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Chapter 20: Induced Voltages and Inductances

Chapter 20: Induced Voltages and Inductances. Homework assignment : 17,18,57,25,34,66 . Discovery of induction. Induced Emf and Magnetic Flux. Induced Emf and Magnetic Flux. Magnetic flux. A (area). magnetic flux: . magnetic flux: . q. Farady’s law of induction.

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Chapter 20: Induced Voltages and Inductances

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  1. Chapter 20: Induced Voltages and Inductances Homework assignment : 17,18,57,25,34,66 • Discovery of induction Induced Emf and Magnetic Flux

  2. Induced Emf and Magnetic Flux • Magnetic flux A (area) magnetic flux: magnetic flux: q

  3. Farady’s law of induction An emf in volts is induced in a circuit that is equal to the time rate of change of the total magnetic flux in webers threading (linking) the circuit: If the circuit contains N tightly wound loops Farady’s Law of Induction • The flux through the circuit may be changed in several different ways • B may be made more intense. • The coil may be enlarged. • The coil may be moved into a region of stronger field. • The angle between the plane of the coil and B may change.

  4. Farady’s law of induction (cont’d) Farady’s Law of Induction • The sum of Ei Dsi along the loop • is equal to the work done per unit • charge, which is the emf of the circuit.

  5. B due to induced current B due to induced current • Lenz’s law The sign of the induced emf is such that it tries to produce a current that would create a magnetic flux to cancel (oppose) the original flux change. Farady’s Law of Induction

  6. Farady’s Law of Induction • Lenz’s law (cont’d) • The bar magnet moves towards loop. • The flux through loop increases, and an emf induced in the loop • produces current in the direction shown. • B field due to induced current in the loop (indicated by the dashed • lines) produces a flux opposing the increasing flux through the loop • due to the motion of the magnet.

  7. Origin of motional electromotive force I FE FB Motional Electromotive Force

  8. Origin of motional electromotive force I (cont’d) Motional Electromotive Force

  9. Origin of motional electromotive force II B . Bind Motional Electromotive Force

  10. Origin of motional electromotive force II (cont’d) Motional Electromotive Force

  11. Origin of motional electromotive force II (cont’d) Motional Electromotive Force

  12. Origin of motional electromotive force II (cont’d) Motional Electromotive Force

  13. Origin of motional electromotive force II (cont’d) Motional Electromotive Force

  14. Origin of motional electromotive force III Motional Electromotive Force

  15. Origin of motional electromotive force III (cont’d) Motional Electromotive Force

  16. Origin of motional electromotive force III (cont’d) JUST FOR FUN WITH CALCULUS! Motional Electromotive Force

  17. A bar magnet and a loop (again) Motional Electromotive Force In this example, a magnet is being pushed towards (away from) a closed loop. The number of field lines linking the loop is evidently increasing (decreasing).

  18. An electromagnet and a coil Motional Electromotive Force

  19. Tape recorder Motional Electromotive Force

  20. v v • A generator (alternator) q The armature of the generator opposite is rotating in a uniform B field with angular velocity ω this can be treated as a simple case of the E = υ×B field. On the ends of the loop υ×B is perpendicular to the conductor so does not contribute to the emf. On the top υ×B is parallel to the conductor and has the value E = υB sin θ = ωRB sin ωt. The bottom conductor has the same value of E in the opposite direction but the same sense of circulation. top 90o-q B Generators bottom Farady emf

  21. A generator (cont’d) AC generator Generators DC generator

  22. induced current a b X X X X X X X X X X X X X X • Self-inductance Consider the loop at the right. switch • - Switch closed : Current starts to flow on the loop. • Magnetic field produced in the area enclosed by • the loop (B proportional to I). • - Flux through the loop increases with I. • Emf induced to oppose the initial direction of the current flow. • Self-induction: changing the current through the loop inducing • an opposing emf the loop. Self-inductance

  23. I • Self-inductance (cont’d) - The magnetic field induced by the current in the loop is proportional to the current: - The magnetic flux induced by the current in the loop is also proportional to the current: self-inductance - Define the constant of proportion as L: - From Frarady’s law: Self-inductance SI unit of L :

  24. Self Inductance • Calculation of self inductance : A solenoid Accurate calculations of L are generally difficult. Often the answer depends even on the thickness of the wire, since B becomes strong close to a wire. In the important case of the solenoid, the first approximation result for L is quite easy to obtain: earlier we had Hence Then, So L is proportional to n2 and the volume of the solenoid

  25. Self Inductance • Calculation of self inductance: A solenoid (cont’d) Example: the L of a solenoid of length 10 cm, area 5 cm2, with a total of 100 turns is L = 6.28×10−5 H 0.5 mm diameter wire would achieve 100 turns in a single layer. Going to 10 layers would increase L by a factor of 100. Adding an iron or ferrite core would also increase L by about a factor of 100.  The expression for L shows that μ0 has units H/m, c.f, Tm/A obtained earlier

  26. RL Circuits • Inductor A circuit element that has a large inductance, such as a closely wrapped coil of many turns, is called a inductor. • RL circuit Kirchhoff’s rules: time constant

  27. Energy Stored in a Magnetic Field • Inductor • The emf induced by an inductor prevents a battery from establishing • instantaneous current in a circuit. • The battery has to do work to produce a current – this work can be • considered as energy stored in the inductor in its magnetic field. energy stored in inductor

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