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Regents Physics Mr. Rockensies. Energy, Work & Power. Introduction to Energy. How does energy manifest itself physically?. What is energy?. Energy is the ability to do Work . Energy exists in several different forms. Almost all energy on Earth can be traced back to the Sun. Examples:
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Regents Physics Mr. Rockensies Energy, Work & Power
Introduction to Energy How does energy manifest itself physically?
What is energy? Energy is the ability to do Work. Energy exists in several different forms. Almost all energy on Earth can be traced back to the Sun. Examples: Mechanical, Thermal (Heat), Chemical, Nuclear, Electromagnetic, Kinetic, Potential
What is Work? Work is a measure of the amount of energy used to move an object. Mathematically: Work = Force • displacement Because we are multiplying two vectors, we end up with a scalar quantity – Work is a scalar quantity. Work is only done when the Force and the displacement are in the SAME direction.
Unit for work: Work = F • d = Newton•m To simplify this, we use Joules (J). 1 J = 1 N•m All energy quantities will be measured in Joules.
Work and Friction When friction is present, energy in a system is lost because of it. When two objects come into contact and move past each other, energy is given off in the form of HEAT – this is due to FRICTION.
What is Power? Power is the rate at which energy is used, transformed, or transferred. Power = Work/time AND Power = Velocity • Force Power = Force • Distance time Units: Watts = Joules/second = N •m = kg • m2 s s3 We measure Power in Watts to simplify the units
What is horsepower then? A measure of the amount of energy expended by the average horse over a given period of time. One horsepower is equal to 746 Watts, but depending on how you are using horsepower, it is up for debate.
Law of Conservation of Energy Energy cannot be created or destroyed; it can only change forms.
Conservation in Free Fall m initial Ei = Ef PEi = PEf + Kef mghi = mghf + 1/2mvf2 ghi – ghf = v2/2 Δhi If an object starts from some initial height and enters free fall, its initial Potential Energy will equal the sum of its final Potential Energy and Kinetic Energy m final vf Δhf
Energy is a scalar quantity Because energy is a scalar , direction doesn’t matter, and this works for curved motion as well m hi vf m hf
Hill slides and roller coasters are the same EA = EB = EC PEA + KEA = PEB + KEB = … A C hA hC B
Pendulum Etop = Ebottom PE = KE vi = 0 Kei = 0 All PE vf is max KE is max No PE
Springs Ei = Ef Pes = Kecart 1/2kx2 = 1/2mv2 PE = 1/2kx2 KE = 1/2mv2
Systems with Friction Initial Mechanical energy (PE + KE) becomes final mechanical energy plus some internal energy, converted by friction. (PE + KE + Q) Q = internal energy, usually heat, caused by friction height reached with no friction height reached with friction
Summary In a closed isolated system, what happens to the gravitational potential energy of an object as it falls? the kinetic energy? the total energy? Does the amount of energy an object has change if the object changes direction? How does Potential Energy change if a spring is compressed more? When is Kinetic Energy the greatest for a swinging pendulum?