A body of mass `m` s connected to an inextensible thread of length `L` si whirled in horizontal circle. Find the maximum angular velocity with which it can be whirsted without breaking the thread (Breaking stress of thread `=S`)

A stone of mass of 16 kg is attached to a string 144 m long and is whirled in a horizontal circle. The maximum velocity of revolution that can be given to the stone without breaking it, will be (Breaking tension is 16 N)

A body of mass m = 0 kg is attached to a wire of length 0.3 m. Calculate the maximum angular velcoity with wicch it can be rotated in a horizontal circle (Breaking stress of wire = 4.8 x 10^(7)N//m^(2) and area of cross-section of wire = 10^(-6)m^(2) )

A body of mass m = 10 kg is attached to a wire of length 0.3m. The maximum angular velocity with which it can be rotated in a horizontal circle is (Given, breaking stress of wire = 4.8 xx 10^(7) Nm^(-2) and area of cross-section of a wire = 10^(-2) m^(2) )

A body of mass m = 10 kg is attached to a wire of length 0.3m. The maximum angular velocity with which it can be rotated in a horizontal circle is (Given, breaking stress of wire = 4.8 xx 10^(7) Nm^(-2) and area of cross-section of a wire = 10^(-6) m^(2) )

A stone of mass 4 kg is attached to a string of 10 m length and is whirled in a horizontal circle. The string can withstand a maximum tension of 160 N. Calculate the maximum velocity of revolution that can be given to the stone without breaking the string.

A stone of mass 2.0 kg is tied to the end of a string of 2m length. It is whirled in a horizontal circle. If the breaking tension of the string is 400 N, calculate the maximum velocity of the stone.

A stone of mass 2.0 kg is tied to the end of a string of 2m length. It is whirled in a horizontal circle. If the breaking tension of the string is 400 N, calculate the maximum velocity of the stone.