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Work & Power Simple & Compound Machines Mechanical & Ideal Mechanical Advantage Efficiency By: Deborah Wang modified by: S. Ingle.

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Presentation on theme: "Work & Power Simple & Compound Machines Mechanical & Ideal Mechanical Advantage Efficiency By: Deborah Wang modified by: S. Ingle."— Presentation transcript:

1 Work & Power Simple & Compound Machines Mechanical & Ideal Mechanical Advantage Efficiency By: Deborah Wang modified by: S. Ingle

2 Work Concepts 4 Work (W) ~ product of the force exerted on an object and distance the object moves in the direction of the force. –W is transfer of energy by mechanical means. –W is done on an object only if it moves in the direction of the force. –Only the component of the force in the direction of the motion does work.

3 Work Formulas Work = Force x displacement W = Fd 1 joule (J) = 1 Newton * meter (N * m) if force is exerted at an angle to direction of motion, W = (Fcos  )d or W = Fd cos  F d F  d

4 Power 4 Power (P) ~ rate at which work is done or rate at which energy is transferred. Measured in watts. –Watt (W) ~ one joule of energy transferred in one second. Power = Work / time 1 watt = 1 joule / second (J/s)

5 Simple Machines 4 Machine ~ makes work easier either by changing the magnitude or the direction of a force, but can not increase the amount of work done. 1. lever ~ bottle opener, seesaw, crowbar 2. pulley ~ rope on flagpole, block & tackle 3. wheel-an-axle ~ wheel barrow, bike pedals 4. inclined plane ~ wheelchair ramp 5. wedge ~ knife, axe, chisel 6. screw ~ bottle cap, nut, bolt

6 Mechanical Energy 4 Effort force (F e ) ~ force you exert on a machine. 4 Resistance force (F r )force exerted by the machine. W in = F e d eWork input W out = F r d rWork output

7 Ideal Machines 4 Ideal machines exist only in a frictionless, air resistance-less world. 4 No energy or work is lost to the system through outside forces 4 For ideal machines: Work input = Work out put so: F e d e = F r d r

8 Mechanical Advantage 4 Mechanical Advantage (MA) ~ ratio of resistance force to effort force. MA = F r / F e 4 Ideal Mechanical Advantage (IMA) ~ ratio of effort distance to resistance distance. IMA = d e / d r

9 Efficiency 4 Efficiency ~ ratio of work output to work input expressed in percent. efficiency = (W out / W in ) * 100% or efficiency = (MA / IMA) * 100%

10 Compound Machines 4 Compound machine ~ consists of two or more simple machines linked so that the resistance force of one machine become the effort force of the second. –Ex. The pedal and gear of a bicycle. 4 To calculate the efficiency of a compound machine you simply multiply the efficiencies of the simple machines that make it together.

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