum tension in the rope will be (g=10 m//s^(2))