Buildings.Electrical.AC.ThreePhasesUnbalanced.Validation.IEEETests.Test4NodesFeeder.BaseClasses
This package contains the base classes used by the IEEE 4 nodes test feeder
Information
This package contains base classes used by the models that are part of the package Buildings.Electrical.AC.ThreePhasesUnbalanced.Validation.IEEETests.Test4NodesFeeder.
Extends from Modelica.Icons.BasesPackage (Icon for packages containing base classes).
Package Content
| Name | Description |
|---|---|
 IEEE4
|
Base model of the IEEE 4 nodes test feeder |
Buildings.Electrical.AC.ThreePhasesUnbalanced.Validation.IEEETests.Test4NodesFeeder.BaseClasses.IEEE4
Base model of the IEEE 4 nodes test feeder
Information
This is a partial model that is extended by all the other validation test cases. This model defined replaceable probes and transformer so they can be easily changed when implementing the different tests.
More information can be found in each model that extends this one.
Reference results
The reference results for the tests are saved as parameter of the model and compared to the simulated ones. The error between the results (herein called Xmodel) and the references (herein called Xref) are computed in both absolute and relative way. Note that Xmodel and Xref can be either voltage amplitudes or phase angles.
Errabs = Xmodel - Xref
Err% = Errabs / Xref
The variables that store the results of the comparison are listed in the table below
| Variable | Description | Unit |
|---|---|---|
err_V2[3] |
Error between simulated voltage at node 2 and reference results | [V] |
err_V3[3] |
Error between simulated voltage at node 3 and reference results | [V] |
err_V4[3] |
Error between simulated voltage at node 4 and reference results | [V] |
err_Theta2[3] |
Error between simulated phase angle at node 2 and reference phase angle | [rad], displayed as [deg] |
err_Theta3[3] |
Error between simulated phase angle at node 2 and reference phase angle | [rad], displayed as [deg] |
err_Theta4[3] |
Error between simulated phase angle at node 2 and reference phase angle | [rad], displayed as [deg] |
err_V2_percent[3] |
Relative error between simulated voltage at node 2 and reference results | [%] |
err_V3_percent[3] |
Relative error between simulated voltage at node 3 and reference results | [%] |
err_V4_percent[3] |
Relative error between simulated voltage at node 4 and reference results | [%] |
err_Theta2_percent[3] |
Relative error between simulated phase angle at node 2 and reference phase angle | [%] |
err_Theta3_percent[3] |
Relative error between simulated phase angle at node 2 and reference phase angle | [%] |
err_Theta4_percent[3] |
Relative error between simulated phase angle at node 2 and reference phase angle | [%] |
Extends from Modelica.Icons.Example (Icon for runnable examples).
Parameters
| Type | Name | Default | Description |
|---|---|---|---|
| Voltage | VLL_side1 | 12.47e3 | Voltage line to line side 1 [V] |
| Voltage | VLL_side2 | 4.16e3 | Voltage line to line side 2 [V] |
| ApparentPower | VARbase | 6000e3 | Base VA power of the transformer [V.A] |
| Boolean | line1_use_Z_y | true | Choose between Zy or Zd impedance matrix for line 1 |
| Boolean | line2_use_Z_y | true | Choose between Zy or Zd impedance matrix for line 2 |
| Voltage | V2_ref[3] | {7107,7140,7121} | Reference RMS voltage node 2 - IEEE results [V] |
