A wire is supporting two masses on a pulley as shown. If breaking stress of wire is `(2400/ pi) N/m^(-2)`. Find minimum radius of wire, so that it does not break.

The breaking stress of a wire depends on

Two blocks of masses 2 kg and 3kg are connected by a metal wire going over a smoother pulley as shown in figure. The breaking stress of the steel is 2xx10^(9)Nm^(-2) . What would be the minimum radius of the wire used if it not to break ? Take , g=10 ms^(-2)

Two blocks of masses 1 kg and 2kg are connect by a metal wire going over a smooth pulley as shown in figure. The breaking stress of the metal is 2xx10^9m^-2 . What should be the minmum radius of the wire used if it is not to break? Take g=10ms^-2

Two blocks of masses 3 kg and 5 kg are connected by a metal wire going over a smooth pulley. The breaking stress of the metal is 24/pi xx 10^2 Nm^( - 2) . What is the minimum radius of the wire ? (take g=10ms^(-2) )

Two blocks of masses 1 kg and 2 kg are connected by a metal wire goijng over a smooth pulley as shown in figure. The breaking stress of the metal is (40//3pi)xx10^(6)N//m^(2) . If g=10ms^(-12) , then what should be the minimum radlus of the wire used if it is not to break?

Two blocks of masses 5 kg and 10 kg are connected by a metal wire going over a smooth pulley as shown in the figure. The breaking stress of the metal wire is 2xx10^(9)"N m"^(-2) . If g=10ms^(-2) , then what is the minimum radius of the wire which will not break

Two bodies of masses 2kg and 3kg are connected by a metel wire of cross section 0.04 mm^(2) . Breaking stress of metel wire is 2.5 Gpa. The maximum force F that can be applied to 3kg block so that wire does not break is :

Two bodies of masses 2 kg and 3 kg are connected by a metal wire of cross-section 0.04 mm^(2) and are placed on a frictionless horizontal surface. Breaking stress of metal wire is 2.5 Gpa. The maximum force F that can be applied to 3kg block so that wire does not break is

Two blocks of masses m and 2m are connected through a wire fo breakig stress S passing over a frictionless pulley. The maximum radius of the wire to be used so that the wire may not break is

A body of mass 500 g is fastened to one end of a steel wire of length 2m and area of cross-section 2m m^(2) . If the breaking stress of the wire is 1.25 xx 10^(7) N//m^(2) , then the maximum angular velocity with which the body can be rotated in a horizontal circle is