Buildings.Applications.BaseClasses.Controls

Package with control components for Buildings.Applications examples

Information

Collection of models for the control of equipment in Buildings.Applications.

Extends from Modelica.Icons.Package (Icon for standard packages).

Package Content

Name Description
Buildings.Applications.BaseClasses.Controls.VariableSpeedPumpStage VariableSpeedPumpStage Staging control for variable speed pumps
Buildings.Applications.BaseClasses.Controls.Validation Validation Collection of validation models

Buildings.Applications.BaseClasses.Controls.VariableSpeedPumpStage Buildings.Applications.BaseClasses.Controls.VariableSpeedPumpStage

Staging control for variable speed pumps

Buildings.Applications.BaseClasses.Controls.VariableSpeedPumpStage

Information

This model implements a simple staging control logic for variable speed pumps.

Extends from Modelica.Blocks.Icons.Block (Basic graphical layout of input/output block).

Parameters

TypeNameDefaultDescription
TimetWai Waiting time [s]
MassFlowRatem_flow_nominal Nominal mass flow rate of the identical variable-speed pumps [kg/s]
RealminSpe0.05Minimum speed ratio required by variable speed pumps [1]
MassFlowRatecriPoiFlo0.7*m_flow_nominalCritcal point of flowrate for switch pump on or off [kg/s]
MassFlowRatedeaBanFlo0.1*m_flow_nominalDeadband for critical point of flowrate [kg/s]
RealcriPoiSpe0.5Critical point of speed signal for switching on or off
RealdeaBanSpe0.3Deadband for critical point of speed signal

Connectors

TypeNameDescription
input RealInputmasFloPumTotal mass flowrate in the variable speed pumps
input RealInputspeSigSpeed signal
output RealOutputy[2]On/off signal - 0: off; 1: on

Modelica definition

model VariableSpeedPumpStage "Staging control for variable speed pumps" extends Modelica.Blocks.Icons.Block; parameter Modelica.Units.SI.Time tWai "Waiting time"; parameter Modelica.Units.SI.MassFlowRate m_flow_nominal "Nominal mass flow rate of the identical variable-speed pumps"; parameter Real minSpe(unit="1",min=0,max=1) = 0.05 "Minimum speed ratio required by variable speed pumps"; parameter Modelica.Units.SI.MassFlowRate criPoiFlo=0.7*m_flow_nominal "Critcal point of flowrate for switch pump on or off"; parameter Modelica.Units.SI.MassFlowRate deaBanFlo=0.1*m_flow_nominal "Deadband for critical point of flowrate"; parameter Real criPoiSpe = 0.5 "Critical point of speed signal for switching on or off"; parameter Real deaBanSpe = 0.3 "Deadband for critical point of speed signal"; Modelica.Blocks.Interfaces.RealInput masFloPum "Total mass flowrate in the variable speed pumps"; Modelica.Blocks.Interfaces.RealInput speSig "Speed signal"; Modelica.Blocks.Interfaces.RealOutput y[2] "On/off signal - 0: off; 1: on"; Modelica.StateGraph.Transition con1( enableTimer=true, waitTime=tWai, condition=speSig > minSpe) "Fire condition 1: free cooling to partially mechanical cooling"; Modelica.StateGraph.StepWithSignal oneOn(nIn=2, nOut=2) "One chiller is commanded on"; Modelica.StateGraph.InitialStep off(nIn=1, nOut=1) "Free cooling mode"; Modelica.StateGraph.StepWithSignal twoOn(nIn=1, nOut=1) "Two chillers are commanded on"; Modelica.StateGraph.Transition con2( enableTimer=true, waitTime=tWai, condition=speSig > criPoiSpe + deaBanSpe and masFloPum > criPoiFlo + deaBanFlo) "Fire condition 2: partially mechanical cooling to fully mechanical cooling"; Modelica.StateGraph.Transition con3( enableTimer=true, waitTime=tWai, condition=speSig < criPoiSpe - deaBanSpe or masFloPum < criPoiFlo - deaBanFlo) "Fire condition 3: fully mechanical cooling to partially mechanical cooling"; Modelica.StateGraph.Transition con4( enableTimer=true, waitTime=tWai, condition=speSig <= minSpe) "Fire condition 4: partially mechanical cooling to free cooling"; inner Modelica.StateGraph.StateGraphRoot stateGraphRoot; Modelica.Blocks.Tables.CombiTable1Ds combiTable1Ds( table=[0,0,0; 1,1,0; 2,1,1]) "Determine which pump should be on - rotation control is not considered here"; Buildings.Controls.OBC.CDL.Conversions.BooleanToInteger booToInt( final integerTrue=1, final integerFalse=0); Buildings.Controls.OBC.CDL.Conversions.BooleanToInteger booToInt1( final integerFalse=0, final integerTrue=2); Buildings.Controls.OBC.CDL.Integers.Add addInt; Buildings.Controls.OBC.CDL.Conversions.IntegerToReal intToRea; equation connect(off.outPort[1], con1.inPort); connect(con1.outPort, oneOn.inPort[1]); connect(con2.inPort, oneOn.outPort[1]); connect(con2.outPort, twoOn.inPort[1]); connect(twoOn.outPort[1], con3.inPort); connect(con4.outPort, off.inPort[1]); connect(con3.outPort, oneOn.inPort[2]); connect(con4.inPort, oneOn.outPort[2]); connect(combiTable1Ds.y, y); connect(booToInt.u, oneOn.active); connect(twoOn.active, booToInt1.u); connect(booToInt.y, addInt.u1); connect(booToInt1.y, addInt.u2); connect(addInt.y, intToRea.u); connect(intToRea.y, combiTable1Ds.u); end VariableSpeedPumpStage;