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Electromagnetic Induction Lenz’s discovery Faraday’s law example ways to change flux WB - EMF WB Direction.

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Presentation on theme: "Electromagnetic Induction Lenz’s discovery Faraday’s law example ways to change flux WB - EMF WB Direction."— Presentation transcript:

1 Electromagnetic Induction Lenz’s discovery Faraday’s law example ways to change flux WB - EMF WB Direction

2 Lenz’s Discovery demo - show coil within coil EMF (voltage) is induced by changing magnetic fields

3 Ways to change flux: (show)  = BAcos  Change B (magnetic field) Change A (area) Change  (angle - rotate) Change any combination:  = BAcos  - BAcos  (final) - (initial) Magnetic Flux:  = BAcos   - Magnetic Flux in Webers B - Magnetic Field in T A - Area in m 2 θ - Angle twixt B and A A Show with overhead max flux with loop, min flux

4 Lenz’s Law - induced current resists: Change in flux Motion that caused change in flux N S Ways to predict direction: Magnet: Oppose the motion – Conservation of Energy! Flux: Lose it – replace it/Gain it – Oppose it Direction of current, energy in wire, work done

5  = -N   t  - Electromotive force (voltage) N - # windings Δ  - Change in Magnetic Flux Δt - The time elapsed Faraday’s Law:...... 50. cm 75 cm B = 1.7 T Example: The loop is removed in.012 s. What is the EMF generated? Which way does the current flow? (N = 1)

6 The loop is removed in.012 s. What is the EMF generated? Which way does the current flow? (N = 1) So the flux (out of the page) goes away. The flux is (1.7 T)(0.75 m)(0.50 m) = 0.6375 Webers (Tm 2 ), and the EMF is (0.6375 Webers)/(0.012 s) = 53.125 V Now for the direction, we lost flux out of the page, so we replace it (therefore resisting the change) to create flux out of the page, the loop would make the N pole out of the page, and therefore the current would go acw (anti clockwise) in the loop using the loop right hand rule. There are other ways to predict the direction, but in this case, this is the best. 53 V, acw

7 Whiteboards - EMF

8 The approach of the magnet makes the B field inside the 3.0 cm diameter loop go from.025 T to.175 T in.0035 s. What is the EMF, direction of the current, and which electrode is + (current flows out of it).030 V, acw, A N S AB

9 The bar moves to the right at 2.0 m/s, and the loop is 1.5 m wide. What EMF is generated, and which direction is the current? 9.6 V, acw B = 3.2 T x x x x x x 2.0 m/s 1.5 m

10 The loop is rotated about an axis that lies in this page from its current position to an angle of 57 o with the page in.0063 seconds. What EMF, what direction current? 260 V, acw B = 5.3 T...... 82 cm side view

11 I Wrap your Rt. fingers with the current, and your thumb is the N pole N Review Lines of flux away from N, So your thumb is the direction of flux inside the loop

12 Whiteboards Direction flux in a loop 1 | 2 | 3 | 4

13 Which way is the flux inside the loop? outa da page

14 into da page Which way is the flux inside the loop?

15 to the left Current goes up in the front of the coil Which way is the flux inside the loop?

16 up Current goes right in the front of the coil Which way is the flux inside the loop?

17 to the right Current goes down in the front of the coil Which way is the flux inside the loop?

18 down Current goes left in the front of the coil Which way is the flux inside the loop?

19 Whiteboards – Direction of current

20 Which way is the current? ACW......

21 Which way is the current? (When does it stop flowing?) CW......

22 Which way is the current? ACW x x x x x x B increases into page

23 Which way is the current? ACW x x x x x x

24 Which way is the current? CW x x x x Before x x x x Loop has been rotated

25 Up the front N S Which way is the current on the front of the coil? (up or down)

26 Down the front N S Which way is the current on the front of the coil? (up or down)

27 Up the front N S Which way is the current on the front of the coil? (up or down)

28 Which way will the current flow? CW x x x x x x (stays fixed)

29 Which way is the current on the front of the coil? (right or left) right on the front N S

30 Which way will the current flow in the circle? ACW Wire with current increasing I

31 Which way will the current flow in the circle? CW Wire with current Decreasing I

32 Which way will the current flow? ACW Current in outer loop Decreases (ACW)

33 Which way will the current flow in the inner loop? CW Resistance Decreases

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