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Chapter-6 Work, Power, Energy

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1 Chapter-6 Work, Power, Energy
Work and Power Kinetic Energy Potential Energy: Gravitational & Elastic Conservation of Energy Energy Transformations Energy and the Pole Vault

2 Work Work done in moving an object by a force is defined as follows:
Work = Force  Distance. W = F  d. Here the force acts along the distance. Work is a scalar. The SI unit for work is, N.m = joule = J Q: Ramps enable loading easy. Explain why? (SP6, Hwk)

3 Does any force do work? W = F  d E5: a. Work done by the 30 N force?
b. Work done by the 40 N force? c. Work done by the 50 N force? Q: Work done in pushing an immobile wall?

4 Power The rate at which work is done is called the power.
Power is a scalar quantity. The SI unit for power is Watt, W. 1 W = 1 J/s. Before the arrival of machines horses were used to do work. With this originated the unit horsepower, hp. 1 hp = 746 W = 550 ft•lb/s. Why mountain roads are made round and round not straight up?

5 Kinetic Energy Kinetic energy is the energy of motion. The word “kinetic” originated from the Greek word kinetikos, meaning “motion”. If an object of mass, m moves with a velocity v, then the kinetic energy, KE is given by the following equation, Kinetic energy is a scalar quantity. It also has the same unit as work, joule (J). 1 J = 1 kg.m2/s2. Do problem E7 (Hwk).

6 W = F  d = KEf  KEi. Positive work Negative work

7 Gravitational Potential Energy
Gravitational potential energy, GPE is the energy stored in an object as a result of its height. It can be calculated using weight, which is mass times gravity, and height. It is given by the following equation, Gravitational potential energy is a scalar quantity. The SI unit for it is also joule, J.

8 Elastic Potential energy
Elastic potential energy is the energy stored in elastic materials as the result of their stretching or compressing. How shock absorbers work?

9 Conservation of Energy
The swing of the pendulum demonstrates the principle of conservation of energy. Mechanical energy = KE + PE In the absence of friction and air drag, the total mechanical energy of a system remains a constant.

10 How is energy analysis like accounting?
Try SP5, Hwk.

11 Energy: Forms and Transformations

12 Energy Transformations in Pole Vault (p114, textbook)
Forms of Energy: Energy Transformations:

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