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Electromagnetic Induction

Can a magnet produce electricity?. Electromagnetic Induction. An English scientist who was first to prove that a magnet can produce current. Michael Faraday. A magnet can produce electricity!. Duh!. Joseph Henry. What conditions are necessary for a magnet to produce current?.

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Electromagnetic Induction

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  1. Can a magnet produce electricity? Electromagnetic Induction

  2. An English scientist who was first to prove that a magnet can produce current. Michael Faraday A magnet can produce electricity! Duh! Joseph Henry

  3. What conditions are necessary for a magnet to produce current? • Magnet must be moving or • Wire must be moving • Movement causes changing magnetic field • Changing magnetic field induces current

  4. The phenomenon by which an emf or current induced in a conductor due to change in magnetic field. Electromagnetic Induction

  5. What factors affect the nature of emf or current produced? • Direction of motion • In or out • Speed of motion • Polarity of magnet coming in • Number of turns • Area of coil

  6. The direction of the current induced opposes the change producing it Direction of Motion

  7. The faster the movement is, the greater is the induced emf. Speed of Motion

  8. The induced current produces a magnetic field that opposes the one causing it. • Use RHR Polarity of magnet

  9. The more the number of turns, the greater the emf induced. Number of turns

  10. Faraday’s Law • The induced emf across the conductor is equal to the rate at which magnetic flux is cut by the conductor. Laws of EM induction

  11. Product of flux density (B) and the area (A), when flux is at right angles to the area. • Ø= BA • Unit: Weber, Wb • A weber is the flux when a unit tesla of magnetic flux density is at right angles to a unit area. Magnetic Flux

  12. Total flux cut by all turns of the coil • Ø= BAN Magnetic Flux Linkage

  13. EMF = dØ /dt • For single coil • EMF = BA/t • For many coils • EMF = BAN/t • For a wire • EMF = Blx/t • Where l is length of wire and x is distance traveled. • EMF = Blv • Where v is the speed So far…

  14. The direction of any induced current is such as to oppose the change that causes it. Lenz’s Law

  15. EMF = -dØ /dt • For single coil • EMF = - BA/t • For many coils • EMF = - BAN/t • For a wire • EMF = -Blx/t • Where l is length of wire and x is distance traveled. • EMF = -Blv • Where v is the speed Therefore

  16. A straight wire of length 0.2 m moves at a steady speed of 3 ms-1 at right angles to a magnetic field of flux density 0.1 T. What will be the emf induced across the ends of the wire? Example 1

  17. A coil of wire having 2500 turns and of area 1 cm2 is placed between the poles of a magnet so that the magnetic flux passes perpendicularly through the coil. The flux density of the field is 0.5 T. The coil is pulled rapidly out of the field in a time of 0.1 s. What average emf is induced across the ends of the coil? Example 2

  18. Investigating Lenz’s Law

  19. Uses of EM Induction (Generator)

  20. Transformer

  21. Uses of EM Induction

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