When shearing force is applied to a body, then the elastic potential energy is stored in it. On removing the force, this energy:
1. converts into kinetic energy.
2. converts into heat energy.
3. remains as potential energy.
4. None of the above
A wire is suspended by one end. At the other end a weight equivalent to 20 N force is applied. If the increase in length is 1.0 mm, the increase in energy of the wire will be
(1) 0.01 J
(2) 0.02 J
(3) 0.04 J (4) 1.00 J
The ratio of Young's modulus of the material of two wires is 2 : 3. If the same stress is applied on both, then the ratio of elastic energy per unit volume will be-
(1) 3 : 2
(2) 2 : 3
(3) 3 : 4
(4) 4 : 3
The stress versus strain graphs for wires of two materials A and B are as shown in the figure. If and are the Young ‘s modulii of the materials, then
(1)
(2)
(3)
(4)
If a spring extends by x on loading, then the energy stored by the spring is (if T is tension in the spring and k is spring constant)
(1)
(2)
(3)
(4)
When a force is applied on a wire of uniform cross-sectional area and length 4m, the increase in length is 1 mm. Energy stored in it will be
1. 6250 J 2. 0.177 J
3. 0.075 J 4. 0.150 J
A stretched rubber has:
(1) increased kinetic energy.
(2) increased potential energy.
(3) decreased kinetic energy.
(4) decreased potential energy.
When load of 5kg is hung on a wire then extension of 3m takes place, then work done will be
(1) 75 joule
(2) 60 joule
(3) 50 joule
(4) 100 joule
When strain is produced in a body within elastic limit, its internal energy:
1. Remains constant
2. Decreases
3. Increases
4. None of the above
If the force constant of a wire is \(K\), the work done in increasing the length of the wire by \(l\) is:
1. \(\frac{Kl}{2}\)
2. \(Kl\)
3. \(\frac{Kl^2}{2}\)
4. \(Kl^2\)