Buildings.Controls.OBC.ASHRAE.G36_PR1.AHUs.MultiZone.VAV.Economizers.Validation
Collection of validation models
Information
This package contains validation models for the classes in Buildings.Controls.OBC.ASHRAE.G36_PR1.AHUs.MultiZone.VAV.Economizers.
Note that most validation models contain simple input data which may not be realistic, but for which the correct output can be obtained through an analytic solution. The examples plot various outputs, which have been verified against these solutions. These model outputs are stored as reference data and used for continuous validation whenever models in the library change.
Package Content
| Name | Description |
|---|---|
 Controller_Disable
|
Validation model for disabling the multi zone VAV AHU economizer modulation and damper position limit control loops |
| Controller_Mod_DamLim
|
Validation model for multi zone VAV AHU economizer operation: damper modulation and minimum ooutdoor air requirement damper position limits |
Buildings.Controls.OBC.ASHRAE.G36_PR1.AHUs.MultiZone.VAV.Economizers.Validation.Controller_Disable
Validation model for disabling the multi zone VAV AHU economizer modulation and damper position limit control loops
Information
This example validates
Buildings.Controls.OBC.ASHRAE.G36_PR1.AHUs.MultiZone.VAV.Economizers.Controller
for control signals which disable modulation control loop only (economizer block)
and both minimum outdoor airflow and modulation control loops (economizer1 block).
Modelica definition
model Controller_Disable
"Validation model for disabling the multi zone VAV AHU economizer modulation and damper position limit control loops"
Buildings.Controls.OBC.ASHRAE.G36_PR1.AHUs.MultiZone.VAV.Economizers.Controller
economizer(
final use_enthalpy=true,
final retDamPhyPosMax=1,
final retDamPhyPosMin=0,
final outDamPhyPosMax=1,
final outDamPhyPosMin=0,
final use_TMix=false,
final use_G36FrePro=true) "Multi zone VAV AHU economizer ";
Buildings.Controls.OBC.ASHRAE.G36_PR1.AHUs.MultiZone.VAV.Economizers.Controller
economizer1(
final use_enthalpy=true,
final retDamPhyPosMax=1,
final retDamPhyPosMin=0,
final outDamPhyPosMax=1,
final outDamPhyPosMin=0,
final use_TMix=false,
final use_G36FrePro=true) "Multi zone VAV AHU economizer";
Buildings.Controls.OBC.ASHRAE.G36_PR1.AHUs.MultiZone.VAV.Economizers.Controller
economizer2(
final retDamPhyPosMax=1,
final retDamPhyPosMin=0,
final outDamPhyPosMax=1,
final outDamPhyPosMin=0,
final use_TMix=true,
final use_G36FrePro=false,
final use_enthalpy=false)
"Multi zone VAV AHU economizer with TMix freeze protection";
protected
final parameter Real TOutCutoff(
final unit="K",
final displayUnit="degC",
final quantity="ThermodynamicTemperature")=297.15
"Outdoor temperature high limit cutoff";
final parameter Real hOutCutoff(
final unit="J/kg",
final quantity="SpecificEnergy")=65100
"Outdoor air enthalpy high limit cutoff";
final parameter Real minVOutSet_flow(
final unit="m3/s",
final quantity="VolumeFlowRate")=0.71
"Example volumetric airflow setpoint, 15cfm/occupant, 100 occupants";
final parameter Real VOutMin_flow(
final unit="m3/s",
final quantity="VolumeFlowRate")=0.61
"Minimal measured volumetric airflow";
final parameter Real incVOutSet_flow(
final unit="m3/s",
final quantity="VolumeFlowRate")=(minVOutSet_flow - VOutMin_flow)*2.2
"Maximum volumetric airflow increase during the example simulation";
Buildings.Controls.OBC.CDL.Logical.Sources.Constant fanSta(final k=true)
"Fan is on";
Buildings.Controls.OBC.CDL.Integers.Sources.Constant freProSta(
