NREL · Myoldmopar · Mar 4, 2021 · Feb 9, 2021 · Feb 15, 2021 · Feb 16, 2021
diff --git a/src/EnergyPlus/ChilledCeilingPanelSimple.cc b/src/EnergyPlus/ChilledCeilingPanelSimple.cc
@@ -1708,12 +1708,10 @@ namespace EnergyPlus::CoolingPanelSimple {
 
         SumHATsurf = 0.0;
 
-        for (SurfNum = state.dataHeatBal->Zone(ZoneNum).SurfaceFirst; SurfNum <= state.dataHeatBal->Zone(ZoneNum).SurfaceLast; ++SurfNum) {
+        for (SurfNum = state.dataHeatBal->Zone(ZoneNum).HTSurfaceFirst; SurfNum <= state.dataHeatBal->Zone(ZoneNum).HTSurfaceLast; ++SurfNum) {
 
             auto &ThisSurf(Surface(SurfNum));
 
-            if (!ThisSurf.HeatTransSurf) continue; // Skip non-heat transfer surfaces
-
             Area = ThisSurf.Area;
 
             if (ThisSurf.Class == DataSurfaces::SurfaceClass::Window) {

diff --git a/src/EnergyPlus/ConvectionCoefficients.cc b/src/EnergyPlus/ConvectionCoefficients.cc
@@ -251,9 +251,7 @@ namespace ConvectionCoefficients {
         }
         for (ZoneNum = 1; ZoneNum <= state.dataGlobal->NumOfZones; ++ZoneNum) {
 
-            for (SurfNum = Zone(ZoneNum).SurfaceFirst; SurfNum <= Zone(ZoneNum).SurfaceLast; ++SurfNum) {
-
-                if (!Surface(SurfNum).HeatTransSurf) continue; // Skip non-heat transfer surfaces
+            for (SurfNum = Zone(ZoneNum).HTSurfaceFirst; SurfNum <= Zone(ZoneNum).HTSurfaceLast; ++SurfNum) {
 
                 if (present(ZoneToResimulate)) {
                     if ((ZoneNum != ZoneToResimulate) && (AdjacentZoneToSurface(SurfNum) != ZoneToResimulate)) {
@@ -2743,9 +2741,7 @@ namespace ConvectionCoefficients {
 
         Real64 AirHumRat = DataHeatBalFanSys::ZoneAirHumRatAvg(ZoneNum);
 
-        for (auto SurfNum = Zone(ZoneNum).SurfaceFirst; SurfNum <= Zone(ZoneNum).SurfaceLast; ++SurfNum) {
-            if (!Surface(SurfNum).HeatTransSurf) continue; // Skip non-heat transfer surfaces
-
+        for (auto SurfNum = Zone(ZoneNum).HTSurfaceFirst; SurfNum <= Zone(ZoneNum).HTSurfaceLast; ++SurfNum) {
             if (Surface(SurfNum).ExtBoundCond == DataSurfaces::KivaFoundation) {
                 state.dataSurfaceGeometry->kivaManager.surfaceConvMap[SurfNum].in = [=, &state](double Tsurf, double Tamb, double, double, double cosTilt) -> double {
                     return CalcCeilingDiffuserIntConvCoeff(
@@ -2830,9 +2826,7 @@ namespace ConvectionCoefficients {
             }
         }
 
-        for (SurfNum = Zone(ZoneNum).SurfaceFirst; SurfNum <= Zone(ZoneNum).SurfaceLast; ++SurfNum) {
-            if (!Surface(SurfNum).HeatTransSurf) continue; // Skip non-heat transfer surfaces
-
+        for (SurfNum = Zone(ZoneNum).HTSurfaceFirst; SurfNum <= Zone(ZoneNum).HTSurfaceLast; ++SurfNum) {
             if (ACH <= 3.0) { // Use the other convection algorithm
                 if (!state.dataConstruction->Construct(Surface(SurfNum).Construction).TypeIsWindow) {
                     CalcASHRAEDetailedIntConvCoeff(state, SurfNum, SurfaceTemperatures(SurfNum), MAT(ZoneNum));
@@ -2928,7 +2922,7 @@ namespace ConvectionCoefficients {
         HConvNet = 0.0;
 
