Electromagnetic induction
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| Electromagnetism | |
| Electricity · Magnetism | |
| Electrostatics | |
|---|---|
| Electric charge | |
| Coulomb's law | |
| Electric field | |
| Gauss's law | |
| Electric potential | |
| Electric dipole moment | |
| Magnetostatics | |
| Ampère's circuital law | |
| Magnetic field | |
| Magnetic flux | |
| Biot-Savart law | |
| Magnetic dipole moment | |
| Electrodynamics | |
| Electrical current | |
| Lorentz force law | |
| Electromotive force | |
| (EM) Electromagnetic induction | |
| Faraday-Lenz law | |
| Displacement current | |
| Maxwell's equations | |
| (EMF) Electromagnetic field | |
| (EM) Electromagnetic radiation | |
| Electrical Network | |
| Electrical conduction | |
| Electrical resistance | |
| Capacitance | |
| Inductance | |
| Impedance | |
| Resonant cavities | |
| Waveguides | |
| Tensors in Relativity | |
| Electromagnetic tensor | |
| Electromagnetic stress-energy tensor | |
Electromagnetic induction is the production of voltage across a conductor situated in a changing magnetic field or a conductor moving through a stationary magnetic field.
Contents
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[edit] Discovery
Michael Faraday is generally credited with having discovered the induction phenomenon in 1831 though it may have been anticipated by the work of Francesco Zantedeschi in 1829[citation needed]. Around 1830 [1] to 1832 [2] Joseph Henry made a similar discovery, but did not publish his findings until later.
[edit] Findings
Faraday found that the electromotive force (EMF) produced around a closed path is proportional to the rate of change of the magnetic flux through any surface bounded by that path.
In practice, this means that an electrical current will be induced in any closed circuit when the magnetic flux through a surface bounded by the conductor changes. This applies whether the field itself changes in strength or the conductor is moved through it.
Electromagnetic induction underlies the operation of generators, induction motors, transformers, and most other electrical machines.
Faraday's law of electromagnetic induction states that:
,
where
is the electromotive force (emf) in volts- ΦB is the magnetic flux in webers
For the common but special case of a coil of wire, comprised of N loops with the same area, Faraday's law of electromagnetic induction states that
where
- is the electromotive force (emf) in volts
- N is the number of turns of wire (per metre)
- ΦB is the magnetic flux in webers through a single loop.
Further, Lenz's law gives the direction of the induced emf, thus:
- The emf induced in an electric circuit always acts in such a direction that the current it drives around the circuit opposes the change in magnetic flux which produces the emf.
Lenz's law is therefore responsible for the minus sign in the above equation.
[edit] Practical Demonstration
Two videos demonstrating Faraday's and Lenz's laws can be watched at EduMation
[edit] Applications
The principles of electromagnetic induction are applied in many devices and systems, including:
- Induction Sealing
- Induction motors
- Electrical generators
- Transformers
- Contactless charging of rechargeable batteries
- The 6.6kW Magne Charge system for Battery electric vehicles
- Induction cookers
- Induction welding
- Inductors
- Electromagnetic forming
- Magnetic flow meters
- Transcranial magnetic stimulation
- Faraday Flashlight
- Graphics tablet
- Wireless energy transfer