Work And Energy

Work done = Force × Displacement

Given

Force = 15 N

Displacement = 5 m

Work done = 15×5 = 75 J

The work done is 75 Joule

Power is defined as the rate of doing work. It is the ratio of the work done (W) and the time taken (t).

Power (P) =

The S.I unit of the power is Watt (W) in honour of the physicist James Watt.

The potential energy due to gravitation is given by

P.E = mgh

Where, m = Mass,

G = acceleration due to gravity,

H = height,

Given

Mass = 5 Kg,

P.E = 490 J,

G = 9.8m/s².

H =?,

490 = 5×9.8×h

⇒

Hence the body should be raised to 10 m

SI unit of work is Joule. It is the scalar quantity. It is defined as the Work done by force of 1 N to move an object by 1 m.

SI unit of Power is Watt denoted by W.

1 watt is the power of an agent which does the work at the rate of 1 joule per second.

1W = 1 j/s

Given

Mass of object (m) = 10 Kg.

Height (h) = 6 m.

Acceleration due to gravity (g) = 9.8m/s²

Potential Energy of Object = mgh

= 10×9.8×6 = 98×6

= 588 J

Energy possessed by an object is 588 Joule.

Work done = Kinetic Energy possessed by a body.

Kinetic Energy =

Given

Mass (m) = 80 Kg;

Velocity (v) = 10 m/s;

Kinetic Energy =

⇒ Kinetic Energy =

Hence the work done is 4000 J.

Kinetic Energy⇒ The energy possessed by an object in motion is called as the kinetic Energy. It is given by

Kinetic Energy =

Where m = mass of body;

V = velocity of body.

Example = Earth revolving around the sun, you walking down the street etc.

Potential Energy⇒ When the object is at rest the energy possessed by an object is called as the potential energy.

Potential Energy = mgh

Where m = mass of body,

H = height at which body is kept

G = acceleration due to gravity = 9.8 m/s².

Example = A ball kept at a certain height.

The figure below illustrates the Kinetic and potential energy in more detail.

Given

Mass of Body (m) = 50 Kg,

Time (t) = 9s,

Height of each step = 15 cm,

Acceleration due to gravity (g) = 10 m/s².

Now

Weight = mg = 50×10 = 500N

Height of staircase =

(∵ 1 m = 100 cm)

Power =

⇒ Power =

Power = 375 Watt

Given

Power = 60 W =

(∵ 1Kw = 1000 W).

Time (t) = 6 hours.

Now

Power =

⇒ Energy Consumed = Power × Time taken

= 0.06 × 6 = 0.36kWh

Hence 0.36 unit of electricity is consumed by a bulb in one day.

We know that

Kinetic Energy =

P = Momentum.

K_i = Initial Kinetic Energy

P_i = Initial Momentum

⇒

K_f = Final Kinetic Energy

P_f = Final Momentum

⇒

Given K_f = 4 K_i

⇒

⇒

⇒

Hence the Momentum of body will be doubled when the kinetic energy is increased four times.

Commercial unit of Energy is Kilo Watt per hour denoted by kWh.

1kWh = 3600000 Joules

Energy Consumed in 1 hour

60 W = 60 j/s

1 hour = 60×60 seconds

⇒ Energy consumed in 1 hour = 60 ×60×60 = 216000 j

216000 Joules of energy is consumed in 1 hour.

(a) The rate of doing work is called as the power. The SI unit of power is Watt denoted by W.

1 Watt is the power of appliances that consume the energy at the rate of 1 joule per second.

(b) Given

Mass of brick = 2.5 kg

⇒ Weight = mg = 2.5×10 = 25 N

Weight of 10 bricks = 25×10 = 250 N

Height (h) = 20 m

Time (t) = 50 s

Power =

⇒ Power =

Power spent in carrying bricks is 100 Watt.

Given

Power = 40W

Time = 8 hours

Now

Power =

⇒

⇒ Energy =

Energy consumed by 2 bulbs in 1 week = 320×2×7 = 4480 Wh = 4.48 kW

(∵ 1kWh = 1000Wh)

Total units = 4.48 units

Now

Cost of 1 unit = Rs 3

Total cost = 4.48 ×3 = Rs13.44

Total cost for 1 week is Rs 13.44

Given

Mass of Body (m) = 50 Kg,

Time (t) = 45s,

Height of each step = 15 cm,

Acceleration due to gravity (g) = 10 m/s².

Now

Weight = mg = 50×10 = 500N

Height of staircase =

(∵ 1 m = 100 cm)

Power =

⇒ Power =

Power = 25 Watt

Power used in climbing stairs = 25 W

When the bulb is connected to the battery the chemical energy of the battery is converted into the electrical energy. When bulb receives this electrical energy it converts it into light and heat energy. The figure below shows the energy transformation in more descriptive way.

Chemical Energy → Electrical Energy → Light Energy + Heat Energy

Given

Mass of car = 500 Kg

Initial speed = 36 km/h = 10m/s

(∵ 1 km/h = 5/18 m/s)

Now

Work done = Change in Kinetic Energy.

= Final kinetic Energy – Initial Kinetic Energy.

=

= (Final velocity = 0, because the car is at rest).

= .

The magnitude of work required is 25000 Joule.

(i) At the extreme position of the swing she will have potential energy. At the mean position of the swing, she will have kinetic energy. These energies keep interchanging during the motion of the swing.

The kinetic energy depends on the velocity of the mass so it will be greatest at the bottom and, zero at the top. The gravitational potential energy depends on the height. It will be maximum at the top of the swing and minimum at the bottom.

(ii) On pushing ground harder with the feet, force is applied on the swing. As a result of it the swing starts moving with the greater speed and the speed of the swing increases.

(iii) Rashmi asked her brother pankaj that why on pushing the ground with the feet the speed of the swing increases. She asked so because she is curious to know that why the speed of the oscillations was increasing on pushing the ground when at the lowest position.

(a) The energy conversion which takes place is the change of the potential energy of the Rano while standing on the swing into the kinetic energy of the swing due to which the speed of the swing increases.

(b) The muscular energy of Rano is not converted into the specific form of the energy but it is imparted as the additional kinetic energy to the swing which makes the swing fast.

(c) Roma is adventurous and courageous while Rano is timid and fearful. Also, Roma is risk-taking and Rano is very careful.