Correct VAV maximum air flow fraction during reheat for heating dominated use cases

src/EnergyPlus/SingleDuct.cc

@@ -2877,8 +2877,15 @@ void SingleDuctAirTerminal::SizeSys(EnergyPlusData &state)
 
             CheckZoneSizing(state, this->sysType, this->SysName);
 
-            MaxAirVolFlowRateDes = max(state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesCoolVolFlow,
-                                       state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesHeatVolFlow);
+            Real64 heatingMaxFlow;
+            if (this->DamperHeatingAction == Action::ReverseWithLimits &&
+                state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesHeatVolFlow >
+                    state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesHeatVolFlowMax) {
+                heatingMaxFlow = state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesHeatVolFlowMax;
+            } else {
+                heatingMaxFlow = state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesHeatVolFlow;
+            }
+            MaxAirVolFlowRateDes = max(state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesCoolVolFlow, heatingMaxFlow);
 
             if (MaxAirVolFlowRateDes < SmallAirVolFlow) {
                 MaxAirVolFlowRateDes = 0.0;
@@ -2927,7 +2934,13 @@ void SingleDuctAirTerminal::SizeSys(EnergyPlusData &state)
             }
         } else {
             CheckZoneSizing(state, this->sysType, this->SysName);
-            MaxHeatAirVolFlowRateDes = state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesHeatVolFlow;
+            if (this->DamperHeatingAction == Action::ReverseWithLimits &&
+                state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesHeatVolFlow >
+                    state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesHeatVolFlowMax) {
+                MaxHeatAirVolFlowRateDes = state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesHeatVolFlowMax;
+            } else {
+                MaxHeatAirVolFlowRateDes = state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesHeatVolFlow;
+            }
             if (MaxHeatAirVolFlowRateDes < SmallAirVolFlow) {
                 MaxHeatAirVolFlowRateDes = 0.0;
             }
@@ -3215,7 +3228,13 @@ void SingleDuctAirTerminal::SizeSys(EnergyPlusData &state)
         if (state.dataSize->ZoneSizingRunDone) {
             if (state.dataSize->CurTermUnitSizingNum > 0) {
                 // if zone sizing run done, set the design max reheat air flow to the value from the design calcs
-                MaxAirVolFlowRateDuringReheatDes = state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesHeatVolFlowMax;
+                if (state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesHeatVolFlow >
+                    state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesHeatVolFlowMax) {
+                    MaxAirVolFlowRateDuringReheatDes =
+                        state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesHeatVolFlowMax;
+                } else {
+                    MaxAirVolFlowRateDuringReheatDes = state.dataSize->TermUnitFinalZoneSizing(state.dataSize->CurTermUnitSizingNum).DesHeatVolFlow;
+                }
             }
         } else {
             // if no design calc use 0.002032 [m3/s-m2] times floor area. That's .40 cfm/ft2

tst/EnergyPlus/unit/SingleDuct.unit.cc

@@ -1282,7 +1282,7 @@ TEST_F(EnergyPlusFixture, SingleDuct_ZeroFloorAreaTest)
     // zone floor area of zone 1 = 0, zone 2 > 0. Expect TU MaxAirVolFlowRateDuringReheat = 0 only for zone 1.
     // this test isn't relevant anymore since defaulting is done differently
     Real64 MaxAirVolFlowRateDuringReheatDes =
-        min(state->dataSize->FinalZoneSizing(1).DesHeatVolFlowMax, state->dataSingleDuct->sd_airterminal(1).MaxAirVolFlowRate);
+        min(state->dataSize->FinalZoneSizing(1).DesHeatVolFlow, state->dataSingleDuct->sd_airterminal(1).MaxAirVolFlowRate);
     // Real64 MaxAirVolFlowRateDuringReheatDes = min( 0.002032 * state->dataSingleDuct->sd_airterminal( 1 ).ZoneFloorArea,
     // state->dataSingleDuct->sd_airterminal( 1 ).MaxAirVolFlowRate ); apply limit based on min stop
     MaxAirVolFlowRateDuringReheatDes =
@@ -1291,7 +1291,7 @@ TEST_F(EnergyPlusFixture, SingleDuct_ZeroFloorAreaTest)
 
     // This isn't relevant any more since the default is calculated differently
     Real64 MaxAirVolFractionDuringReheatDes =
-        min(1.0, (state->dataSize->FinalZoneSizing(1).DesHeatVolFlowMax / state->dataSingleDuct->sd_airterminal(1).MaxAirVolFlowRate));
+        min(1.0, (state->dataSize->FinalZoneSizing(1).DesHeatVolFlow / state->dataSingleDuct->sd_airterminal(1).MaxAirVolFlowRate));
     // Real64 MaxAirVolFractionDuringReheatDes = min( 1.0, ( 0.002032 * state->dataSingleDuct->sd_airterminal( 1 ).ZoneFloorArea /
     // state->dataSingleDuct->sd_airterminal( 1 ).MaxAirVolFlowRate )
     // ); apply limit based on min stop
@@ -1306,12 +1306,12 @@ TEST_F(EnergyPlusFixture, SingleDuct_ZeroFloorAreaTest)
     EXPECT_NEAR(MaxAirVolFractionDuringReheatDes, state->dataSingleDuct->sd_airterminal(1).MaxAirVolFractionDuringReheat, 0.0000000000001);
 