         // determine major width and minor width
-        for (SurfNum = Zone(ZoneNum).SurfaceFirst; SurfNum <= Zone(ZoneNum).SurfaceLast; ++SurfNum) {
+        for (SurfNum = Zone(ZoneNum).HTSurfaceFirst; SurfNum <= Zone(ZoneNum).HTSurfaceLast; ++SurfNum) {
             if (Surface(SurfNum).Class != SurfaceClass::Wall) continue;
 
             if (Surface(SurfNum).Width > majorW) {
@@ -2941,7 +2935,7 @@ namespace ConvectionCoefficients {
         }
 
         // assign major surfaces
-        for (SurfNum = Zone(ZoneNum).SurfaceFirst; SurfNum <= Zone(ZoneNum).SurfaceLast; ++SurfNum) {
+        for (SurfNum = Zone(ZoneNum).HTSurfaceFirst; SurfNum <= Zone(ZoneNum).HTSurfaceLast; ++SurfNum) {
             if (Surface(SurfNum).Class != SurfaceClass::Wall) continue;
 
             if (Surface(SurfNum).Width == majorW) {
@@ -2983,9 +2977,7 @@ namespace ConvectionCoefficients {
         }
 
         // Assign convection coefficients
-        for (SurfNum = Zone(ZoneNum).SurfaceFirst; SurfNum <= Zone(ZoneNum).SurfaceLast; ++SurfNum) {
-            if (!Surface(SurfNum).HeatTransSurf) continue; // Skip non-heat transfer surfaces
-
+        for (SurfNum = Zone(ZoneNum).HTSurfaceFirst; SurfNum <= Zone(ZoneNum).HTSurfaceLast; ++SurfNum) {
             // Use ASHRAESimple correlation to give values for all the minor surfaces
             CalcASHRAESimpleIntConvCoeff(state, SurfNum, SurfaceTemperatures(SurfNum), MAT(ZoneNum));
 
@@ -3504,7 +3496,7 @@ namespace ConvectionCoefficients {
                 thisWWR = -999.0; // throw error?
             }
             // first pass thru this zones surfaces to gather data
-            for (int SurfLoop = Zone(ZoneLoop).SurfaceFirst; SurfLoop <= Zone(ZoneLoop).SurfaceLast; ++SurfLoop) {
+            for (int SurfLoop = Zone(ZoneLoop).HTSurfaceFirst; SurfLoop <= Zone(ZoneLoop).HTSurfaceLast; ++SurfLoop) {
                 // first catch exterior walls and do summations
                 if ((Surface(SurfLoop).ExtBoundCond == ExternalEnvironment) && (Surface(SurfLoop).Class == SurfaceClass::Wall)) {
                     PerimExtLengthSum += Surface(SurfLoop).Width;
@@ -3517,7 +3509,7 @@ namespace ConvectionCoefficients {
             }
 
             // second pass thru zone surfs to fill data
-            for (int SurfLoop = Zone(ZoneLoop).SurfaceFirst; SurfLoop <= Zone(ZoneLoop).SurfaceLast; ++SurfLoop) {
+            for (int SurfLoop = Zone(ZoneLoop).HTSurfaceFirst; SurfLoop <= Zone(ZoneLoop).HTSurfaceLast; ++SurfLoop) {
                 // now fill values
                 Surface(SurfLoop).IntConvZoneWallHeight = Zone(ZoneLoop).CeilingHeight;
                 Surface(SurfLoop).IntConvZonePerimLength = PerimExtLengthSum;
@@ -3527,7 +3519,7 @@ namespace ConvectionCoefficients {
 
