Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy

Transformers: primary D / secondary y

Information


This package contains transformers primary D connected / secondary y connected in all possbile vector groups.

Extends from Modelica.Icons.VariantsPackage (Icon for package containing variants).

Package Content

NameDescription
Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy01 Dy01 Transformer Dy1
Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy03 Dy03 Transformer Dy3
Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy05 Dy05 Transformer Dy5
Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy07 Dy07 Transformer Dy7
Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy09 Dy09 Transformer Dy9
Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy11 Dy11 Transformer Dy11


Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy01 Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy01

Transformer Dy1

Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy01

Information


Transformer Dy1

Typical parameters see: PartialBasicTransformer

Extends from QuasiStationary.Machines.Interfaces.PartialBasicTransformer (Partial model of threephase transformer).

Parameters

TypeNameDefaultDescription
Realn Ratio primary voltage (line-to-line) / secondary voltage (line-to-line)
BooleanuseThermalPortfalseEnable / disable (=fixed temperatures) thermal port
Operational temperatures
TemperatureT1Operational Operational temperature of primary resistance [K]
TemperatureT2Operational Operational temperature of secondary resistance [K]
Nominal resistances and inductances
ResistanceR1 Primary resistance per phase at TRef [Ohm]
TemperatureT1Ref Reference temperature of primary resistance [K]
LinearTemperatureCoefficient20alpha20_1 Temperature coefficient of primary resistance at 20 degC [1/K]
InductanceL1sigma Primary stray inductance per phase [H]
ResistanceR2 Secondary resistance per phase at TRef [Ohm]
TemperatureT2Ref Reference temperature of secondary resistance [K]
LinearTemperatureCoefficient20alpha20_2 Temperature coefficient of secondary resistance at 20 degC [1/K]
InductanceL2sigma Secondary stray inductance per phase [H]

Connectors

TypeNameDescription
PositivePlugplug1Primary plug
NegativePlugplug2Secondary plug
ThermalPortTransformerthermalPort 
NegativePinstarpoint2 

Modelica definition

model Dy01 "Transformer Dy1"

  extends QuasiStationary.Machines.Interfaces.PartialBasicTransformer(
      final VectorGroup="Dy01");
  QuasiStationary.MultiPhase.Basic.Star star2(final m=m);
  QuasiStationary.SinglePhase.Interfaces.NegativePin starpoint2;
  QuasiStationary.MultiPhase.Basic.Delta Delta1(final m=m);
  QuasiStationary.MultiPhase.Basic.Delta Rot2(final m=m);
equation 
  connect(star2.pin_n, starpoint2);
  connect(l2sigma.plug_p, Rot2.plug_p);
  connect(Delta1.plug_p, r1.plug_p);
  connect(Delta1.plug_n, core.plug_n1);
  connect(l1sigma.plug_n, core.plug_p1);
  connect(core.plug_n2, core.plug_p3);
  connect(core.plug_n3, Rot2.plug_n);
  connect(core.plug_p2, star2.plug_p);
end Dy01;

Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy03 Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy03

Transformer Dy3

Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy03

Information


Transformer Dy3

Typical parameters see: PartialBasicTransformer

Extends from QuasiStationary.Machines.Interfaces.PartialBasicTransformer (Partial model of threephase transformer).

Parameters

TypeNameDefaultDescription
Realn Ratio primary voltage (line-to-line) / secondary voltage (line-to-line)
BooleanuseThermalPortfalseEnable / disable (=fixed temperatures) thermal port
Operational temperatures
TemperatureT1Operational Operational temperature of primary resistance [K]
TemperatureT2Operational Operational temperature of secondary resistance [K]
Nominal resistances and inductances
ResistanceR1 Primary resistance per phase at TRef [Ohm]
TemperatureT1Ref Reference temperature of primary resistance [K]
LinearTemperatureCoefficient20alpha20_1 Temperature coefficient of primary resistance at 20 degC [1/K]
InductanceL1sigma Primary stray inductance per phase [H]
ResistanceR2 Secondary resistance per phase at TRef [Ohm]
TemperatureT2Ref Reference temperature of secondary resistance [K]
LinearTemperatureCoefficient20alpha20_2 Temperature coefficient of secondary resistance at 20 degC [1/K]
InductanceL2sigma Secondary stray inductance per phase [H]

Connectors

TypeNameDescription
PositivePlugplug1Primary plug
NegativePlugplug2Secondary plug
ThermalPortTransformerthermalPort 
NegativePinstarpoint2 

Modelica definition

model Dy03 "Transformer Dy3"

  extends QuasiStationary.Machines.Interfaces.PartialBasicTransformer(
      final VectorGroup="Dy03");
  QuasiStationary.MultiPhase.Basic.Star star2(final m=m);
  QuasiStationary.SinglePhase.Interfaces.NegativePin starpoint2;
  QuasiStationary.MultiPhase.Basic.Delta Delta1(final m=m);
  QuasiStationary.MultiPhase.Basic.Delta Rot2(final m=m);
equation 
  connect(star2.pin_n, starpoint2);
  connect(Rot2.plug_n, l2sigma.plug_p);
  connect(Delta1.plug_p, r1.plug_p);
  connect(l1sigma.plug_n, core.plug_p1);
  connect(Delta1.plug_n, core.plug_n1);
  connect(core.plug_p2, Rot2.plug_p);
  connect(core.plug_n2, core.plug_p3);
  connect(core.plug_n3, star2.plug_p);
end Dy03;

Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy05 Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy05

Transformer Dy5

Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy05

Information


Transformer Dy5

Typical parameters see: PartialBasicTransformer

Extends from QuasiStationary.Machines.Interfaces.PartialBasicTransformer (Partial model of threephase transformer).

