model MultiZone "Multiple thermal zone models" package MediumA = Buildings.Media.Air "Medium model"; parameter Integer nZon(min=1) = 1 "Number of zones per floor"; parameter Integer nFlo(min=1) = 1 "Number of floors"; parameter Modelica.SIunits.Angle lat=41.98*3.14159/180 "Latitude"; parameter Real ampFactor[nZon]= if nZon<=5 then {abs(cos(i*3.1415926/(nZon))) for i in 1:nZon} else {abs(cos(i*3.1415926/5)) for i in 1:nZon} "IHG fluctuating amplitude factor"; Modelica.Fluid.Vessels.BaseClasses.VesselFluidPorts_b portsIn[nZon,nFlo]( redeclare each package Medium = MediumA) "Fluid inlets"; Modelica.Fluid.Vessels.BaseClasses.VesselFluidPorts_b portsOut[nZon,nFlo]( redeclare each package Medium = MediumA) "Fluid outlets"; Modelica.Blocks.Interfaces.RealOutput TRooAir[nZon,nFlo] "Room air temperatures"; Modelica.Blocks.Interfaces.RealOutput heaCooPow[nZon,nFlo] "HVAC power"; Buildings.Examples.ScalableBenchmarks.BuildingVAV.ThermalZones.ThermalZone theZon[nZon,nFlo]( redeclare each package MediumA = MediumA, each final lat=lat, gainFactor={{ampFactor[i] for j in 1:nFlo} for i in 1:nZon}) "Thermal zone model"; Buildings.BoundaryConditions.WeatherData.Bus weaBus "Weather data bus"; equation for iZon in 1:nZon-1 loop for iFlo in 1:nFlo-1 loop connect(theZon[iZon, iFlo].heaPorFlo, theZon[iZon, if iFlo == nFlo then 1 else iFlo+1].heaPorCei); connect(theZon[iZon, iFlo].heaPorWal1, theZon[if iZon == nZon then 1 else iZon+1, iFlo].heaPorWal2); end for; end for; for iZon in 1:nZon loop for iFlo in 1:nFlo loop connect(weaBus, theZon[iZon, iFlo].weaBus); connect(portsIn[iZon, iFlo], theZon[iZon, iFlo].portsInOut[1]); connect(portsOut[iZon, iFlo], theZon[iZon, iFlo].portsInOut[2]); connect(theZon[iZon, iFlo].heaCooPow, heaCooPow[iZon, iFlo]); connect(theZon[iZon, iFlo].TRooAir, TRooAir[iZon, iFlo]); end for; end for; end MultiZone;

model ThermalZone "Thermal zone model" replaceable package MediumA = Modelica.Media.Interfaces.PartialMedium "Medium model"; parameter Modelica.SIunits.Angle lat "Latitude"; parameter Real gainFactor(start=1) "IHG fluctuating amplitude factor"; parameter Real VInf_flow=(roo.AFlo*roo.hRoo)*0.5/3600 "Infiltration volume flow rate"; final parameter Modelica.SIunits.Angle S_= Buildings.Types.Azimuth.S "Azimuth for south walls"; final parameter Modelica.SIunits.Angle E_= Buildings.Types.Azimuth.E "Azimuth for east walls"; final parameter Modelica.SIunits.Angle W_= Buildings.Types.Azimuth.W "Azimuth for west walls"; final parameter Modelica.SIunits.Angle N_= Buildings.Types.Azimuth.N "Azimuth for north walls"; final parameter Modelica.SIunits.Angle C_= Buildings.Types.Tilt.Ceiling "Tilt for ceiling"; final parameter Modelica.SIunits.Angle F_= Buildings.Types.Tilt.Floor "Tilt for floor"; final parameter Modelica.SIunits.Angle Z_= Buildings.Types.Tilt.Wall "Tilt for wall"; final parameter HeatTransfer.Data.Solids.Plywood matFur(x=0.15, nStaRef=5) "Material for furniture"; final parameter HeatTransfer.Data.Solids.Concrete matCon( x=0.1, k=1.311, c=836, nStaRef=5) "Concrete"; final