Work And Energy

We know that,

Work done = Force × Displacement

W = F × s

Given,

Force, F = 7 N

Displacement, s = 8 m

W = 7 × 8

= 56 J

Therefore, the work done is 56 J

Work is said to be done whenever the given conditions are satisfied:

(i)A force acts on a body.

(ii) There is a Displacement in the body caused by the applied force along the direction of the applied force.

When a force F displaces a body through a distance s in the direction of the applied force, then the work done W is given by the expression:

Work done = Force × Displacement

W = F × s

1 Joule is the energy used to accelerate a body with a mass ofone kilogram using one newton of force over a distance of one meter.The SI unit of energy is joule (J)

Given,

Force, F = 140 N

Distance, s = 15 m

Work done, W =?

W = F × s

= 140 × 15

= 2100 J

The kinetic energy of an object is the energy that it possesses due to its motion. It is defined as the work needed to accelerate a body of a given mass from rest to its stated velocity.

The heavier a thing is, and the faster it moves, the more kinetic energy it has.

If a body of mass m is moving with a velocity v, then its kinetic energy

is given by the expression:

K.E. = mv²

Where, m = Mass of the object

v = velocity of object

Its SI unit is Joule (J).

Given:
velocity of the body, v=5 m/s

kinetic energy of the body, K.E.=25 J

Formula Used:
(1)

putting the value in the equation(2):

We get,

In the first case, the velocity of is doubled

hence, the velocity becomes 5×2 = 10 m/s and mass is 2 kg

putting the values in the equation(1) we get

In the second case, the velocity of is increased three times.

hence, the velocity becomes 5×3 = 15 m/s and mass is 2 kg

putting the values m and v in equation (1)

Therefore, when the velocity of object is increases three times, then its kinetic energy becomes 225 J which is 9 × the kinetic energy when speed is 5 m/s

Power is defined as energy consumed or work done per unit time.

Power = Work done / time

Or,

Energy consumed / time

Its SI unit is watts or joules/ sec

When the work of 1 joule is done in a time of 1 s, the power is said to be one watt.

We know that,

Power =

Power =

= 100

= 100 W

When a machine or person does different amounts of work or uses energy in different intervals of time, the ratio between the total work or energy consumed to the total time is average power.

Average Power =

(a) Work is done because the displacement of swimmer takes place in the direction of applied force.

(b) A donkey is not doing work against gravity. No work is done as the displacement of load does not take place in the direction of applied force.

(c) Work is done, as the displacement takes place in the direction of force.

(d) No work is done, because no displacement takes place.

(e) When an engine pulls a train the angle between distance and force becomes 0° and work will be done.

(f) No work is done in this process as the grains are not moving or covering some distance when being dried in the sun, hence no work is done.

(g) When wind energy is applied to the boat it starts moving in the direction of the force applied by the wind. So the angle between distance and force becomes 0° and some work will be done.

Since, the body returns to a point which is on the same horizontal line through the point of projection, hence no displacement has taken place against the force of gravity, therefore, no work is done by the force due to gravity.

Within the electric cell of the battery the chemical energy changes into electrical energy. The electric

Energy on flowing through the filament of the bulb, first changes into heat energy and then into the light energy

When the Velocity, v = 5 m/s

Mass, m = 20 kg

Then,

K.E. = mv²

= × 20 × (5) 2

= × 20 × 25

= 250 J

When the Velocity, v = 2 m/s

Mass, m = 20 kg

K.E. = mv²

= × 20 × (2) 2

= × 20 × 4

= 40 J

We know that,

Work done by force = Change in kinetic energy

= 250 - 40

= 210 J

The work done is zero. This is because the gravitational force and displacement are perpendicular to each other.

It does not violate the law of conservation of energy. Whatever, is the decrease in Potential energy due to loss of height, same is the increase in the Kinetic energy due to increase in velocity of the body.

The chemical energy of the food changes into heat and then to muscular energy.

On paddling, the muscular energy is converted into kinetic energy of the pedal.

The kinetic energy of pedal is converted into kinetic energy of the bicycle.

The kinetic energy of cycle is converted to kinetic energy of the cyclist.

The mechanical energy is sum of potential energy and kinetic energy ,since potential energy is zero.

Thus ,we can say that the muscular energy of the cyclist is directly converted to the mechanical energy of the cyclist.

Energy transfer does not take place as no displacement takes place in the direction of applied force. The energy spent is used to overcome inertia of rest of the rock.