Parameters

TypeNameDefaultDescription
Realn Ratio primary voltage (line-to-line) / secondary voltage (line-to-line)
BooleanuseThermalPortfalseEnable / disable (=fixed temperatures) thermal port
Operational temperatures
TemperatureT1Operational Operational temperature of primary resistance [K]
TemperatureT2Operational Operational temperature of secondary resistance [K]
Nominal resistances and inductances
ResistanceR1 Primary resistance per phase at TRef [Ohm]
TemperatureT1Ref Reference temperature of primary resistance [K]
LinearTemperatureCoefficient20alpha20_1 Temperature coefficient of primary resistance at 20 degC [1/K]
InductanceL1sigma Primary stray inductance per phase [H]
ResistanceR2 Secondary resistance per phase at TRef [Ohm]
TemperatureT2Ref Reference temperature of secondary resistance [K]
LinearTemperatureCoefficient20alpha20_2 Temperature coefficient of secondary resistance at 20 degC [1/K]
InductanceL2sigma Secondary stray inductance per phase [H]

Connectors

TypeNameDescription
PositivePlugplug1Primary plug
NegativePlugplug2Secondary plug
ThermalPortTransformerthermalPort 
NegativePinstarpoint2 

Modelica definition

model Dy05 "Transformer Dy5"

  extends QuasiStationary.Machines.Interfaces.PartialBasicTransformer(
      final VectorGroup="Dy05");
  QuasiStationary.MultiPhase.Basic.Star star2(final m=m);
  QuasiStationary.SinglePhase.Interfaces.NegativePin starpoint2;
  QuasiStationary.MultiPhase.Basic.Delta Delta1(final m=m);
equation 
  connect(star2.pin_n, starpoint2);
  connect(Delta1.plug_p, r1.plug_p);
  connect(Delta1.plug_n, core.plug_n1);
  connect(l1sigma.plug_n, core.plug_p1);
  connect(core.plug_n2, core.plug_p3);
  connect(l2sigma.plug_p, core.plug_n3);
  connect(core.plug_p2, star2.plug_p);
end Dy05;

Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy07 Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy07

Transformer Dy7

Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy07

Information


Transformer Dy7

Typical parameters see: PartialBasicTransformer

Extends from QuasiStationary.Machines.Interfaces.PartialBasicTransformer (Partial model of threephase transformer).

Parameters

TypeNameDefaultDescription
Realn Ratio primary voltage (line-to-line) / secondary voltage (line-to-line)
BooleanuseThermalPortfalseEnable / disable (=fixed temperatures) thermal port
Operational temperatures
TemperatureT1Operational Operational temperature of primary resistance [K]
TemperatureT2Operational Operational temperature of secondary resistance [K]
Nominal resistances and inductances
ResistanceR1 Primary resistance per phase at TRef [Ohm]
TemperatureT1Ref Reference temperature of primary resistance [K]
LinearTemperatureCoefficient20alpha20_1 Temperature coefficient of primary resistance at 20 degC [1/K]
InductanceL1sigma Primary stray inductance per phase [H]
ResistanceR2 Secondary resistance per phase at TRef [Ohm]
TemperatureT2Ref Reference temperature of secondary resistance [K]
LinearTemperatureCoefficient20alpha20_2 Temperature coefficient of secondary resistance at 20 degC [1/K]
InductanceL2sigma Secondary stray inductance per phase [H]

Connectors

TypeNameDescription
PositivePlugplug1Primary plug
NegativePlugplug2Secondary plug
ThermalPortTransformerthermalPort 
NegativePinstarpoint2 

Modelica definition

model Dy07 "Transformer Dy7"

  extends QuasiStationary.Machines.Interfaces.PartialBasicTransformer(
      final VectorGroup="Dy07");
  QuasiStationary.MultiPhase.Basic.Star star2(final m=m);
  QuasiStationary.SinglePhase.Interfaces.NegativePin starpoint2;
  QuasiStationary.MultiPhase.Basic.Delta Delta1(final m=m);
  QuasiStationary.MultiPhase.Basic.Delta Rot2(final m=m);
equation 
  connect(star2.pin_n, starpoint2);
  connect(r1.plug_p, Delta1.plug_p);
  connect(Rot2.plug_p, l2sigma.plug_p);
  connect(l1sigma.plug_n, core.plug_p1);
  connect(Delta1.plug_n, core.plug_n1);
  connect(core.plug_n2, core.plug_p3);
  connect(core.plug_n3, star2.plug_p);
  connect(core.plug_p2, Rot2.plug_n);
end Dy07;

Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy09 Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy09

Transformer Dy9

Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy09

Information


Transformer Dy9

Typical parameters see: PartialBasicTransformer

Extends from QuasiStationary.Machines.Interfaces.PartialBasicTransformer (Partial model of threephase transformer).

