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Work, Power, and Simple Machines

Work, Power, and Simple Machines. Book Chapter 14 Work Power Simple Machines. Work.

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Work, Power, and Simple Machines

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  1. Work, Power, andSimple Machines Book Chapter 14 Work Power Simple Machines

  2. Work Work is a force acting through a distance. In order for work to be done on an object, a force must move it. The object MUST move in the direction of the force. If there is no movement, there is no work done on the object. Work is the product of a force applied to an object and the distance through which the force is applied. Work = force x distance

  3. Example Lifting a barbell: If a 100 N barbell is lifted 1 meter, there are 100 J of work done on the barbell by the person. If the barbell is lifted 2 meters high, twice the amount (or 200 J) of work is done. Once the barbell is lifted and held in air, NO work is being done – the object is not moving a distance.

  4. Work falls into two categories: • Work done against another force - An archer stretches the bowstring; she is doing work against the elastic forces of the bow. • Work done to change the speed of an object - It takes work to increase the speed of a car from 10 mph to 20 mph

  5. Joule The SI (metric) unit of work (and of energy) is the Joule (J). 1 Joule = (1 Newton)*(1 meter) = 1 Nm (force) * (distance)

  6. Calculating Work A man picks a 350 N crate up and places it on a 2 meter high shelf. How much work is being done on the crate? There are 700 Joules of work done on the crate.

  7. Power Power is the rate at which work is done. The faster an object can do work, the more power it has. Power and work are not the same thing!

  8. Power Example: A car engine One engine can do 100 J of work in 2 seconds. Its power is 50 J/s, or 50 Watts (W). An engine that is twice as powerful can do 100 J of work (same amount) in 1 second (Half the time). Its power is 100 Watts.

  9. Units for Power The SI unit of power is the Watt (W). The unit we use (British/English) is the horsepower (hp). 1 hp = 0.75 kilowatts (kW) = 750 Watts

  10. James Watt When James Watt built his steam engine in the 1760’s, he wanted to use a unit of power that most people recognized. The horse was the most common source of power during those times, so he decided to compare the work his steam engine could do to the amount of work a horse could do. Watt determined that a good horse could move a 750 N object a distance of about 1 meter in 1 second, which is a power output of 750 Watts. He set 1 horsepower equal to this number of watts.

  11. Calculating Power Acrane can lift a 250 N safe to a height of 5 meters in only 3 seconds. What is the power output of the crane?

  12. Simple Machines A machine is a device that makes work easier by changing the size of the force needed, the direction of a force, or the distance over which the force acts. The six simple machines are the basic components of every tool we use. In each case, we use a simple machine to lessen the amount of work needed to get a desired result.

  13. Work Input of a Machine Because of friction, the work done by a machine is always less than the work done on a machine. The work you exert on a machine is the input force. The distance the input force acts through is the input distance. The work done by the input force acting through the input distance is called the work input.

  14. Work Output of a Machine The force exerted by the machine is the output force. The distance the output force is exerted through is the output distance. The work output of a machine is the output force multiplied by the output distance.

  15. Actual Mechanical Advantage The Mechanical Advantage of a machine is the number of times that the machine increases an input force. To find the Actual Mechanical Advantage (AMA): Return to Home Page

  16. Ideal Mechanical Advantage The ideal mechanical advantage of a machine is the mechanical advantage in the absence of friction. Because friction is always present, the actual mechanical advantage is always less than the ideal mechanical advantage

  17. Efficiency The previous examples were ideal cases – all energy put in turned into work out. This is never the case; the amount of work out is ALWAYS less than the work put in.

  18. Efficiency Example: 100 J of work put in and only 60 J of work done Efficiency = (60 J out) ÷ (100 J in) = 0.6 or 60% The wasted energy usually turns into heat. Brand new gas engine cars only reach 35% efficiency. Return to Home Page

  19. Six Simple Machines There are six types of simple machines: 1. Inclined Plane 2. Wheel and Axle 3. Wedge 4. Screw 5. Pulley 6. Lever

  20. An inclined plane is a slanting surface connecting a lower level to a higher level Inclined Plane

  21. Wheel and Axle A wheel with a rod, called an axle, through its center lifts or moves loads.

  22. Wedge A wedge is an object with at least one slanting side ending in a sharp edge, which cuts material apart.

  23. Screw A screw is an inclined plane wrapped around a pole which holds things together or lifts materials.This simple machine is a modification of the wedge designed to yield a very large mechanical advantage in minimum space. The screw is essentially a transfer device of motion and/or force.

  24. Pulley A pulley is a simple machine that uses grooved wheels and a rope to raise, lower or move a load. A single pulley can change the direction of a force. Multiple pulleys can multiply the amount of input force. The more strands of rope supporting the load, the higher the mechanical advantage of a pulley system.

  25. Pulley

  26. A lever is a stiff bar that rests on a support called a fulcrum which lifts or moves loads.  Lever

  27. Force Up Force Down Lever The lever is used to lift up loads. Work Input = Work Output Since work = (force)(distance), then either force or distance can be changed.

  28. Lever The larger the lever, the less force needed to push down. The fulcrum, or pivot point can be changed to change the length of the lever. The lever arm is measured from the pivot point the place where the force is applied to the lever.

  29. Three Classes of Levers Type 1: Fulcrum between the force and the load Examples: Seesaw, crowbar

  30. Three Classes of Levers Type 2: Load is between the force and the fulcrum Examples: Car jack, hand bottle cap opener

  31. Three Classes of Levers Type 3: Fulcrum is at one end and the load is at the other Examples: Bicep, Construction crane

  32. Compound Machines A compound machine is a combination of two or more simple machines that operate together. Examples: Automobiles, washing machine, clock

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