parameter HeatTransfer.Data.Solids.Plywood matWoo( x=0.01, k=0.11, d=544, nStaRef=1) "Wood for exterior construction"; final parameter HeatTransfer.Data.Solids.Generic matIns( x=0.087, k=0.049, c=836.8, d=265, nStaRef=5) "Steelframe construction with insulation"; final parameter HeatTransfer.Data.Solids.GypsumBoard matGyp( x=0.0127, k=0.16, c=830, d=784, nStaRef=2) "Gypsum board"; final parameter HeatTransfer.Data.Solids.GypsumBoard matGyp2( x=0.025, k=0.16, c=830, d=784, nStaRef=2) "Gypsum board"; final parameter HeatTransfer.Data.OpaqueConstructions.Generic conExtWal( final nLay=3, material={matWoo,matIns,matGyp}) "Exterior construction"; final parameter HeatTransfer.Data.OpaqueConstructions.Generic conIntWal( final nLay=1, material={matGyp2}) "Interior wall construction"; final parameter HeatTransfer.Data.OpaqueConstructions.Generic conFlo( final nLay=1, material={matCon}) "Floor construction (opa_a is carpet)"; final parameter HeatTransfer.Data.Solids.Plywood matCarTra( k=0.11, d=544, nStaRef=1, x=0.215/0.11) "Wood for floor"; final parameter HeatTransfer.Data.GlazingSystems.DoubleClearAir13Clear glaSys( UFra=2, shade=Buildings.HeatTransfer.Data.Shades.Gray(), haveInteriorShade=false, haveExteriorShade=false) "Data record for the glazing system"; Modelica.Blocks.Interfaces.RealOutput TRooAir "Room air temperatures"; Modelica.Blocks.Interfaces.RealOutput heaCooPow "HVAC power"; Modelica.Fluid.Vessels.BaseClasses.VesselFluidPorts_b portsInOut[2]( redeclare package Medium = MediumA) "Fluid inlets and outlets"; Buildings.Fluid.Sensors.TemperatureTwoPort supAirTem( redeclare package Medium = MediumA, m_flow_nominal=1, tau=0) "Supply air temperature sensor"; Buildings.Fluid.Sensors.TemperatureTwoPort retAirTem( redeclare package Medium = MediumA, m_flow_nominal=1, tau=0) "Return air temperature sensor"; Buildings.Fluid.Sensors.MassFlowRate supplyAirFlow( redeclare package Medium = MediumA) "Supply air flow rate"; Modelica.Thermal.HeatTransfer.Interfaces.HeatPort_a heaPorWal1 "Heat port connected to common wall"; Modelica.Thermal.HeatTransfer.Interfaces.HeatPort_a heaPorFlo "Heat port connected to floor"; Modelica.Thermal.HeatTransfer.Interfaces.HeatPort_b heaPorCei "Heat port connected to ceiling"; Modelica.Thermal.HeatTransfer.Interfaces.HeatPort_b heaPorWal2 "Heat port connected to common wall"; Buildings.ThermalZones.Detailed.MixedAir roo( redeclare package Medium = MediumA, hRoo=2.7, nPorts=4, energyDynamics=Modelica.Fluid.Types.Dynamics.FixedInitial, AFlo=6*8, datConExtWin( layers={conExtWal}, A={8*2.7}, glaSys={glaSys}, wWin={2*3}, hWin={2}, fFra={0.001}, til={Z_}, azi={S_}), datConBou( layers={conFlo, conIntWal}, A={6*8, 6*2.7}, til={F_, Z_}), surBou( A={6*8, 6*2.7}, til={C_, Z_}, absIR = {conFlo.absIR_a, conIntWal.absIR_a}, absSol = {conFlo.absSol_a, conIntWal.absSol_a}), datConPar( layers={conIntWal}, A={8*2.7/2}, til={Buildings.Types.Tilt.Wall}), nConExt=0, nConPar=1, nSurBou=2, nConBou=2, nConExtWin=1, lat=lat) "Room model, adapted from BESTEST Case 600 and VAVReheat