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Transcript
Conservation of Energy By R. Christoffel Conservation of Energy A block of mass 2.5 kg is sliding across a smooth, level surface at 3.0 m/s when it strikes a stationary spring bumper, fixed at one at one end as shown, whose force constant is 3.60 x 102 N/m. By what amount does the block compress the spring? Conservation of Energy The law of conservation of energy states: the sum of the initial energies is equal to the sum of the final energies. Another way you can think about this is that if you add up all your sources of energy; kinetic, potential, spring and work, they should equal the amount energies in the uses category. Energies can simply change form but their sum must always add up. Also, energies cannot simply be created nor destroyed. As a formula, we say this: Σ Ei = Σ Ef Conservation of Energy Energy Description Energy Description Kinetic Ek=½mv2 Kinetic energy is the energy of motion. If a body is moving, it has kinetic energy. The energy it possesses is directly proportional to its mass and it’s velocity squared. Spring Es=½kx2 Elastic spring energy results from energy that is stored in some sort of elastic device. This could be a metal spring or rubber band or some other such elastic device. Ek=kinetic energy m=mass v=velocity or speed Potential Ep=mgh Ep=potential energy m=mass g=acceleration of gravity Es=spring energy k=spring constant x=compression or extension of spring If a body is lifted above its Work lowest possible position then W=F d it has gravitational potential W=work F=force applied energy. If dropped, it has the d=distance travelled in the potential to do some damage direction of motion. or hurt something or provide energy for something. Work could be done as an energy input where a motor or force is adding energy to the system. As an output, energy might need to be accounted for as a use such as friction. Conservation of Energy Energy Questions to ask Before After Kinetic Is it moving? ✔ ✗ Potential Does its height change? ✗ ✗ Spring Is there a spring involved? ✗ ✔ Work Is something doing work on the object? ✗ ✗ Conservation of Energy List all the things you know and the things you are supposed to find. m = 2.5 kg vi = 3.0 m/s g = 9.81 m/s2 k = 3.6 x 102 N/m μ=0 θincl = 0° xf = ? Conservation of Energy Σ Ei = Σ Ef Eki + Epi + Esi + Wi = Ekf + Epf + Esf + Wf This is on a level surface We can now expand each so there is no gravitationalof the the two energy terms rewrite this long withWe their appropriate potential energy equation and only include equations. those energies that will There isn’t a spring present actually have relevance in so no spring energy exists. this problem. We now substitute all of the Eki = Esf ½mvi2 = ½kxf2 No work is being values in from the given information. put into this system while it is moving. f amount that the 2spring xfThe = √mv is compressed is the i x/k The object stops moving at the end and therefore has no kinetic energy. The height has not changed so there is no change in gravitational potential energy. value here. We must x = √(2.5kg)(3.0m/s) /(3.60 x 10 N/m) xf = 0.25 m simply solve for2xf No coefficient of friction or 2 force of friction is mentioned, therefore the energy need not be included. Conservation of Energy Reference: Martindale, David G., Heath, Robert W., Eastman, Philip C., (1992), Fundamentals of Physics: A Combined Edition. Canada, Heath Canada Ltd.
