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POWER AND EFFICIENCY PLUS SOME REVIEW OF WORK AND ENERGY.

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Presentation on theme: "POWER AND EFFICIENCY PLUS SOME REVIEW OF WORK AND ENERGY."— Presentation transcript:

1 POWER AND EFFICIENCY PLUS SOME REVIEW OF WORK AND ENERGY

2 REMINDERS ABOUT WORK AND ENERGY 1 joule is equivalent to the energy required for a force of exactly 1 newton to act through a distance of exactly 1 metre. Principle of conservation of energy: energy cannot be created nor destroyed; it can only be transformed from one type to another. Work is completed when the applied force acts in a direction that is in line with the direction of motion. Work is the transfer of energy through motion.

3 QUESTION 5.18A WATER SLIDE I a) Paul b) Kathleen c) both the same Paul and Kathleen start from rest at the same time on frictionless water slides with different shapes. At the bottom, whose velocity is greater?

4 QUESTION 5.18A WATER SLIDE I a) Paul b) Kathleen c) both the same Paul and Kathleen start from rest at the same time on frictionless water slides with different shapes. At the bottom, whose velocity is greater? Conservation of Energy: E i = mgH = E f = mv 2 therefore: gH = v 2 Because they both start from the same height, they have the same velocity at the bottom.

5 QUESTION 5.18B WATER SLIDE II Paul and Kathleen start from rest at the same time on frictionless water slides with different shapes. Who makes it to the bottom first? a) Paul b) Kathleen c) both the same

6 QUESTION 5.18B WATER SLIDE II Paul and Kathleen start from rest at the same time on frictionless water slides with different shapes. Who makes it to the bottom first? Even though they both have the same final velocity, Kathleen is at a lower height than Paul for most of her ride. Thus, she always has a larger velocity during her ride and therefore arrives earlier! a) Paul b) Kathleen c) both the same

7 QUESTION 5.19 CART ON A HILL A cart starting from rest rolls down a hill and at the bottom has a speed of 4 m/s. If the cart were given an initial push, so its initial speed at the top of the hill was 3 m/s, what would be its speed at the bottom? a) 4 m/s b) 5 m/s c) 6 m/s d) 7 m/s e) 25 m/s

8 QUESTION 5.19 CART ON A HILL When starting from rest, the cart’s PE is changed into KE:  PE =  KE = m(4) 2 A cart starting from rest rolls down a hill and at the bottom has a speed of 4 m/s. If the cart were given an initial push, so its initial speed at the top of the hill was 3 m/s, what would be its speed at the bottom? a) 4 m/s b) 5 m/s c) 6 m/s d) 7 m/s e) 25 m/s When starting from 3 m/s, the final KE is: KE f = KE i +  KE = m(3) 2 + m(4) 2 = m(25) = m(5) 2 Speed is not the same as kinetic energy

9 You see a leaf falling to the ground with constant speed. When you first notice it, the leaf has initial total energy PE i + KE i. You watch the leaf until just before it hits the ground, at which point it has final total energy PE f + KE f. How do these total energies compare? a) PE i + KE i > PE f + KE f b) PE i + KE i = PE f + KE f c) PE i + KE i < PE f + KE f d) impossible to tell from the information provided QUESTION 5.20A FALLING LEAVES

10 You see a leaf falling to the ground with constant speed. When you first notice it, the leaf has initial total energy PE i + KE i. You watch the leaf until just before it hits the ground, at which point it has final total energy PE f + KE f. How do these total energies compare? a) PE i + KE i > PE f + KE f b) PE i + KE i = PE f + KE f c) PE i + KE i < PE f + KE f d) impossible to tell from the information provided As the leaf falls, air resistance exerts a force on it opposite to its direction of motion. This force does negative work, which prevents the leaf from accelerating. This frictional force is a nonconservative force, so the leaf loses energy as it falls, and its final total energy is less than its initial total energy. QUESTION 5.20A FALLING LEAVES Follow-up: What happens to leaf’s KE as it falls? What net work is done?

11 QUESTION 5.21A TIME FOR WORK I a) Mike b) Joe c) both did the same work Mike applied 10 N of force over 3 m in 10 seconds. Joe applied the same force over the same distance in 1 minute. Who did more work?

12 Both exerted the same force over the same displacement. Therefore, both did the same amount of work. Time does not matter for determining the work done. QUESTION 5.21A TIME FOR WORK I a) Mike b) Joe c) both did the same work Mike applied 10 N of force over 3 m in 10 seconds. Joe applied the same force over the same distance in 1 minute. Who did more work?

13 POWER

14

15 COMMON NON-METRIC POWER UNITS 1 Horsepower (hp) = 745.7 W = 745.7 J·s -1 Fun Fact: By definition, 1 horsepower is the power required to lift a weight of 550 pounds to a height of 1 foot in the time of 1 second.

16 EFFICIENCY A measure of the amount of useful energy that can be taken out of a system (or, the work done by the system) compared with the amount of energy put into the system (work done TO the system) Typically reported as a percentage (%)

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