Given,

Energy consumed = 250 units

= 250 kWh

We know that,

1 kilowatt-hour = 3.6 × 10⁶ J

250 kilowatt-hours = 3.6 × 10⁶ × 250

= 9 × 10⁸ J

Given,

Mass, m = 40 kg

Acceleration due to gravity, g = 10 m/s²

Height, h = 5 m

We know that,

Potential energy = m × g × h

= 40 × 10 × 5

= 2000 J

When the object is fall to its half way down, then its height above the ground =

=2.5 m

Now, Potential energy = m × g × h

= 40 × 10 × 2.55 J

= 1000 J

Now, we know that according to the law of conservation of energy:

Total potential energy = Potential energy at half way down + Kinetic energy at half way down

2000 = 1000 + Kinetic energy at half way down

Kinetic energy at half way down = 2000 – 1000

= 1000 J

When a satellite revolves around the earth in a circular path, its displacement in any short interval of time is along the tangent to the circular path of the satellite. The force of gravity acting on the satellite is along the radius of the earth at that point. Since a tangent is always at right angles to the radius, therefore, the motion of a satellite and force of gravity are at right angles (90 ^o angle) to each other.

Now, work done W = F Cos 90 ^o × s.

Since Cos 90 ^o = 0, therefore,

Work done W = F × 0 × s = 0

Thus, the work done by the force of gravity on a satellite round the earth is zero.

Yes, the given situation is true as we known that F = m × a

Now, when force F = 0,

Then, m × a = 0

Since ‘m’ cannot be zero, therefore, when force F = 0 then acceleration ‘a’ = 0

In such a situation, either the object is in uniform motion in a straight line or it is at rest (not moving). In the first case, there is a displacement of the object without any force acting on it.

The person does not do work because no displacement takes place in the direction of applied force as the force acts in the vertically upward direction.

Given,

Power, P = 1500 W

= KW

= 1.5 kW

Time, t = 10 h

We know that,

Power =

1.5 =

Energy used = 1.5 × 10

= 15 kWh

When the pendulum bob is pulled (say towards left), the energy supplied is stored in it is the form of potential energy on account of its higher position. When the pendulum is released so that it starts moving towards right, then its PE changes into kinetic energy such that in mean position, it has maximum kinetic energy, and Zero potential energy. As the pendulum moves towards extreme right, its kinetic energy changes into potential energy such that at the extreme position, it has maximum potential energy and zero Kinetic energy. When it moves from this extreme position to mean position, its potential energy again changes to kinetic energy.

This illustrates the law of conservation of energy. Eventually, the bob comes to rest, because during each oscillation a part of the energy possessed by it transferred to air and is used in overcoming friction of air . Thus, the energy of the pendulum is dissipated during oscillation in the air.

Initial kinetic energy of the object, K.E. (Initial) = mv²

When the object comes to rest, final kinetic energy of the object, K.E. (Final) = 0

Change in kinetic energy = mv² - 0

= mv²

Work done on the object = Change in its kinetic energy

= mv²

The kinetic energy of the car is zero as it stops. So, the work done that is required to stop the car will be equal to its kinetic energy.

Given,

Mass of car, m = 1500 kg

Velocity of car, v = 60 km/h

We know that, when car is moving the car energy is in form of kinetic energy but to stop the car kinetic energy should be zero.Thus Work done= Kinetic energy


And ,

= 208333.3 J

Therefore, the value of the work required to stop the car is equal to kinetic energy of the car is 208333.3 J

Work is done whenever the given two conditions are satisfied:

(a) A force acts on the body.

(b) There is a displacement of the body by the application of force in or opposite to the direction of force.

(i) In this case, the direction of force acting on the block is perpendicular to the displacement. Therefore, work done by force on the block will be zero.

(ii) In this case, the direction of force acting on the block is in the direction of displacement. Therefore, work done by force on the block will be positive.

(iii) In this case, the direction of force acting on the block is opposite to the direction of displacement. Therefore, work done by force on the block will be negative.

Yes, I agree with her because when the object is at rest, its velocity is zero which in turn means that its acceleration is also zero. Several forces may act on it but they cancel each other. When the object is in motion and moving with a constant velocity, its acceleration is zero. Even in this situation, several forces may act on the objects which balance each other.

Given,

Power of one device = 500 W

Power of four devices = 500 × 4

= 2000 W

= kW

= 2 kW

Time = 10 h

We know that,

Power =

2 kW =

Energy consumed = 2 × 10

= 20 kWh

When an object falls freely towards the ground, its potential energy decreases and kinetic energy increases. As the object touches the ground, all its potential energy gets converted into kinetic energy. As the object hits the hard ground, all its kinetic energy gets converted into heat energy and sound energy. It can also deform the ground depending upon the nature of the ground and the amount of kinetic energy possessed by the object.