Eddy Currents: Understanding Lenz's Law

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Eddy currents are induced in metal plates primarily through Faraday's Law, particularly when there is a change in magnetic flux. These currents create swirling patterns that oppose the motion causing them, in accordance with Lenz's Law. They can lead to heating, which is a significant concern in applications like transformer laminations. To mitigate eddy currents, materials with higher resistivity and grain-oriented steel are used to enhance magnetic properties and reduce losses. Eddy currents can occur in various conductors, including non-magnetic materials such as aluminum and copper.
elitewarr
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I don't really understand what is eddy current. Is it just the current that is formed using Lenz's law? Or is it different? My idea of eddy current is that it is of many small swirls all over a metal plate that opposes the force exerted to move the plate.

Thank you.
 
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Exactly. Eddy currents are induced in metal plates by Faraday's Law, usually dB/dt. Also, as you point out, eddy currents can be generated in a metal plate moving in a non-uniform magnetic field. There are many many swirls, as you also point out. The eddy currents not only reduce the magnitude of B (per Lenz's law), but also create heating. The heating is often the more important problem, like in transformer laminations. This is why transformer laminations not only have grain-oriented steel to improve the magnetic properties (including lower hysteresis losses) but also have higher resistivity to reduce the eddy currents. Eddy currents can be generated in any conductor, including non-magnetic materials, like aluminum and copper (including copper wires).

Bob S
 
ooh. Thanks very much!
 

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