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Section B1.4 Work and Energy.

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1 Section B1.4 Work and Energy

2 Types of Energy Mechanical Energy – is the energy which is possessed by an object due to its motion or due to its position; mechanical energy can either be kinetic energy or potential energy Kinetic Energy – the energy of motion Potential Energy – stored energy; energy having the potential for doing work

3 Work An object which possesses mechanical energy is able to do work.
In fact, mechanical energy is often defined as the ability to do work. Work – is the transfer of mechanical energy from one object to another For example, if you stretch or compress a spring, you do work on the spring and transfer energy to the spring.

4 Work The amount of work done on an object can be calculated by multiplying the force exerted on the object by the distance which the object moves. Force – push or pull on an object W=F x Δd

5 Work W=F x Δd Where: W is the work done in Joules (J)
F is the force in Newtons (N) Δd is the distance in meters (m)

6 _____________________________________________
Work ***In order for work to be done the direction of the force and the direction of the motion must be parallel, or along the same line. _____________________________________________

7 Example Problem #1 Example: You exert a force of 25 N on your textbook while lifting it a height of 1.4 m to put it on a shelf. How much work did you do on your textbook?

8 Example Problem #2 A weightlifter lifts a barbell a vertical distance of 2.40m. If the average force required to lift the barbell is 2.00 x 103N, how much work is done by the weightlifter?

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