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Work, Energy, & Power. Work. In science, commonly used terms may have slightly different definitions from normal usage. The quantity work , is a perfect example of this. Work Definition. Work = Force x Distance W = Fd Thus, work depends on force applied, and distance moved.
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Work In science, commonly used terms may have slightly different definitions from normal usage. The quantity work, is a perfect example of this.
Work Definition Work = Force x Distance W = Fd Thus, work depends on force applied, and distance moved.
Physics concept of WORK • WORK is done only when a constant force applied on an object, causes the object to move in the same direction as the force applied.
Example of Work? The weightlifter holding the bar in a stationary position does NO work since distance equals zero.
Units Since W = F d Work is measured in N• m One N• m is also called 1 Joule.
More Work? Q: If one person lifts a 100 kg mass a distance of 1m up in 3 seconds, and another person does the same task in only 1 second, who does more work? A: Neither. Work is not dependent of time. However, power is dependent on time.
Examples of WORK • You are helping to push your mother’s heavy shopping cart with a force of 50 N for 200 m. What is amount of work done? Work done, W = F x d = 50 N x 200 m = 10,000 J (or Nm) or 10 kJ (kilo-Joules)
Examples of WORK: • Jack put on his bag-pack of weight 120 N. He then starts running on level ground for 100 m before he started to climb up a ladder up a height of 10 m. How much work was done? From Physics point of view, no work is done on pack at level ground. Reason: Lift is perpendicular to movement. Work is done on pack only when Jack climbs up the ladder. Work done, W = F x d = 120N x 10m = 1200 J or 1.2 kJ
Energy When you do work on an object and lift it upwards, you change the state of the object. Since the object is higher now, it could fall and do work for you. Thus, the work you did increased the energy of the object.
Energy is the ability to cause change and perform work. Work involves movement but energy does not require movement. The unit for energy is a JOULE or Nm (Newton-meter)
Potential Energy:stored energy. There are many ways that energy can be stored and then released. It’s a lot like saving money in the bank so that it can be used later.
Chemical Potential Energy The chemical bonds between atoms can store energy. This can be released when the bonds are broken in chemical reactions.
Gravitational Potential Energy When an object is lifted to a particular height, the stored energy due to its elevated position increases. A dam is a good example of this.
Gravitational potential energy, PE, will be the main type considered. PEgrav = weight x height PEgrav = mg h Remember that you only increase PE when you work against gravity. Moving an object horizontally doesn’t change its PE.
PE Example: A crane lifts a steel beam with a mass of 2500 kg to a height of 20 m. How much potential energy was given to the beam?
Potential Energy Example • The crane is lifting against gravity, so we find the gravitational potential energy. • h= 20 m; g= 10 m/s2; m = 2500kg • PEgrav= m g h • (2500kg) x (10 m/s2)x (20 m) • 500000 J
Reference Point, Base Level When measuring an “h” to calculate PE, its important to know where you are measuring from. Any point can be used as a base level because the energy amount you calculate will be relative. However, you must be consistent.
Elastic Potential Energy If you compress a spring, or stretch a rubber band, the work you do can be returned later when the spring or rubber band bounces back.
Kinetic Energy Kinetic Energy, KE: energy of motion KE = ½ m v2 m = mass v = velocity Any object in motion has kinetic energy.
BOOM Objects with a small mass can have high kinetic energy if their velocity is high. (Example: a cannonball)
Objects moving at slow speed can have great kinetic energy if their mass is great. (Example: a freighter)
KE Example: m=80 kg; v = 10m/s; d = 100 m KE = 1/2 mv2 KE = 1/2 (80kg) (10m/s)2 KE = 4000 kgm2/s2 or 4000 J Ex: A 80 kg sprinter may average about 10 m/s during a 100m dash. What would his KE be?
Power Power = Work / time P = W / t = F x d / t Power is a measure of how quickly work is done.
Units: Since work has units of Joules, power must be in units of Joules per second. 1 J/s = 1 Watt, W James Watt invented the steam engine.
A watt is not exclusively used for electrical measurements, although that is common. Since 1 watt is relatively small, kilowatts 103 W or megawatts 106 W are often used.
5m high Power Example: Ex: A 50 kg boy wants to escape the monster beneath his steps. He climbs the 5m high steps in 2.0 seconds. How much power did he generate during his run? m= 50kg h= 5m t= 2s g = 9.8m/s2
P = W / t = Fd / t (notice the force needed is the boy’s weight) = (mg)d / t = (50kg) ( 10m/s2) ( 5.0 m) / (2.0s) = 1250 J/s = 1250 Watts = 1.250 kilowatts
Work Energy Theorem Work = ΔE Work is equivalent to the change in energy. Work and energy both have the same unit, Joule.
Ex: You could do work by pushing an object to slide it across the floor. This work you do goes into increasing the KE of the object.
Ex: You lift an object and do work. This work goes into increasing the PE of the object.
The archer does work to draw the bow back. This is temporarily stored as PE in the bow. When the arrow is released, it is changed to KE in the form of the flying arrow.
Conservation of Energy: Energy cannot be created or destroyed; it may be transformed from one form into another,but the total amount of energy never changes.
Often, it may seem like energy is lost, but it merely is transformed into another type of KE or PE. Just look closely and consider where energy may be transferred.
Notice that the total amount of energy remains constant. As he falls, PE is changed to KE. At the top, the diver has all PE Before he hits, all the PE has changed to KE.
#1 - Tot E = all PE #3 - Tot E = mostly PE + some KE Total Mechanical Energy = KE + PE PE = mgh KE = 1/2 mv2 #4 - Tot E = all KE #2 - Tot E = mostly KE + some PE