Electromagnetic pump

Electromagnetism
Electricity Magnetism
Electrostatics Electric charge Static electricity Electric field Conductor Insulator Triboelectricity Electrostatic discharge Induction Coulomb's law Gauss's law Electric flux / potential energy Electric dipole moment Polarization density
Magnetostatics Ampère's law Magnetic field Magnetization Magnetic flux Biot–Savart law Magnetic dipole moment Gauss's law for magnetism
Electrodynamics Lorentz force law Electromagnetic induction Faraday's law Lenz's law Displacement current Magnetic potential Maxwell's equations Electromagnetic field Electromagnetic radiation Maxwell tensor Poynting vector Liénard–Wiechert potential Jefimenko's equations Eddy current London equations Mathematical descriptions of the electromagnetic field
Electrical network Electric current Electric potential Voltage Resistance Ohm's law Series circuit Parallel circuit Direct current Alternating current Charged current Neutral current Electromotive force Capacitance Inductance Impedance Resonant cavities Waveguides
Covariant formulation Electromagnetic tensor (stress–energy tensor) Four-current Electromagnetic four-potential
Scientists Ampère Coulomb Faraday Gauss Heaviside Henry Hertz Lorentz Maxwell Tesla Volta Weber Ørsted

An electromagnetic pump is a pump that moves liquid metal (or any electrically conductive liquid) using electromagnetism. A magnetic field is set at right angles to the direction the liquid moves in, and a current is passed through it. This causes an electromagnetic force that moves the liquid.

Applications include pumping liquid metal through a cooling system.

Working Principle

Schematic of Electromagnetic Pump

A magnetic field (b_rc) always exists around the current (I) carrying conductor. When this current carrying conductor is subjected to external magnetic field (B_ap), the conductor experiences a force perpendicular to the direction of I and B_ap. This is because, the magnetic field produced by the conductor and the applied magnetic field try to align with each other. The similar effect one can see between any two magnets.

The same principle is used in electromagnetic pump. The current is supplied through a conducting liquid. And two permanent magnets are arranged to produce magnetic field B_ap as shown in the figure. The supplied current has current density (J) and the magnetic field associated with this current can be called as 'Reaction magnetic Field (b_rc)'. The two magnetic fields B_ap and b_rc try to align with each other. This causes the mechanical motion of the fluid.

See also

• Electromagnetic flow meter
• Molten salt

References

Bibliography

R. S. Baker Handbook of Electromagnetic pump technology

External links

• demo
• Analysis and Design of Electromagnetic Pump
• The Einstein-Szilard Electromagnetic Pump -American Physics Society