Physics:Permeance

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Electromagnetism
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Electrostatics Conductor Coulomb's law Electric charge Electric dipole moment Electric field Electric flux / potential energy Electrostatic discharge Gauss's law Induction Insulator Polarization density Static electricity Triboelectricity
Magnetostatics Ampère's law Biot–Savart law Gauss's law for magnetism Magnetic field Magnetic flux Magnetic dipole moment Magnetization Magnetomotive force
Electrodynamics Lorentz force law Electromagnetic induction Faraday's law Lenz's law Displacement current Magnetic potential Maxwell's equations Electromagnetic field Electromagnetic pulse Electromagnetic radiation Maxwell tensor Poynting vector Liénard–Wiechert potential Jefimenko's equations Eddy current London equations Mathematical descriptions of the electromagnetic field
Electrical network Alternating current Capacitance Direct current Electric current Electric potential Electromotive force Impedance Inductance Ohm's law Parallel circuit Resistance Resonant cavities Series circuit Voltage Waveguides
Covariant formulation Electromagnetic tensor (stress–energy tensor) Four-current Electromagnetic four-potential
Scientists Ampère Biot Coulomb Faraday Gauss Heaviside Henry Hertz Lenz Lorentz Maxwell Ørsted Savart Tesla Volta Weber
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Permeance, in general, is the degree to which a material admits a flow of matter or energy. Permeance is usually represented by a curly capital P: P.

In electromagnetism, permeance is the inverse of reluctance. In a magnetic circuit, permeance is a measure of the quantity of magnetic flux for a number of current-turns. A magnetic circuit almost acts as though the flux is conducted, therefore permeance is larger for large cross-sections of a material and smaller for smaller cross section lengths. This concept is analogous to electrical conductance in the electric circuit.

Magnetic permeance P is defined as the reciprocal of magnetic reluctance R (in analogy with the reciprocity between electric conductance and resistance): $${\displaystyle {𝒫}=\frac{1}{{ℛ}}}$$

which can also be re-written: $${\displaystyle {𝒫}=\frac{{\mathrm{\Phi }}_{\mathrm{B}}}{NI}}$$

using Hopkinson's law (magnetic circuit analogue of Ohm's law for electric circuits) and the definition of magnetomotive force (magnetic analogue of electromotive force): $${\displaystyle {ℱ}={\mathrm{\Phi }}_{\mathrm{B}}{ℛ}=NI}$$

where:

• Φ_B, magnetic flux,
• I, current, in amperes,
• N, winding number of, or count of turns in the electric coil.

Alternatively in terms of magnetic permeability (analogous to electric conductivity): $${\displaystyle {𝒫}=\frac{\mu A}{\ell }}$$

where:

• μ, permeability of material,
• A, cross-sectional area,
• ℓ, magnetic path length.

The SI unit of magnetic permeance is the henry (H), equivalently, webers per ampere.^{[lower-alpha 1]}

In materials science, permeance is the degree to which a material transmits another substance.

• Dielectric complex reluctance
• Reluctance

• Properties of Magnetic Materials (units of magnetic permeance)

• Bombaru, D., Jutras, R., and Patenaude, A., "Air Permeance of Building Materials". Summary report prepared by, AIR-INS Inc. for Canada Mortgage and Housing Corporation, Ottawa, 1988.

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