             // third pass for window locations
             if ((ExtWindowCount > 0) && (ExtWallCount > 0)) {
-                for (int SurfLoop = Zone(ZoneLoop).SurfaceFirst; SurfLoop <= Zone(ZoneLoop).SurfaceLast; ++SurfLoop) {
+                for (int SurfLoop = Zone(ZoneLoop).HTSurfaceFirst; SurfLoop <= Zone(ZoneLoop).HTSurfaceLast; ++SurfLoop) {
                     if ((Surface(SurfLoop).ExtBoundCond == ExternalEnvironment) &&
                         ((Surface(SurfLoop).Class == SurfaceClass::Window) || (Surface(SurfLoop).Class == SurfaceClass::GlassDoor))) {
                         if (Surface(SurfLoop).IntConvWindowWallRatio < 0.5) {
@@ -4190,7 +4182,7 @@ namespace ConvectionCoefficients {
             state.dataConvectionCoefficient->ActiveFloorCount = 0;
             state.dataConvectionCoefficient->ActiveFloorArea = 0.0;
 
-            for (SurfLoop = Zone(ZoneLoop).SurfaceFirst; SurfLoop <= Zone(ZoneLoop).SurfaceLast; ++SurfLoop) {
+            for (SurfLoop = Zone(ZoneLoop).HTSurfaceFirst; SurfLoop <= Zone(ZoneLoop).HTSurfaceLast; ++SurfLoop) {
                 if (!Surface(SurfLoop).IntConvSurfHasActiveInIt) continue;
                 if (Surface(SurfLoop).Class == SurfaceClass::Wall || Surface(SurfLoop).Class == SurfaceClass::Door) {
                     ++state.dataConvectionCoefficient->ActiveWallCount;
@@ -5178,7 +5170,7 @@ namespace ConvectionCoefficients {
                         } else if ((SELECT_CASE_var == VentilatedSlab_Num) || (SELECT_CASE_var == LoTempRadiant_Num)) {
 
                             if (state.dataZoneEquip->ZoneEquipConfig(ZoneNum).InFloorActiveElement) {
-                                for (SurfLoop = Zone(ZoneNum).SurfaceFirst; SurfLoop <= Zone(ZoneNum).SurfaceLast; ++SurfLoop) {
+                                for (SurfLoop = Zone(ZoneNum).HTSurfaceFirst; SurfLoop <= Zone(ZoneNum).HTSurfaceLast; ++SurfLoop) {
                                     if (!Surface(SurfLoop).IntConvSurfHasActiveInIt) continue;
                                     if (Surface(SurfLoop).Class == SurfaceClass::Floor) {
                                         DeltaTemp = TH(2, 1, SurfLoop) - MAT(ZoneNum);
@@ -5197,7 +5189,7 @@ namespace ConvectionCoefficients {
                             }
 
                             if (state.dataZoneEquip->ZoneEquipConfig(ZoneNum).InCeilingActiveElement) {
-                                for (SurfLoop = Zone(ZoneNum).SurfaceFirst; SurfLoop <= Zone(ZoneNum).SurfaceLast; ++SurfLoop) {
+                                for (SurfLoop = Zone(ZoneNum).HTSurfaceFirst; SurfLoop <= Zone(ZoneNum).HTSurfaceLast; ++SurfLoop) {
                                     if (!Surface(SurfLoop).IntConvSurfHasActiveInIt) continue;
                                     if (Surface(SurfLoop).Class == SurfaceClass::Roof) {
                                         DeltaTemp = TH(2, 1, SurfLoop) - MAT(ZoneNum);
@@ -5216,7 +5208,7 @@ namespace ConvectionCoefficients {
                             }
 
                             if (state.dataZoneEquip->ZoneEquipConfig(ZoneNum).InWallActiveElement) {
-                                for (SurfLoop = Zone(ZoneNum).SurfaceFirst; SurfLoop <= Zone(ZoneNum).SurfaceLast; ++SurfLoop) {
+                                for (SurfLoop = Zone(ZoneNum).HTSurfaceFirst; SurfLoop <= Zone(ZoneNum).HTSurfaceLast; ++SurfLoop) {
                                     if (!Surface(SurfLoop).IntConvSurfHasActiveInIt) continue;
                                     if (Surface(SurfLoop).Class == SurfaceClass::Wall || Surface(SurfLoop).Class == SurfaceClass::Door) {
                                         DeltaTemp = TH(2, 1, SurfLoop) - MAT(ZoneNum);
@@ -5275,8 +5267,8 @@ namespace ConvectionCoefficients {
 
