SinglePhaseElectroMagneticConverterSingle-phase electromagnetic converter |
This information is part of the Modelica Standard Library maintained by the Modelica Association.
The single-phase winding has an effective number of turns, and a respective orientation of the winding, . The current in winding is .
The total complex magnetic potential difference of the single-phase winding is determined by:
In this equation the magnetomotive force is aligned with the orientation of the winding.
The voltage induced in the winding depends on the cosine between the orientation of the winding and the angle of the complex magnetic flux. Additionally, the magnitudes of the induced voltages are proportional to the respective number of turns. This relationship can be modeled by means of
The single-phase electromagnetic converter is a special case of the PolyphaseElectroMagneticConverter
effectiveTurns |
Value: Type: Real Description: Effective number of turns |
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orientation |
Value: Type: Angle (rad) Description: Orientation of the resulting fundamental wave V_m phasor |
N |
Value: effectiveTurns * Modelica.ComplexMath.exp(Complex(0, orientation)) Type: Complex Description: Complex number of turns |
pin_p |
Type: PositivePin Description: Positive pin |
|
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pin_n |
Type: NegativePin Description: Negative pin |
|
port_p |
Type: PositiveMagneticPort Description: Positive complex magnetic port |
|
port_n |
Type: NegativeMagneticPort Description: Negative complex magnetic port |
V_m |
Type: ComplexMagneticPotentialDifference Description: Complex magnetic potential difference |
|
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Phi |
Type: ComplexMagneticFlux Description: Complex magnetic flux |
|
N |
Type: Complex Description: Complex number of turns |
Modelica.Magnetic.FundamentalWave.Examples.Components Single-phase inductance |
PolyphaseElectroMagneticConverter Modelica.Magnetic.FundamentalWave.Components Polyphase electromagnetic converter |
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Modelica.Magnetic.FundamentalWave.BasicMachines.Components Symmetric winding model coupling electrical and magnetic domain |