Parameters

TypeNameDefaultDescription
Realn Ratio primary voltage (line-to-line) / secondary voltage (line-to-line)
BooleanuseThermalPortfalseEnable / disable (=fixed temperatures) thermal port
Operational temperatures
TemperatureT1Operational Operational temperature of primary resistance [K]
TemperatureT2Operational Operational temperature of secondary resistance [K]
Nominal resistances and inductances
ResistanceR1 Primary resistance per phase at TRef [Ohm]
TemperatureT1Ref Reference temperature of primary resistance [K]
LinearTemperatureCoefficient20alpha20_1 Temperature coefficient of primary resistance at 20 degC [1/K]
InductanceL1sigma Primary stray inductance per phase [H]
ResistanceR2 Secondary resistance per phase at TRef [Ohm]
TemperatureT2Ref Reference temperature of secondary resistance [K]
LinearTemperatureCoefficient20alpha20_2 Temperature coefficient of secondary resistance at 20 degC [1/K]
InductanceL2sigma Secondary stray inductance per phase [H]

Connectors

TypeNameDescription
PositivePlugplug1Primary plug
NegativePlugplug2Secondary plug
ThermalPortTransformerthermalPort 
NegativePinstarpoint2 

Modelica definition

model Dy09 "Transformer Dy9"

  extends QuasiStationary.Machines.Interfaces.PartialBasicTransformer(
      final VectorGroup="Dy09");
  QuasiStationary.MultiPhase.Basic.Star star2(final m=m);
  QuasiStationary.SinglePhase.Interfaces.NegativePin starpoint2;
  QuasiStationary.MultiPhase.Basic.Delta Delta1(final m=m);
  QuasiStationary.MultiPhase.Basic.Delta Rot2(final m=m);
equation 
  connect(star2.pin_n, starpoint2);
  connect(r1.plug_p, Delta1.plug_p);
  connect(l2sigma.plug_p, Rot2.plug_n);
  connect(l1sigma.plug_n, core.plug_p1);
  connect(Delta1.plug_n, core.plug_n1);
  connect(core.plug_n2, core.plug_p3);
  connect(core.plug_n3, Rot2.plug_p);
  connect(core.plug_p2, star2.plug_p);
end Dy09;

Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy11 Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy11

Transformer Dy11

Modelica.Electrical.QuasiStationary.Machines.BasicMachines.Transformers.Dy.Dy11

Information


Transformer Dy11

Typical parameters see: PartialBasicTransformer

Extends from QuasiStationary.Machines.Interfaces.PartialBasicTransformer (Partial model of threephase transformer).

Parameters

TypeNameDefaultDescription
Realn Ratio primary voltage (line-to-line) / secondary voltage (line-to-line)
BooleanuseThermalPortfalseEnable / disable (=fixed temperatures) thermal port
Operational temperatures
TemperatureT1Operational Operational temperature of primary resistance [K]
TemperatureT2Operational Operational temperature of secondary resistance [K]
Nominal resistances and inductances
ResistanceR1 Primary resistance per phase at TRef [Ohm]
TemperatureT1Ref Reference temperature of primary resistance [K]
LinearTemperatureCoefficient20alpha20_1 Temperature coefficient of primary resistance at 20 degC [1/K]
InductanceL1sigma Primary stray inductance per phase [H]
ResistanceR2 Secondary resistance per phase at TRef [Ohm]
TemperatureT2Ref Reference temperature of secondary resistance [K]
LinearTemperatureCoefficient20alpha20_2 Temperature coefficient of secondary resistance at 20 degC [1/K]
InductanceL2sigma Secondary stray inductance per phase [H]

Connectors

TypeNameDescription
PositivePlugplug1Primary plug
NegativePlugplug2Secondary plug
ThermalPortTransformerthermalPort 
NegativePinstarpoint2 

Modelica definition

model Dy11 "Transformer Dy11"

  extends QuasiStationary.Machines.Interfaces.PartialBasicTransformer(
      final VectorGroup="Dy11");
  QuasiStationary.MultiPhase.Basic.Star star2(final m=m);
  QuasiStationary.SinglePhase.Interfaces.NegativePin starpoint2;
  QuasiStationary.MultiPhase.Basic.Delta Delta1(final m=m);
equation 
  connect(star2.pin_n, starpoint2);
  connect(r1.plug_p, Delta1.plug_p);
  connect(l1sigma.plug_n, core.plug_p1);
  connect(Delta1.plug_n, core.plug_n1);
  connect(core.plug_n2, core.plug_p3);
  connect(core.plug_n3, star2.plug_p);
  connect(core.plug_p2, l2sigma.plug_p);
end Dy11;

Automatically generated Fri Nov 12 16:29:35 2010.