| Voltage | V3_ref[3] | {2247,2269,2256} | Reference RMS voltage node 3 - IEEE results [V] |
| Voltage | V4_ref[3] | {1918,2061,1981} | Reference RMS voltage node 4 - IEEE results [V] |
| Angle | Theta2_ref[3] | {-0.3,-120.3,119.6} | Reference voltage phase angle node 2 - IEEE results [rad] |
| Angle | Theta3_ref[3] | {-3.7,-123.5,116.4} | Reference voltage phase angle node 3 - IEEE results [rad] |
| Angle | Theta4_ref[3] | {-9.1,-128.3,110.9} | Reference voltage phase angle node 4 - IEEE results [rad] |
| GeneralizedProbe | node1 | node1(perUnit=false, V_nomin... | Probe at source |
| GeneralizedProbe | node2 | node2(perUnit=false, V_nomin... | Probe at the primary side of the transformer |
| GeneralizedProbe | node3 | node3(perUnit=false, V_nomin... | Probe at the secondary side of the transformer |
| GeneralizedProbe | node4 | node4(perUnit=false, V_nomin... | Probe at the load |
Modelica definition
partial model IEEE4 "Base model of the IEEE 4 nodes test feeder"
extends Modelica.Icons.Example;
parameter Modelica.Units.SI.Voltage VLL_side1=12.47e3
"Voltage line to line side 1";
parameter Modelica.Units.SI.Voltage VLL_side2=4.16e3
"Voltage line to line side 2";
parameter Modelica.Units.SI.ApparentPower VARbase=6000e3
"Base VA power of the transformer";
parameter Boolean line1_use_Z_y = true
"Choose between Zy or Zd impedance matrix for line 1";
parameter Boolean line2_use_Z_y = true
"Choose between Zy or Zd impedance matrix for line 2";
parameter Modelica.Units.SI.Voltage V2_ref[3]={7107,7140,7121}
"Reference RMS voltage node 2 - IEEE results";
parameter Modelica.Units.SI.Voltage V3_ref[3]={2247,2269,2256}
"Reference RMS voltage node 3 - IEEE results";
parameter Modelica.Units.SI.Voltage V4_ref[3]={1918,2061,1981}
"Reference RMS voltage node 4 - IEEE results";
parameter Modelica.Units.SI.Angle Theta2_ref[3](each displayUnit="deg") = {-0.3,
-120.3,119.6} "Reference voltage phase angle node 2 - IEEE results";
parameter Modelica.Units.SI.Angle Theta3_ref[3](each displayUnit="deg") = {-3.7,
-123.5,116.4} "Reference voltage phase angle node 3 - IEEE results";
parameter Modelica.Units.SI.Angle Theta4_ref[3](each displayUnit="deg") = {-9.1,
-128.3,110.9} "Reference voltage phase angle node 4 - IEEE results";
Modelica.Units.SI.Voltage err_V2[3]=node2.V - V2_ref
"Error on voltage at node 2";
Modelica.Units.SI.Voltage err_V3[3]=node3.V - V3_ref
"Error on voltage at node 3";
Modelica.Units.SI.Voltage err_V4[3]=node4.V - V4_ref
"Error on voltage at node 4";
Modelica.Units.SI.Angle err_Theta2[3](each displayUnit="deg") = node2.theta
- Theta2_ref "Error on voltage at node 2";
Modelica.Units.SI.Angle err_Theta3[3](each displayUnit="deg") = node3.theta
- Theta3_ref "Error on voltage at node 3";
Modelica.Units.SI.Angle err_Theta4[3](each displayUnit="deg") = node4.theta
- Theta4_ref "Error on voltage at node 4";
Real err_V2_percent[3] = 100*{err_V2[i]/V2_ref[i] for i in 1:3}
"Error in RMS voltage at node 2 -- percent";
Real err_V3_percent[3] = 100*{err_V3[i]/V3_ref[i] for i in 1:3}
"Error in RMS voltage at node 3 -- percent";
Real err_V4_percent[3] = 100*{err_V4[i]/V4_ref[i] for i in 1:3}
"Error in RMS voltage at node 4 -- percent";
Real err_Theta2_percent[3] = 100*{err_Theta2[i]/Theta2_ref[i] for i in 1:3}
"Error in voltage phase angle at node 2 -- percent";
Real err_Theta3_percent[3] = 100*{err_Theta3[i]/Theta3_ref[i] for i in 1:3}
"Error in voltage phase angle at node 3 -- percent";