             // Calculate Grashof, Reynolds, and Richardson numbers for the zone
             // Grashof for zone air based on largest delta T between surfaces and zone height
-            Tmin = minval(TH(2, 1, {Zone(ZoneNum).SurfaceFirst, Zone(ZoneNum).SurfaceLast}));
-            Tmax = maxval(TH(2, 1, {Zone(ZoneNum).SurfaceFirst, Zone(ZoneNum).SurfaceLast}));
+            Tmin = minval(TH(2, 1, {Zone(ZoneNum).HTSurfaceFirst, Zone(ZoneNum).HTSurfaceLast}));
+            Tmax = maxval(TH(2, 1, {Zone(ZoneNum).HTSurfaceFirst, Zone(ZoneNum).HTSurfaceLast}));
             GrH = (g * (Tmax - Tmin) * pow_3(Zone(ZoneNum).CeilingHeight)) / ((MAT(ZoneNum) + DataGlobalConstants::KelvinConv) * pow_2(v));
 
             // Reynolds number = Vdot supply / v * cube root of zone volume (Goldstein and Noveselac 2010)

diff --git a/src/EnergyPlus/DElightManagerF.cc b/src/EnergyPlus/DElightManagerF.cc
@@ -304,8 +304,8 @@ namespace DElightManagerF {
                     // Zone Surface Data Section
                     // Count the number of opaque surfaces bounding the current zone
                     iNumOpaqueSurfs = 0;
-                    iSurfaceFirst = zn.SurfaceFirst;
-                    int const iSurfaceLast = zn.SurfaceLast; // ending loop variable for surfaces
+                    iSurfaceFirst = zn.HTSurfaceFirst;
+                    int const iSurfaceLast = zn.HTSurfaceLast; // ending loop variable for surfaces
 
                     for (int isurf = iSurfaceFirst; isurf <= iSurfaceLast; ++isurf) {
                         auto &surf(Surface(isurf));

