Work and Energy

1. Work and Energy Dr. Robert MacKay Clark College

2. Introduction • What is Energy? • What are some of the different forms of energy? • Energy = $$$

3. Overview • Work (W) Kinetic Energy (K) Potential Energy (U) • All Are measured in Units of Joules (J) • 1.0 Joule = 1.0 N m W K U

4. Overview • Work Kinetic Energy Potential Energy Heat Loss W K U Heat Loss Heat Loss

5. Work and Energy • Work = Force x displacement • W = F d • Actually • Work = Force x displacement parallel to force Dr =4.0 m W= F Dr = 6.0 N (4.0m) = 24.0 J F= 6.0 N

6. Work and Energy • Work = Force x Displacement parallel to force Dr = 8.0 m F= - 6.0 N W= F Dr = -6.0 N (8.0m) =-48 J

7. Work and Energy • Work = Force x Displacement parallel to force Dr = 6.0 m F= ? N W= 60 J

8. Work and Energy • Work = Force x Displacement parallel to force Dr = ? m F= - 50.0 N W= 200 J

9. Work and Energy • Work = Force x Displacement parallel to force Dr = 8.0 m F= + 6.0 N W= 0 (since F and d are perpendicular

10. Fig. 7.2, p.184

11. Work and Energy • Work = FDr • Dot product W = F Dr cos (40) Dr = 8.0 m F= + 6.0 N 40° W= (6.0N) [8.0m cos(40) ]= 36.8 J

12. Work and Energy • Work = F Dr • Dot product W = F Dr cos(40) Dr = 8.0 m F= + 6.0 N 40° W= (6.0N cos(40) ) [8.0m]= 36.8 J

13. Total Area ~S (DA) Work ~ S (FxDx) ~ ~ Fig. 7.7a, p.189

14. Fig. 7.7b, p.189

15. Work Variable Force (q=0) • Work = F Dr cosq = FavgDx

16. Springs 101 • Spring Constant k, stiffness = 50 N/m

17. Work Variable Force (q=0) • Work = F D cosq = F D

18. Work Variable Force (q=0) • Work = “Area” units of N m (Joules) W= 0.5*(100N)(4m) - 0.5(50N)2m) = +200 J-50 J = 150 J

19. Potential Energy, U • Gravitational Potential Energy • Springs • Chemical • Pressure • Mass (Nuclear) • Measured in Joules

20. Potential Energy, U The energy required to put something in its place (state) • Gravitational Potential Energy • Springs • Chemical • Pressure • Mass (Nuclear)

21. Potential Energy • Gravitational Potential Energy = weight x height U=(mg) h m = 2.0 kg 4.0 m

22. Potential Energy U=(mg) h U=80 J m = 2.0 kg 4.0 m K=?

23. Potential Energy to Kinetic Energy U=(mg) h m = 2.0 kg K E= 0 J PE=40 J 2.0 m 1.0 m KE=?

24. Potential Energy of a spring x 1 kx2 U= 2

25. Potential Energy of a spring x 1 kx2 U= 2 For a spring with stiffness k= 80 N/m, what is its potential energy when stretched 0.1m? How about 0.2 m?

26. Potential Energy of a spring x 1 1 U= kx2 = 80 N/m (0.1m)2 2 2 = 0.40 J For a spring with stiffness k= 80 N/m, what is its potential energy when stretched 0.1m? How about 0.2 m?

27. Potential Energy of a spring x 1 1 U= kx2 = 80 N/m (0.2m)2 2 2 = 1.60 J For a spring with stiffness k= 80 N/m, what is its potential energy when stretched 0.1m? How about 0.2 m?

28. Potential Energy of a spring x 1 kx2 U= 2

29. Kinetic Energy K=1/2mv2 Table 7.1, p.194

30. Kinetic Energy, K • K =1/2 m v2 m=2.0 kg and v= 5 m/s K= ?

31. Kinetic Energy m=2.0 kg and v= 5 m/s K= 25 J • K =1/2 m v2 m=4.0 kg and v= 5 m/s K= ? m=2.0 kg and v= 10 m/s K= ?

32. Kinetic Energy • K =1/2 m v2 • if m doubles KE doubles • if v doubles KE quadruples • if v triples KE increases 9x • if v quadruples KE increases ____ x

33. Work Energy Theorm • K =1/2 m v2 • F = m a

34. Work Energy Theorm • K =1/2 m v2 • F = m a • F d = m a d

35. Work Energy Theorm • K =1/2 m v2 • F = m a • F d =m a d • F d = m (v/t) [(v/2)t]

36. Work Energy Theorm • K =1/2 m v2 • F = m a • F d = m a d • F d = m (v/t) [(v/2)t] • W = 1/2 m v2

37. Work Energy Theorm • KE =1/2 m v2 • F = m a • F d = m a d • F d = m (v/t) [(v/2)t] • W = 1/2 m v2 • W = ∆ KE

38. Work EnergyW = ∆K • How much work is required to stop a 2000 kg car traveling at 20 m/s (45 mph)?

39. Work EnergyW = ∆K • How much work is required to stop a 2000 kg car traveling at 20 m/s (45 mph)? • W= ∆K =-1/2 m v2 • =-1/2(2000 kg)(20 m/s)2 • = - 1000kg (400 m 2 /s 2) • = - 400,000 Joules

40. Work EnergyW = ∆K • How much work is required to stop a 2000 kg car traveling at 20 m/s? If the friction force equals its weight, how far will it skid? • W= ∆K = - 400,000 Joules • F=weight=mg=-20,000 N • W=F d d=W/F=-400,000 J/-20,000N • = 20.0 m

41. Work EnergyW = ∆K v = 20 m/s d=? m Same Friction Force v = 10 m/s d= 15 m

42. Conservation of Energy Energy can neither be created nor destroyed only transformed from one form to another Total Mechanical Energy, E = U +K In the absence of friction or other non-conservative forces the total mechanical energy of a system does not change E f=Eo

43. Conservation of Energy U=100 J K = 0 J m = 1.02 kg (mg = 10.0 N) Constant E {E = K + U} Ef = Eo U = 75 J K = 25 J 10.0 m U = 50 J K = 50 J U = 25 J K= ? No friction No Air resistance U = 0 J K = ?

44. Conservation of Energy U=100 J m = 2.0 kg K=0 J Constant E {E = K + U} Constant E {E = K + U} Ef=Eo 5.0 m No friction U = 0 J K = ?

45. Conservation of Energy U =100 J m = 2.0 kg K = 0 J Constant E {E = K + U} Constant E {E = K + U} Ef=Eo 5.0 m No friction v = ? K = 100 J

46. Conservation of Energy Constant E {E = K + U} Ef=Eo Ef=Eo+Wother Kf +Uf=Ko+Uo +Wother

49. Example 8.8