model (for constructions)"; Modelica.Blocks.Sources.Constant qConGai_flow(k=579/48) "Convective heat gain"; Modelica.Blocks.Sources.Constant qRadGai_flow(k=689/48) "Radiative heat gain"; Modelica.Blocks.Sources.Constant qLatGai_flow(k=146.5/48) "Latent heat gain"; Modelica.Blocks.Routing.Multiplex3 multiplex3_1 "Sum of heat gain"; Modelica.Blocks.Sources.Constant uSha(k=0) "Control signal for the shading device"; Buildings.Fluid.Sources.Outside sinInf( redeclare package Medium = MediumA, nPorts=1) "Sink model for air infiltration"; Buildings.BoundaryConditions.WeatherData.Bus weaBus "Weather data bus"; Modelica.Blocks.Math.Product product1 "Scheduled radiative heat gain"; Modelica.Blocks.Math.Gain gain(k=gainFactor) "Factorized radiative heat gain"; Modelica.Blocks.Math.Product product2 "Scheduled convective heat gain"; Modelica.Blocks.Math.Gain gain1(k=gainFactor) "Factorized convective heat gain"; Modelica.Blocks.Math.Product product3 "Scheduled latent heat gain"; Modelica.Blocks.Math.Gain gain2(k=gainFactor) "Factorized latent heat gain"; Modelica.Blocks.Sources.RealExpression powCal(y=supplyAirFlow.m_flow*1005*( supAirTem.T - TRooAir)) "Power calculation, with cooling negative and heating positive"; Modelica.Thermal.HeatTransfer.Sensors.TemperatureSensor rooAirTem "Air temperature sensor"; Buildings.Examples.ScalableBenchmarks.BuildingVAV.BaseClasses.IntLoad intLoad( table=[0,0.1; ((gainFactor - 0.5) + 8)*3600,1.0; ((gainFactor - 0.5) + 18)*3600,0.1; 24*3600,0.1]) "Internal load schedule"; Fluid.Sources.MassFlowSource_T souInf( redeclare package Medium = MediumA, nPorts=1, use_m_flow_in=false, m_flow=-VInf_flow*1.2) "Source model for air infiltration"; Fluid.FixedResistances.PressureDrop res( redeclare package Medium = MediumA, m_flow_nominal=VInf_flow*1.2, dp_nominal=20, linearized=true) "Pressure drop for infiltration"; equation connect(multiplex3_1.y, roo.qGai_flow); connect(roo.surf_conBou[1], heaPorFlo); connect(roo.surf_conBou[2], heaPorWal1); connect(roo.surf_surBou[1], heaPorCei); connect(roo.surf_surBou[1], heaPorWal2); connect(uSha.y, roo.uSha[1]); connect(weaBus, roo.weaBus); connect(sinInf.weaBus, weaBus); connect(qLatGai_flow.y, product3.u1); connect(product3.y, gain2.u); connect(product2.y, gain1.u); connect(product1.y, gain.u); connect(gain1.y, multiplex3_1.u2[1]); connect(qConGai_flow.y, product2.u1); connect(qRadGai_flow.y, product1.u1); connect(gain.y, multiplex3_1.u1[1]); connect(gain2.y, multiplex3_1.u3[1]); connect(intLoad.y[1], product1.u2); connect(product1.u2, product2.u2); connect(product1.u2, product3.u2); connect(souInf.ports[1], roo.ports[1]); connect(sinInf.ports[1], res.port_a); connect(res.port_b, roo.ports[2]); connect(supAirTem.port_a,supplyAirFlow.port_b); connect(portsInOut[1],supplyAirFlow.port_a); connect(portsInOut[2],retAirTem.port_b); connect(rooAirTem.T, TRooAir); connect(powCal.y, heaCooPow); connect(supAirTem.port_b, roo.ports[3]); connect(retAirTem.port_a, roo.ports[4]); connect(roo.heaPorAir, rooAirTem.port); end ThermalZone;