diff --git a/src/EnergyPlus/DataHeatBalance.hh b/src/EnergyPlus/DataHeatBalance.hh
@@ -369,25 +369,30 @@ namespace DataHeatBalance {
         int PlenumCondNum;                        // Supply or return plenum conditions number, 0 if this is not a plenum zone
         int TempControlledZoneIndex;              // this is the index number for TempControlledZone structure for lookup
         //            Pointers to Surface Data Structure
-        int AllSurfaceFirst;                         // First surface in zone including air boundaries
-        int SurfaceFirst;                            // First Heat Transfer Surface in Zone
-        int SurfaceLast;                             // Last  Heat Transfer Surface in Zone
-        int NonWindowSurfaceFirst;                   // First Non-Window Heat Transfer Surface in Zone
-        int NonWindowSurfaceLast;                    // Last  Non-Window Heat Transfer Surface in Zone
-        int WindowSurfaceFirst;                      // First Window Heat Transfer Surface in Zone
-        int WindowSurfaceLast;                       // Last  Window Heat Transfer Surface in Zone
-        int InsideConvectionAlgo;                    // Ref: appropriate values for Inside Convection solution
-        int NumSurfaces;                             // Number of surfaces for this zone
-        int NumSubSurfaces;                          // Number of subsurfaces for this zone (windows, doors, tdd dome and diffusers)
-        int NumShadingSurfaces;                      // Number of shading surfaces for this zone
-        int OutsideConvectionAlgo;                   // Ref: appropriate values for Outside Convection solution
-        Vector Centroid;                             // Center of the zone found by averaging wall, floor, and roof centroids
-        Real64 MinimumX;                             // Minimum X value for entire zone
-        Real64 MaximumX;                             // Maximum X value for entire zone
-        Real64 MinimumY;                             // Minimum Y value for entire zone
-        Real64 MaximumY;                             // Maximum Y value for entire zone
-        Real64 MinimumZ;                             // Minimum Z value for entire zone
-        Real64 MaximumZ;                             // Maximum Z value for entire zone
+        int AllSurfaceFirst;       // First surface in zone including air boundaries
+        int AllSurfaceLast;        // Last  surface in zone including air boundaries
+        int HTSurfaceFirst;        // First Heat Transfer Surface in Zone
+        int HTSurfaceLast;         // Last  Heat Transfer Surface in Zone
+        int OpaqOrIntMassSurfaceFirst; // First Opaque or Interior Mass Heat Transfer Surface (including opaque doors) in Zone
+        int OpaqOrIntMassSurfaceLast;  // Last  Opaque or Interior Mass Heat Transfer Surface (including opaque doors) in Zone
+        int WindowSurfaceFirst;    // First Window Heat Transfer Surface in Zone
+        int WindowSurfaceLast;     // Last  Window Heat Transfer Surface in Zone
+        int OpaqOrWinSurfaceFirst; // First opaque (including IntMass) or window (non TDD Dome) Surface in Zone
+        int OpaqOrWinSurfaceLast;  // Last  opaque (including IntMass) or window (non TDD Dome) Surface in Zone
+        int TDDDomeFirst;          // First TDD Dome Surface in Zone
+        int TDDDomeLast;           // Last  TDD Dome Surface in Zone
+        int InsideConvectionAlgo;  // Ref: appropriate values for Inside Convection solution
+        int NumSurfaces;           // Number of surfaces for this zone
+        int NumSubSurfaces;        // Number of subsurfaces for this zone (windows, doors, tdd dome and diffusers)
+        int NumShadingSurfaces;    // Number of shading surfaces for this zone
+        int OutsideConvectionAlgo; // Ref: appropriate values for Outside Convection solution
+        Vector Centroid;           // Center of the zone found by averaging wall, floor, and roof centroids
+        Real64 MinimumX;           // Minimum X value for entire zone
+        Real64 MaximumX;           // Maximum X value for entire zone
+        Real64 MinimumY;           // Minimum Y value for entire zone
+        Real64 MaximumY;           // Maximum Y value for entire zone
+        Real64 MinimumZ;           // Minimum Z value for entire zone
+        Real64 MaximumZ;           // Maximum Z value for entire zone