final k=Buildings.Controls.OBC.ASHRAE.G36_PR1.Types.FreezeProtectionStages.stage1)
"Freeze protection status is 0";
Buildings.Controls.OBC.CDL.Integers.Sources.Constant freProSta2(
final k=Buildings.Controls.OBC.ASHRAE.G36_PR1.Types.FreezeProtectionStages.stage2)
"Freeze protection stage is 2";
Buildings.Controls.OBC.CDL.Integers.Sources.Constant opeMod(
final k=Buildings.Controls.OBC.ASHRAE.G36_PR1.Types.OperationModes.occupied)
"AHU operation mode is Occupied";
Buildings.Controls.OBC.CDL.Continuous.Sources.Constant hOutBelowCutoff(
final k=hOutCutoff - 40000) "Outdoor air enthalpy is below the cutoff";
Buildings.Controls.OBC.CDL.Continuous.Sources.Constant hOutCut(
final k=hOutCutoff) "Outdoor air enthalpy cutoff";
Buildings.Controls.OBC.CDL.Continuous.Sources.Constant TOutBelowCutoff(
final k=TOutCutoff - 30) "Outdoor air temperature is below the cutoff";
Buildings.Controls.OBC.CDL.Continuous.Sources.Constant TOutCut1(
final k=TOutCutoff) "Outdoor air temperature cutoff";
Buildings.Controls.OBC.CDL.Continuous.Sources.Constant VOutMinSet_flow(
final k=minVOutSet_flow)
"Outdoor airflow rate setpoint, example assumes 15cfm/occupant and 100 occupants";
Buildings.Controls.OBC.CDL.Continuous.Sources.Ramp VOut_flow(
final height=incVOutSet_flow,
final offset=VOutMin_flow,
final duration=1800) "Measured outdoor air volumetric airflow";
Buildings.Controls.OBC.CDL.Continuous.Sources.Ramp uTSup(
final duration=1800,
final height=1,
final offset=0) "Supply air temperature control signal";
Buildings.Controls.OBC.CDL.Continuous.Sources.Sine sin1(
amplitude=20,
freqHz=1/1800,
offset=272.15,
startTime=0) "Mixed air temerature";
equation
connect(fanSta.y, economizer.uSupFan);
connect(freProSta.y, economizer.uFreProSta);
connect(TOutBelowCutoff.y, economizer.TOut);
connect(TOutCut1.y, economizer.TOutCut);
connect(hOutBelowCutoff.y, economizer.hOut);
connect(hOutCut.y, economizer.hOutCut);
connect(VOut_flow.y, economizer.VOut_flow_normalized);
connect(VOutMinSet_flow.y, economizer.VOutMinSet_flow_normalized);
connect(TOutCut1.y, economizer1.TOutCut);
connect(TOutBelowCutoff.y, economizer1.TOut);
connect(hOutCut.y, economizer1.hOutCut);
connect(hOutBelowCutoff.y, economizer1.hOut);
connect(VOut_flow.y, economizer1.VOut_flow_normalized);
connect(VOutMinSet_flow.y, economizer1.VOutMinSet_flow_normalized);
connect(fanSta.y, economizer1.uSupFan);
connect(freProSta2.y, economizer1.uFreProSta);
connect(opeMod.y, economizer.uOpeMod);
connect(opeMod.y, economizer1.uOpeMod);
connect(uTSup.y, economizer.uTSup);
connect(uTSup.y, economizer1.uTSup);
connect(TOutBelowCutoff.y, economizer2.TOut);
connect(TOutCut1.y, economizer2.TOutCut);
connect(VOut_flow.y, economizer2.VOut_flow_normalized);
connect(VOutMinSet_flow.y, economizer2.VOutMinSet_flow_normalized);
connect(uTSup.y, economizer2.uTSup);
connect(fanSta.y, economizer2.uSupFan);
connect(opeMod.y, economizer2.uOpeMod);
connect(sin1.y, economizer2.TMix);
end Controller_Disable;
Buildings.Controls.OBC.ASHRAE.G36_PR1.AHUs.MultiZone.VAV.Economizers.Validation.Controller_Mod_DamLim
Validation model for multi zone VAV AHU economizer operation: damper modulation and minimum ooutdoor air requirement damper position limits
Information
This example validates
Buildings.Controls.OBC.ASHRAE.G36_PR1.AHUs.MultiZone.VAV.Economizers.Controller control loops:
minimum outdoor air damper position limits control loop (economizer block) and modulation
control loop (economizer1 block) for VOut_flow and TSup control signals.
Both control loops are enabled during the validation test.
