Electro-Magnetic Induction

1. Electro-Magnetic Induction © David Hoult 2009

2. Magnetic flux © David Hoult 2009

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6. If the magnitude of the flux density is B then the magnitude of the magnetic flux (f) linked with the area A is defined to be © David Hoult 2009

7. If the magnitude of the flux density is B then the magnitude of the magnetic flux (f) linked with the area A is defined to be f= AB © David Hoult 2009

8. f= AB units of flux © David Hoult 2009

9. f= AB units of flux Tm2 © David Hoult 2009

10. f= AB units of flux Tm2 1 Tm2 = 1 Weber (Wb) © David Hoult 2009

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12. Now, the magnitude of the component of the flux density perpendicular to the area is Bcosq © David Hoult 2009

13. Now, the magnitude of the component of the flux density perpendicular to the area is Bcosq so the magnetic flux (f) linked with the area is now f= ABcosq alternatively © David Hoult 2009

14. In practice, the area in question is usually surrounded by a conductor, often a coil of wire. © David Hoult 2009

15. In practice, the area in question is usually surrounded by a conductor, often a coil of wire. If the coil of wire has N turns, we define the flux linkage as follows © David Hoult 2009

16. In practice, the area in question is usually surrounded by a conductor, often a coil of wire. If the coil of wire has N turns, we define the flux linkage as follows Flux linkage = N f © David Hoult 2009

17. EMF induced in a conductor moving through a uniform magnetic field © David Hoult 2009

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23. The wire moves distance Ds in time Dt. In this time, a charge Dq moves past any point in the wire. © David Hoult 2009

24. The wire moves distance Ds in time Dt. In this time, a charge Dq moves past any point in the wire. work done = FDs © David Hoult 2009

25. The wire moves distance Ds in time Dt. In this time, a charge Dq moves past any point in the wire. work done = FDs FDs work done per unit charge = Dq © David Hoult 2009

26. The wire moves distance Ds in time Dt. In this time, a charge Dq moves past any point in the wire. work done = FDs FDs work done per unit charge = Dq work done per unit charge is the induced emf © David Hoult 2009

27. If the wire moves at constant speed, the force F must be © David Hoult 2009

28. If the wire moves at constant speed, the force F must be equal but opposite to the force acting on it due to the current I, induced in it © David Hoult 2009

29. If the wire moves at constant speed, the force F must be equal but opposite to the force acting on it due to the current I, induced in it F = -ILB © David Hoult 2009

30. If the wire moves at constant speed, the force F must be equal but opposite to the force acting on it due to the current I, induced in it F = -ILB FDs E = Dq © David Hoult 2009

31. If the wire moves at constant speed, the force F must be equal but opposite to the force acting on it due to the current I, induced in it F = -ILB FDs E = Dq -ILBDs E = Dq © David Hoult 2009

32. I = © David Hoult 2009

33. Dq I = Dt © David Hoult 2009

34. Dq - (Dq/Dt)LBDs I = E = Dq Dt and © David Hoult 2009

35. Dq - (Dq/Dt)LBDs I = E = Dq Dt and Ds = Dt © David Hoult 2009

36. Dq - (Dq/Dt)LBDs I = E = Dq Dt and Ds = v Dt © David Hoult 2009

37. Dq - (Dq/Dt)LBDs I = E = Dq Dt and Ds = v Dt E = -BLv © David Hoult 2009

38. The Laws of Electro-magnetic Induction © David Hoult 2009

39. Lenz’s Law When e.m.i. occurs, any induced current will flow in such a direction as to © David Hoult 2009

40. Lenz’s Law When e.m.i. occurs, any induced current will flow in such a direction as to oppose the change producing it © David Hoult 2009

41. Lenz’s Law When e.m.i. occurs, any induced current will flow in such a direction as to oppose the change producing it It should be clear that Lenz’s law is an “electro-magnetic version” of © David Hoult 2009

42. Lenz’s Law When e.m.i. occurs, any induced current will flow in such a direction as to oppose the change producing it It should be clear that Lenz’s law is an “electro-magnetic version” of the law of conservation of energy © David Hoult 2009

43. Lenz’s Law When e.m.i. occurs, any induced current will flow in such a direction as to oppose the change producing it Faraday’s Law The induced emf is directly proportional to the © David Hoult 2009

44. Lenz’s Law When e.m.i. occurs, any induced current will flow in such a direction as to oppose the change producing it Faraday’s Law The induced emf is directly proportional to the rate of change of flux linking the conductor © David Hoult 2009

45. The sense of the induced current can be predicted using Fleming’s RIGHT hand rule © David Hoult 2009

46. The sense of the induced current can be predicted using Fleming’s RIGHT hand rule which is pretty much like Fleming’s left hand rule © David Hoult 2009

47. The sense of the induced current can be predicted using Fleming’s RIGHT hand rule which is pretty much like Fleming’s left hand rule except, guess what... © David Hoult 2009

48. The sense of the induced current can be predicted using Fleming’s RIGHT hand rule which is pretty much like Fleming’s left hand rule except, guess what... using the right hand instead of the left hand! © David Hoult 2009

49. ThuMb Motion First finger Field SeCond finger Current © David Hoult 2009

50. Both the laws of e.m.i. can be combined in a single mathematical statement © David Hoult 2009