Two discs, each having mass m, are attac...

Two discs, each having mass `m`, are attached rigidly to the ends of a vertical spring. One of the discs rests on a horizontal surface and the other produces a compression `x_0` on the spring when it is in equilibrium. How much further must the spring be compressed so that when the force causing compression is removed, the extension of the spring will be able to lift the lower disc off the table?

A

(a) `x_0`

B

(b) `2x_0`

C

(c) `3x_0`

D

(d) `1.5x_0`

Text Solution

Verified by Experts

The correct Answer is:

B

A is the position of the spring when it is in its normal uncompressed length. The upper disc compresses the spring by `x_0` when spring is in equilibrium. So `kx_0=mg`. Hence, B is the equilibrium position of the spring. Let it be further compressed by y and released. After releasing it can be proved that the spring will go up to the position D so that `BC=BD`. Extension in the spring at this position
`=y-x_0`.
Now for lifting up of the lowe disc:
`k(y-x_0)=mgimpliesy=(mg)/(k)+x_0`
`impliesy=x_0+x_0=2x_0`

Doubtnut Promotions Banner Desktop Dark

Doubtnut Promotions Banner Mobile Dark

|

Topper's Solved these Questions

WORK, POWER & ENERGY
CENGAGE PHYSICS|Exercise Multiple Correct|25 Videos
WORK, POWER & ENERGY
CENGAGE PHYSICS|Exercise Linked Comprehension|55 Videos
WORK, POWER & ENERGY
CENGAGE PHYSICS|Exercise Subjective|23 Videos
VECTORS
CENGAGE PHYSICS|Exercise Exercise Multiple Correct|5 Videos

Similar Questions

Explore conceptually related problems

A 16kg block moving on a frictionless horizontal surface with a velocity of 4m//s compresses an ideal spring and comes to rest. If the force constant of the spring be 100N//m , then how much is the spring commpressed ?

Two blocks each having mass m is attached to each other with a spring having force constant k. The system is placed on a rough horizontal surface having coefficient of friction mu . The maximum initial compression, that can be given to the spring so that when released the blocks do not move is

Knowledge Check

Two plates of some mass are attached rigidly to the two ends of a spring as shown in figure. One of the two ends of a spring s shown in figure. One of the plates resets on a horizontal surface to the other rusults a compression y of the spring when it is in equilibrium state. The further minimum compression required, so that when the force causing compression is removed the lower plate is lifted off the surface, will be :

A

`0.5 y`

B

`3y`

C

`2y`

D

`y`

When a spring is compressed by 0.05 m a restoring force of 10 N is developed in it. Then the force constant of the spring is

A

50 N/m

B

100 N/m

C

150 N/m

D

200 N/m

A compressed spring possesses :

A

Electric energy

B

Chemical energy

C

Potential energy

D

Kinetic energy

Similar Questions

Explore conceptually related problems

The spring is compressed by a distance a and released. The block again comes to rest when the spring is elongated by a distance b . During this

A block of mass m initially at rest is dropped from a height h on to a spring of force constant k . the maximum compression in the spring is x then

All surfaces shown in figure are smooth system is released with the spring unstretched In equilibrium, compression in the spring will be

A vertical spring with force constant k is fixed on a table. A ball of mass m at a height h above the free upper end of the spring falls vertically on the spring, so that the spring is compressed by a distance d. The net work done in the process is

A vertical spring with force constant k is fixed on a table. A ball of mass m at a height h above the free upper end of the spring falls vertically on the spring, so that the spring is compressed by a distance d. The net work done in the process is

CENGAGE PHYSICS-WORK, POWER & ENERGY-Single Correct

A particle of mass m moves along a circular path of radius r with a ce...
02:36
|
A chain of length l and mass m lies of the surface of a smooth hemisph...
06:38
|
Two discs, each having mass m, are attached rigidly to the ends of a v...
05:32
|
Two ends A and B of a smooth chain of mass m and length l are situated...
02:48
|
A block m is kept stationary on the surface of an accelerating cage as...
03:23
|
A man places a chain (of mass m and length l) on a table slowly. Initi...
03:30
|
The potential energy of a particle of mass m free to move along the x-...
02:18
|
The blocks A and B shown in figure have masses MA=5kg and MB=4kg. The ...
04:23
|
A collar B of mass 2kg is constrained to move along a horizontal smoot...
03:20
|
A block attached to a spring, pulled by a constant horizontal force, i...
02:48
|
A particle is projected along a horizontal field whose coefficient of ...
03:39
|
Two identical blocks A and B are placed on two inclined planes as show...
04:28
|
A block of mass m is being pulled up a rough incline by an agent deliv...
03:00
|
The given plot shows the variation of U, the potential energy of inter...
04:49
|
One end of an unstretched vertical spring is attached to the ceiling a...
02:52
|
The potential energy function associated with the force vecF=4xyhati+2...
02:35
|
The potential energy for a force filed vecF is given by U(x,y)=cos(x+y...
02:36
|
A particle is projected with a velocity u making an angle theta with t...
02:51
|
A block of mass m is attached with a massless spring of force constant...
04:36
|
In the above question, the maximum power delivered by the agent in pul...
Text Solution
|