Centrifugal Force in the Electric Circuit: Difference between revisions
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The centrifugal force is heavily involved in electromagnetism. It is involved in the magnetic force that acts on a current carrying wire and it is also involved in the electromotive force that induces an electric current in a wire that is moving in a magnetic field. In the former case it is a simple centrifugal force of the kind that keeps the planets in orbit, whereas in the latter case it is a compound centrifugal force which bears close similarities to the transverse Coriolis force that acts in non-circular planetary orbits and in all vortex phenomena.[[Category:Scientific Paper]] | The centrifugal force is heavily involved in electromagnetism. It is involved in the magnetic force that acts on a current carrying wire and it is also involved in the electromotive force that induces an electric current in a wire that is moving in a magnetic field. In the former case it is a simple centrifugal force of the kind that keeps the planets in orbit, whereas in the latter case it is a compound centrifugal force which bears close similarities to the transverse Coriolis force that acts in non-circular planetary orbits and in all vortex phenomena. | ||
[[Category:Scientific Paper|centrifugal force electric circuit]] | |||
[[Category:Aether]] | [[Category:Aether]] | ||
[[Category:Electrodynamics]] | [[Category:Electrodynamics]] | ||
Revision as of 12:07, 1 January 2017
| Scientific Paper | |
|---|---|
| Title | Centrifugal Force in the Electric Circuit |
| Author(s) | David Tombe |
| Keywords | centrifugal force |
| Published | 2009 |
| Journal | General Science Journal |
| No. of pages | 7 |
Abstract
The centrifugal force is heavily involved in electromagnetism. It is involved in the magnetic force that acts on a current carrying wire and it is also involved in the electromotive force that induces an electric current in a wire that is moving in a magnetic field. In the former case it is a simple centrifugal force of the kind that keeps the planets in orbit, whereas in the latter case it is a compound centrifugal force which bears close similarities to the transverse Coriolis force that acts in non-circular planetary orbits and in all vortex phenomena.