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ENERGY

ENERGY. Work. Work Formula. Work = Force x Distance W =Fd Factor one: there must be a force applied Factor two: there must be movement in the direction of the force. Types of Work. 1. The work done to overcome a force (lifting something to overcome the force of gravity…)

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ENERGY

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  1. ENERGY Work

  2. Work Formula • Work = Force x Distance W=Fd • Factor one: there must be a force applied • Factor two: there must be movement in the direction of the force

  3. Types of Work • 1. The work done to overcome a force (lifting something to overcome the force of gravity…) • 2. Changing something’s velocity (working against its inertia to speed up or slow down).

  4. Units • Work – joules (J) • a joule is a N•m or • 1 J is the amount of work done by 1 N of force for 1 m of distance. • For large work values we use kJ (kilojoules, or 1000 joules).

  5. Power • When we look at time we use power. • The unit for Power is the Watt (W) • 1 watt is the power expended when 1 Joule of work is done in 1 second of time • One kW (kilowatt) is 1000 watts. One MW (megawatt) is one million watts

  6. Problems - 1 Adam, a very large man of mass 130 kg, stands on a pogo stick. How much work is done as Adam compresses the spring of the pogo stick 0.50 m?

  7. Problem - 2 After finishing her physics homework, Kayla pulls her 50.0 kg body out of the living room and climbs up the 5.0-m-high flight of stairs to her bedroom. How much work does Kayla do in ascending the stairs?

  8. Problem - 3 • In the previous example, Kayla slowly ascends the stairs, taking 10.0 seconds to go from bottom to top. The next evening, in a rush to catch her favorite TV show, she runs up the stairs in 3.0 seconds. • On which night does Kayla do more work? • On which night does Kayla generate more power?

  9. PRACTICEPROBLEMS

  10. Energy • Energy enables work to be done • Mechanical energy is energy that comes from the position of something or the movement of something and it can be either potential energy or kinetic energy

  11. Potential Energy • Potential energy is energy due to position • Chemical potential energy is found in food, fossil fuels, and electric batteries. • Positional potential energy can be found in a compressed spring, a the string on a bow ready to shoot an arrow, etc. • PE in this case equals the force times the distance used to store the energy (how hard you pulled on the string times how far back you pulled it. • Gravitational potential energy comes from an objects distance from the surface of the earth. • Gravitational potential energy can be found by GPE = mgh (mass times acceleration due to gravity times height) • Gravitational potential energy only depends on height not on path

  12. Kinetic Energy • Kinetic energy is energy of motion. • KE = ½ mv² where m is mass and v is velocity or speed • Kinetic energy is also equal to the amount of work done to give the object the velocity that it has • So…net force x distance = kinetic energy, which can also be written as: Fd = ½ mv² • Note that the speed of the object is squared; this means that if you double the objects speed you are quadrupling the kinetic energy. Also an object moving twice as fast takes four times as much work to stop. • The work energy theorem states that whenever work is done energy changes. This can be represented by the following formula: Work = E

  13. PRACTICEPROBLEMS

  14. Conservation of Energy • The law of conservation of energy states: Energy cannot be created or destroyed. It can be transformed from one form into another, but the total amount of energy never changes. • In order to see this we will need to look at entire systems, not single objects! • One of the classic PHYSICS examples of this is the pendulum.

  15. Pendulum • In this image you can see that when the pendulum is all the way up, it has large PE, when it has fallen it has small PE, and then when it rises back up it has large PE again

  16. More Pendulum • Here you can see that when the pendulum is up it has 10 J of PE and 0 KE and when it is down it has 0 J of PE and 10 J of KE • Disregarding friction,energy changes between the two types but is not lost.

  17. Roller Coaster • The rollercoaster is a more complicated example, however you can see that at the top there is 40,000 J of PE and 0 KE, and at the bottom there is 0 PE and 40,000 J KE.

  18. The Energy Ramp • In the energy ramp we can demonstrate the fact that the path an object takes does not determine its energy.

  19. Machines • A machine is a device used to multiply forces or simply change the direction of forces. Some common simple machines are the: • Lever • Pulley • Inclined plane • Wedge • Screw • Wheel & axle

  20. The Lever • The lever – we work on one end of the lever the other end works on the load. • Neglecting friction, work input equals work output. So (force x distance) input = (force x distance) output. • Fulcrum is middle point of lever • Mechanical Advantage is ratio of input force to output force or input distance traveled to output distance traveled. • http://www.cosi.org/files/Flash/simpMach/sm1.swf

  21. The Pulley • The Pulley – a pulley is a type of machine that can be used to change the direction of a force. • The mechanical advantage of a simple pulley system is the same as the number of strands of rope that support the load. Note: Not all strands on a pulley are necessarily supporting!!! http://www.cosi.org/files/Flash/simpMach/sm1.swf

  22. The Ramp • The mechanical advantage of a ramp can be found either by the ratio of input force to output force or by the ratio of distance traveled along the ramp to height risen.

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