         std::vector<int> ZoneHTSurfaceList;          // List of HT surfaces related to this zone (includes adjacent interzone surfaces)
         std::vector<int> ZoneIZSurfaceList;          // List of interzone surfaces in this zone
         std::vector<int> ZoneHTNonWindowSurfaceList; // List of non-window HT surfaces related to this zone (includes adjacent interzone surfaces)
@@ -471,17 +476,20 @@ namespace DataHeatBalance {
               ExtWindowArea_Multiplied(0.0), ExtGrossWallArea_Multiplied(0.0), ExtNetWallArea(0.0), TotalSurfArea(0.0), ExteriorTotalSurfArea(0.0),
               ExteriorTotalGroundSurfArea(0.0), ExtGrossGroundWallArea(0.0), ExtGrossGroundWallArea_Multiplied(0.0), SystemZoneNodeNumber(0),
               IsControlled(false), IsSupplyPlenum(false), IsReturnPlenum(false), ZoneEqNum(0), PlenumCondNum(0), TempControlledZoneIndex(0),
-              AllSurfaceFirst(0), SurfaceFirst(0), SurfaceLast(0), NonWindowSurfaceFirst(0), NonWindowSurfaceLast(0), WindowSurfaceFirst(0),
-              WindowSurfaceLast(0), InsideConvectionAlgo(ASHRAESimple), NumSurfaces(0), NumSubSurfaces(0), NumShadingSurfaces(0),
-              OutsideConvectionAlgo(ASHRAESimple), Centroid(0.0, 0.0, 0.0), MinimumX(0.0), MaximumX(0.0), MinimumY(0.0), MaximumY(0.0), MinimumZ(0.0),
-              MaximumZ(0.0), RadiantEnclosureNum(0), SolarEnclosureNum(0), OutDryBulbTemp(0.0), OutDryBulbTempEMSOverrideOn(false),
-              OutDryBulbTempEMSOverrideValue(0.0), OutWetBulbTemp(0.0), OutWetBulbTempEMSOverrideOn(false), OutWetBulbTempEMSOverrideValue(0.0),
-              WindSpeed(0.0), WindSpeedEMSOverrideOn(false), WindSpeedEMSOverrideValue(0.0), WindDir(0.0), WindDirEMSOverrideOn(false),
-              WindDirEMSOverrideValue(0.0), HasLinkedOutAirNode(false), LinkedOutAirNode(0.0), isPartOfTotalArea(true), isNominalOccupied(false),
-              isNominalControlled(false), TotOccupants(0.0), AirHBimBalanceErrIndex(0), NoHeatToReturnAir(false), RefrigCaseRA(false),
-              HasAdjustedReturnTempByITE(false), AdjustedReturnTempByITE(0.0), HasLtsRetAirGain(false), HasAirFlowWindowReturn(false),
-              InternalHeatGains(0.0), NominalInfilVent(0.0), NominalMixing(0.0), TempOutOfBoundsReported(false), EnforcedReciprocity(false),
-              ZoneMinCO2SchedIndex(0), ZoneMaxCO2SchedIndex(0), ZoneContamControllerSchedIndex(0), FlagCustomizedZoneCap(false),
+              AllSurfaceFirst(0), AllSurfaceLast(-1), HTSurfaceFirst(0), HTSurfaceLast(-1), OpaqOrIntMassSurfaceFirst(0), OpaqOrIntMassSurfaceLast(-1),
+              WindowSurfaceFirst(0), WindowSurfaceLast(-1), OpaqOrWinSurfaceFirst(0), OpaqOrWinSurfaceLast(-1), TDDDomeFirst(0), TDDDomeLast(-1),
+              InsideConvectionAlgo(ASHRAESimple), NumSurfaces(0), NumSubSurfaces(0), NumShadingSurfaces(0), OutsideConvectionAlgo(ASHRAESimple), Centroid(0.0, 0.0, 0.0),
+              MinimumX(0.0), MaximumX(0.0), MinimumY(0.0), MaximumY(0.0), MinimumZ(0.0), MaximumZ(0.0), RadiantEnclosureNum(0), SolarEnclosureNum(0),
+
+              OutDryBulbTemp(0.0), OutDryBulbTempEMSOverrideOn(false), OutDryBulbTempEMSOverrideValue(0.0), OutWetBulbTemp(0.0),
+              OutWetBulbTempEMSOverrideOn(false), OutWetBulbTempEMSOverrideValue(0.0), WindSpeed(0.0), WindSpeedEMSOverrideOn(false),
+              WindSpeedEMSOverrideValue(0.0), WindDir(0.0), WindDirEMSOverrideOn(false), WindDirEMSOverrideValue(0.0), HasLinkedOutAirNode(false),
+              LinkedOutAirNode(0.0), isPartOfTotalArea(true), isNominalOccupied(false), isNominalControlled(false), TotOccupants(0.0),
+              AirHBimBalanceErrIndex(0), NoHeatToReturnAir(false), RefrigCaseRA(false), HasAdjustedReturnTempByITE(false),
+              AdjustedReturnTempByITE(0.0), HasLtsRetAirGain(false), HasAirFlowWindowReturn(false), InternalHeatGains(0.0), NominalInfilVent(0.0),
+              NominalMixing(0.0), TempOutOfBoundsReported(false), EnforcedReciprocity(false), ZoneMinCO2SchedIndex(0), ZoneMaxCO2SchedIndex(0),
+              ZoneContamControllerSchedIndex(0), FlagCustomizedZoneCap(false),
+              // Hybrid Modeling
               ZoneMeasuredTemperature(0.0), ZoneMeasuredHumidityRatio(0.0), ZoneMeasuredCO2Concentration(0.0), ZoneMeasuredSupplyAirTemperature(0.0),
               ZoneMeasuredSupplyAirFlowRate(0.0), ZoneMeasuredSupplyAirHumidityRatio(0.0), ZoneMeasuredSupplyAirCO2Concentration(0.0),
               ZonePeopleActivityLevel(0.0), ZonePeopleSensibleHeatFraction(0.0), ZonePeopleRadiantHeatFraction(0.0), ZoneVolCapMultpSens(1.0),