Work and Energy Work Kinetic Energy Work – Energy Theorem Gravitational Potential Energy Mechanical Energy Conservation of Energy
Starter The angle between two vectors is found by placing their tails together and picking the smallest angle between them. For example, the angle between B and D is 45 degrees. Find the angle between: A and B B and C 3. C and D 4. A and E 1. 180o 2. 90o 3. 135o 4. 90o
Practice - Work
Work = Frcos(q) Units = Joules F = magnitude of the force r = magnitude of the displacement q = the angle between F and r
Example Work = Frcos(q) = 100(2)cos30 = 173J A 100N force acts on a box at 30 degrees with respect to the horizon, moving the box 2m to the right. How much work did the force do? F = 100N r = 2m q = 30 degrees Work = Frcos(q) = 100(2)cos30 = 173J
Example Find the total work done on this box as it moves 3m to the right. Work done by P: W = 200(3)cos(0) = 600J Work done by N: W = Nrcos(90) = 0 Work done by f : W = 80(3) cos(180) = -240J Work done by Weight : W = 100(3)cos(90) = 0 Total Work = 600 + 0 + (-240) + 0 = 360J
Kinetic Energy – Energy of Motion KE = (1/2)mv2 Example: Find the kinetic energy of a 20kg mass moving at 10 m/s. KE = (1/2)mv2 = (1/2)(20)(10)2 = 1000J Example: If you double your velocity, what happens to the KE? KE (new) = (1/2)m(2v)2 = 4KE(original)
Work Energy Theorem Work Total = ½mvf2 – ½mvi2 or Work Total = DKE
Example If this box starts at rest, what is its velocity after it moves 3m? Previously we saw that the total work was 360J. Work Total = (1/2)mvf2 – (1/2)mvi2 360 = (1/2)(10)vf2 vf = 8.48 m/s
Example If a mass is dropped from rest 20m above the ground, how fast is it moving when it hits the ground? Work Total = (1/2)mvf2 – (1/2)mvi2 = (1/2)mvf2 Work = Frcosq = mgrcos(0) = mgr = (1/2)mvf2 vf = [ 2gr ] ½ = [ 2(9.8)(20) ] ½ = 19.8 m/s
Starter 75J 105J 315J None of these. A golf ball moving at 40 m/s has a kinetic energy of 35 Joules. What is its kinetic energy if it instead moves at 120 m/s? 75J 105J 315J None of these.
Starter #2 At the top of her swing, 2 meters from the ground, a child has a potential energy of 500 Joules. When she is 1m from the ground, her kinetic energy is 500J 300J 250J 150J.
Energy of Motion – Kinetic Energy Energy Types Energy of Motion – Kinetic Energy Stored Energy – Potential Energy
Gravitational Potential Energy The work you do to lift an object is equal to its increase in gravitational PE. PE = mgh h = vertical distance from ground level.
Example Work = increase in PE = mgh = 100(9.8)10 = 9800 Joules. How much work does a 100kg person do walking up a flight of stairs that takes her 10m off of the ground? Work = increase in PE = mgh = 100(9.8)10 = 9800 Joules. (Note: 1 Calorie = 4128J, so this person burned a little over 2 calories. ) ( Note: 1 taco = 200 Calories = 825,600 Joules)
Total Mechanical Energy, E E = KE + PE If there is no friction, the total mechanical energy is conserved. This means KE + PE is always the same number. So if KE drops, PE must rise. If PE drops, KE must rise. Another way to say this, is that KE is converted to PE, or PE is converted to KE.
Conservation of Energy
Example A 1 kg rock is dropped from rest from a building 20m high. Fill in the table. Height KE PE E 20 10 5 PE at the top is mgh = 1(9.8)(20) = 196J 196J 196J KE at the top is zero. 98J 196J 98J 147J 49J 196J E at the top (and everywhere) is 0 + 196J = 196J 196J 196J PE at the bottom is zero…………
Practice/ Application Open the “ Energy Skate Park Basics” at the phet site. In the “ Introduction” tab, pick the first track (U shaped.) Check “ bar graph” , “speed”, “grid” and “slow motion”. Place the skater at 4m above the ground on the track and release.
Data Put in Science Notebook Read and record the velocity at the following heights. Each increment on the speed dial is 1.0m/s h(m) v(m/s) 4.0 3.5 3.0 2.5 2.0 1.5 1.0 0.5 0.0
Questions - Put in Science Notebook Describe how the kinetic energy and the potential energy are related by observing the bar graph. a. What can you tell about the sum of KE and PE? b. When the KE is a maximum, what is the PE? c. How is the KE related to the velocity? d. How is the PE related to the height? 2. At what height are the potential energy and the kinetic energy equal? How are h and v related? Are they directly proportional? Plot v2 vs. h and do a best fit for the graph. What does this tell you about the relationship between h and v?
Exit In your science notebook, answer the following: 1. What are the factors that determine potential energy? 2. What are the factors that determine kinetic energy?
Science Notebook Checklist Starter Data table 3 Answered Questions Graph ( v2 vs. h ) Summary Exit
Starter A 10kg rock is moving at 10m/s and is 10m above the ground. What is its total energy, E? KE = (1/2)mv2 = (.5)(10)(102) = 500J PE = mgh = 10(9.8)10 = 980J E = PE + KE = 1480J
Summary Work = Frcos(q) E = KE + PE KE = (1/2)mv2 PE = mgh Work Total = ½mvf2 – ½mvi2 or Work Total = DKE PE = mgh E = KE + PE
Introduction to Energy Skate Park Lab Starter : At what points on the path of a swinging child is her speed a maximum? A minimum? How does this relate to the height of the child above the ground?