Modelica definition
model Controller_Mod_DamLim
"Validation model for multi zone VAV AHU economizer operation: damper modulation and minimum ooutdoor air requirement damper position limits"
Buildings.Controls.OBC.ASHRAE.G36_PR1.AHUs.MultiZone.VAV.Economizers.Controller
economizer(
final use_TMix=true,
final use_enthalpy=true,
final use_G36FrePro=true) "Multi zone VAV AHU economizer";
Buildings.Controls.OBC.ASHRAE.G36_PR1.AHUs.MultiZone.VAV.Economizers.Controller
economizer1(
final use_enthalpy=false,
final use_TMix=true,
final use_G36FrePro=true) "Multi zone VAV AHU economizer";
protected
final parameter Real TOutCutoff(
final unit="K",
final displayUnit="degC",
final quantity="ThermodynamicTemperature")=297.15
"Outdoor temperature high limit cutoff";
final parameter Real hOutCutoff(
final unit="J/kg",
final quantity="SpecificEnergy")=65100
"Outdoor air enthalpy high limit cutoff";
final parameter Real minVOutSet_flow(
final unit="m3/s",
final quantity="VolumeFlowRate")=0.71
"Example volumetric airflow setpoint, 15cfm/occupant, 100 occupants";
final parameter Real VOutMin_flow(
final unit="m3/s",
final quantity="VolumeFlowRate")=0.61
"Minimal measured volumetric airflow";
final parameter Real incVOutSet_flow(
final unit="m3/s",
final quantity="VolumeFlowRate")=(minVOutSet_flow - VOutMin_flow)*2.2
"Maximum volumetric airflow increase during the example simulation";
Buildings.Controls.OBC.CDL.Logical.Sources.Constant fanSta(final k=true)
"Fan is on";
Buildings.Controls.OBC.CDL.Integers.Sources.Constant freProSta(
final k=Buildings.Controls.OBC.ASHRAE.G36_PR1.Types.FreezeProtectionStages.stage0)
"Freeze protection status is 0";
Buildings.Controls.OBC.CDL.Integers.Sources.Constant opeMod(
final k=Buildings.Controls.OBC.ASHRAE.G36_PR1.Types.OperationModes.occupied)
"AHU operation mode is Occupied";
Buildings.Controls.OBC.CDL.Continuous.Sources.Constant hOutBelowCutoff(
final k=hOutCutoff - 10000) "Outdoor air enthalpy is slightly below the cutoff";
Buildings.Controls.OBC.CDL.Continuous.Sources.Constant hOutCut(
final k=hOutCutoff) "Outdoor air enthalpy cutoff";
Buildings.Controls.OBC.CDL.Continuous.Sources.Constant TOutBelowCutoff(
final k=TOutCutoff - 5) "Outdoor air temperature is slightly below the cutoff";
Buildings.Controls.OBC.CDL.Continuous.Sources.Constant TOutCut1(
final k=TOutCutoff) "OA temperature high limit cutoff";
Buildings.Controls.OBC.CDL.Continuous.Sources.Constant TMixMea(
final k=303.15)
"Measured mixed air temperature above cutoff";
Buildings.Controls.OBC.CDL.Continuous.Sources.Constant VOutMinSet_flow(
final k=minVOutSet_flow)
"Outdoor airflow rate setpoint, example assumes 15cfm/occupant and 100 occupants";
Buildings.Controls.OBC.CDL.Continuous.Sources.Ramp VOut_flow(
final offset=VOutMin_flow,
final duration=900,
final height=incVOutSet_flow) "Measured outdoor air volumetric airflow";
Buildings.Controls.OBC.CDL.Continuous.Sources.Ramp uTSup(
final duration=1800,
final height=1,
final offset=0) "Supply air temperature control signal";
equation
connect(fanSta.y, economizer.uSupFan);
connect(freProSta.y, economizer.uFreProSta);
connect(opeMod.y, economizer.uOpeMod);
connect(TOutBelowCutoff.y, economizer.TOut);
connect(TOutCut1.y, economizer.TOutCut);
connect(VOut_flow.y, economizer.VOut_flow_normalized);
connect(VOutMinSet_flow.y, economizer.VOutMinSet_flow_normalized);
connect(TOutBelowCutoff.y, economizer1.TOut);
connect(TOutCut1.y, economizer1.TOutCut);
connect(VOutMinSet_flow.y, economizer1.VOutMinSet_flow_normalized);
connect(fanSta.y, economizer1.uSupFan);
connect(freProSta.y, economizer1.uFreProSta);
connect(opeMod.y, economizer1.uOpeMod);
connect(uTSup.y, economizer.uTSup);
connect(uTSup.y, economizer1.uTSup);
connect(economizer1.TMix, TMixMea.y);
connect(hOutCut.y, economizer.hOutCut);
connect(hOutBelowCutoff.y, economizer.hOut);
connect(TMixMea.y, economizer.TMix);
connect(VOut_flow.y, economizer1.VOut_flow_normalized);
end Controller_Mod_DamLim;