Real err_Theta4_percent[3] = 100*{err_Theta4[i]/Theta4_ref[i] for i in 1:3}
"Error in voltage phase angle at node 4 -- percent";
Buildings.Electrical.AC.ThreePhasesUnbalanced.Sources.FixedVoltage source(
f=60,
V=VLL_side1) "Voltage source";
Buildings.Electrical.AC.ThreePhasesUnbalanced.Lines.TwoPortMatrixRL line1(
Z11=L1*(if line1_use_Z_y then Z11_y else Z11_d),
Z12=L1*(if line1_use_Z_y then Z12_y else Z12_d),
Z13=L1*(if line1_use_Z_y then Z13_y else Z13_d),
Z22=L1*(if line1_use_Z_y then Z22_y else Z22_d),
Z23=L1*(if line1_use_Z_y then Z23_y else Z23_d),
Z33=L1*(if line1_use_Z_y then Z33_y else Z33_d),
V_nominal=VLL_side1) "Line at primary side";
Buildings.Electrical.AC.ThreePhasesUnbalanced.Lines.TwoPortMatrixRL line2(
Z11=L2*(if line2_use_Z_y then Z11_y else Z11_d),
Z12=L2*(if line2_use_Z_y then Z12_y else Z12_d),
Z13=L2*(if line2_use_Z_y then Z13_y else Z13_d),
Z22=L2*(if line2_use_Z_y then Z22_y else Z22_d),
Z23=L2*(if line2_use_Z_y then Z23_y else Z23_d),
Z33=L2*(if line2_use_Z_y then Z33_y else Z33_d),
V_nominal=VLL_side2) "Line at secondary side";
Buildings.Electrical.AC.ThreePhasesUnbalanced.Loads.Inductive loadRL(
pf=0.9,
V_nominal=VLL_side2,
mode=Buildings.Electrical.Types.Load.VariableZ_P_input,
use_pf_in=true) "Load";
replaceable Buildings.Electrical.AC.ThreePhasesUnbalanced.Sensors.BaseClasses.GeneralizedProbe
node1(perUnit=false, V_nominal=VLL_side1) "Probe at source";
replaceable Buildings.Electrical.AC.ThreePhasesUnbalanced.Sensors.BaseClasses.GeneralizedProbe
node2(perUnit=false, V_nominal=VLL_side1)
"Probe at the primary side of the transformer";
replaceable Buildings.Electrical.AC.ThreePhasesUnbalanced.Sensors.BaseClasses.GeneralizedProbe
node3(perUnit=false, V_nominal=VLL_side2)
"Probe at the secondary side of the transformer";
replaceable Buildings.Electrical.AC.ThreePhasesUnbalanced.Sensors.BaseClasses.GeneralizedProbe
node4(perUnit=false, V_nominal=VLL_side2) "Probe at the load";
protected
parameter Real L1 = 2000*(1.0/5280.0) "Length line 1 in miles";
parameter Real L2 = 2500*(1.0/5280.0) "Length line 2 in miles";
parameter Modelica.Units.SI.Impedance Z11_d[2]={0.4013,1.4133}
"Element [1,1] of impedance matrix";
parameter Modelica.Units.SI.Impedance Z12_d[2]={0.0953,0.8515}
"Element [1,2] of impedance matrix";
parameter Modelica.Units.SI.Impedance Z13_d[2]={0.0953,0.7266}
"Element [1,3] of impedance matrix";
parameter Modelica.Units.SI.Impedance Z22_d[2]={0.4013,1.4133}
"Element [2,2] of impedance matrix";
parameter Modelica.Units.SI.Impedance Z23_d[2]={0.0953,0.7802}
"Element [2,3] of impedance matrix";
parameter Modelica.Units.SI.Impedance Z33_d[2]={0.4013,1.4133}
"Element [3,3] of impedance matrix";
parameter Modelica.Units.SI.Impedance Z11_y[2]={0.4576,1.078}
"Element [1,1] of impedance matrix";
parameter Modelica.Units.SI.Impedance Z12_y[2]={0.1559,0.5017}
"Element [1,2] of impedance matrix";
parameter Modelica.Units.SI.Impedance Z13_y[2]={0.1535,0.3849}
"Element [1,3] of impedance matrix";
parameter Modelica.Units.SI.Impedance Z22_y[2]={0.4666,1.0482}
"Element [2,2] of impedance matrix";
parameter Modelica.Units.SI.Impedance Z23_y[2]={0.158,0.4236}
"Element [2,3] of impedance matrix";
parameter Modelica.Units.SI.Impedance Z33_y[2]={0.4615,1.0651}
"Element [3,3] of impedance matrix";
equation
connect(source.terminal, line1.terminal_n);
connect(line2.terminal_p, loadRL.terminal);
end IEEE4;