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CONSERVATION OF ENERGY

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Presentation on theme: "CONSERVATION OF ENERGY"— Presentation transcript:

1 CONSERVATION OF ENERGY

2 Conservative Force A conservative force converts potential energy to other forms of mechanical energy when it does work. In other words, a conservative force does not change the mechanical energy of a system Remember that mechanical energy is potential energy + kinetic energy

3 NonConservative Force
So, what would be a nonconservative force??? Friction is most common example (air resistance is a form of friction) Work done by friction becomes microscopic internal energy in the object, raising its temperature The internal energy cannot be recovered and turned back into kinetic energy

4 Thermal Energy When is thermal energy a desirable outcome and when is is undesirable?

5 Law of Conservation of Energy
Energy cannot be created or destoyed, only changed from one form to another Ei = Ef Ki + Ugi + Usi = Kf + Ugf + Usf + HE ½ mv2 i + mghi + ½ kx2i = ½ mv2 f + mghf + ½ kx2f + HE

6 Example

7 Example A 65 kg snowboarder starts at rest, travels down a hill into a gulley and back up the other side as shown. Find his speed at top of the 2nd hill.

8 Example A trampoline dunk artist is bounces to a maximum vertical height of 4.8 m before launching himself towards the hoop. At the top of his arc he is 3.2 m above the ground. How fast is he traveling at this point?

9 Example A 5.0 kg block of wood is pushed down a ramp with a velocity of 6.0 m/s. The ramp is 1.5 m tall and 3.5 m long. At the bottom of the ramp it is traveling at 7.5 m/s. How much thermal energy is generated due to friction? Determine the force of friction and the coefficient of friction.

10 Work-Energy Theorem Net work = change in kinetic energy.
This means that the net work on a system causes a change in speed of the system

11 Work-Energy Theorem If you know how much energy you want a system or object to have, then you can calculate how much work you need to perform to get it there. Conversely, if you know how much energy a system has, you can calculate how much work that energy can perform.  This has literally MILLIONS of real-life examples: The energy of wind movement performs work when it turns a Wind Turbine The chemical energy in gasoline performs work on a piston, which in turn performs work on a vehicle to create kinetic energy. Work is performed on air as it enters a Jet Engine to speed up the air, which results in higher kinetic energy of the air particles, which pushes the airplane Stirring a pot of water performs work in the form of heat transfer, which results in a higher temperature in the water (higher temp = higher energy) When you throw a water balloon at someone’s face, their face performs work on the balloon, which then increases in pressure (higher pressure = higher energy) until it pops.

12 Example A 60 kg sprinter exerts a net force of 260 N over a distance of 35 m. What is his change in kinetic energy? If started at rest, what is speed at finish?

13 Example A student pushes a 25 kg crate which is initially at rest with a force of 160 N over a distance of 15 m. If there is 75 N of friction, what is the final speed of the crate?


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