     MaxAirVolFlowRateDuringReheatDes =
-        min(state->dataSize->FinalZoneSizing(2).DesHeatVolFlowMax, state->dataSingleDuct->sd_airterminal(2).MaxAirVolFlowRate);
+        min(state->dataSize->FinalZoneSizing(2).DesHeatVolFlow, state->dataSingleDuct->sd_airterminal(2).MaxAirVolFlowRate);
     MaxAirVolFlowRateDuringReheatDes =
         max(MaxAirVolFlowRateDuringReheatDes,
             (state->dataSingleDuct->sd_airterminal(2).MaxAirVolFlowRate * state->dataSingleDuct->sd_airterminal(2).ZoneMinAirFrac));
     MaxAirVolFractionDuringReheatDes =
-        min(1.0, (state->dataSize->FinalZoneSizing(2).DesHeatVolFlowMax / state->dataSingleDuct->sd_airterminal(2).MaxAirVolFlowRate));
+        min(1.0, (state->dataSize->FinalZoneSizing(2).DesHeatVolFlow / state->dataSingleDuct->sd_airterminal(2).MaxAirVolFlowRate));
     MaxAirVolFractionDuringReheatDes = max(MaxAirVolFractionDuringReheatDes, state->dataSingleDuct->sd_airterminal(2).ZoneMinAirFrac);
     MaxAirVolFlowRateDuringReheatDes =
         min(max(MaxAirVolFlowRateDuringReheatDes, MaxAirVolFractionDuringReheatDes * state->dataSingleDuct->sd_airterminal(2).MaxAirVolFlowRate),
@@ -2737,23 +2737,69 @@ TEST_F(EnergyPlusFixture, VAVReheatTerminal_SizeMinFrac)
     EXPECT_TRUE(compare_err_stream(""));
 
     int SysNum = 1;
+    auto &thisSys = state->dataSingleDuct->sd_airterminal(SysNum);
 
     // First test -  design min flow < max flow
     state->dataSize->ZoneSizingRunDone = true;
     state->dataSize->CurZoneEqNum = 1;
     state->dataSize->CurTermUnitSizingNum = 1;
     state->dataSize->TermUnitFinalZoneSizing(1).DesCoolVolFlowMin = 0.5;
-    state->dataSingleDuct->sd_airterminal(SysNum).SizeSys(*state);
-    EXPECT_EQ(0.5, state->dataSingleDuct->sd_airterminal(SysNum).ZoneMinAirFracDes);
+    thisSys.SizeSys(*state);
+    EXPECT_EQ(0.5, thisSys.ZoneMinAirFracDes);
 
     // Second test -  design min flow > max flow
     state->dataSize->ZoneSizingRunDone = true;
     state->dataSize->CurZoneEqNum = 1;
     state->dataSize->CurTermUnitSizingNum = 1;
-    state->dataSingleDuct->sd_airterminal(SysNum).ZoneMinAirFracDes = AutoSize; // need to reset this so it sizes again
+    thisSys.ZoneMinAirFracDes = AutoSize; // need to reset this so it sizes again
     state->dataSize->TermUnitFinalZoneSizing(1).DesCoolVolFlowMin = 1.5;
-    state->dataSingleDuct->sd_airterminal(SysNum).SizeSys(*state);
-    EXPECT_EQ(1.0, state->dataSingleDuct->sd_airterminal(SysNum).ZoneMinAirFracDes);
+    thisSys.SizeSys(*state);
+    EXPECT_EQ(1.0, thisSys.ZoneMinAirFracDes);
+
+    // test Maximum Flow Fraction During Reheat for heating dominated
+    thisSys.MaxAirVolFlowRate = DataSizing::AutoSize;
+    thisSys.ZoneMinAirFracDes = DataSizing::AutoSize;
+    thisSys.MaxAirVolFlowRateDuringReheat = DataSizing::AutoSize;
+    thisSys.MaxAirVolFractionDuringReheat = DataSizing::AutoSize;
+    state->dataSize->TermUnitFinalZoneSizing(1).DesHeatVolFlow = 1.7;
+    state->dataSize->TermUnitFinalZoneSizing(1).DesHeatVolFlowMax = 1.6;
+    thisSys.SizeSys(*state);
+    Real64 expectedZoneMinAirFracDes = std::min(1.0, state->dataSize->TermUnitFinalZoneSizing(1).DesCoolVolFlowMin / thisSys.MaxAirVolFlowRate);
+    // DesHeatVolFlowMax is limiting flow rate
+    Real64 expectedMaxAirVolFractionDuringReheat = state->dataSize->TermUnitFinalZoneSizing(1).DesHeatVolFlowMax / thisSys.MaxAirVolFlowRate;
+    EXPECT_EQ(expectedZoneMinAirFracDes, thisSys.ZoneMinAirFracDes);
+    EXPECT_EQ(1.0, thisSys.MaxAirVolFractionDuringReheat);
+    EXPECT_EQ(expectedMaxAirVolFractionDuringReheat, thisSys.MaxAirVolFractionDuringReheat);
+
+    // switch magnitude of DesHeatVolFlow and DesHeatVolFlowMax, still heating dominated
+    thisSys.MaxAirVolFlowRate = DataSizing::AutoSize;
+    thisSys.ZoneMinAirFracDes = DataSizing::AutoSize;
+    thisSys.MaxAirVolFlowRateDuringReheat = DataSizing::AutoSize;
+    thisSys.MaxAirVolFractionDuringReheat = DataSizing::AutoSize;
+    state->dataSize->TermUnitFinalZoneSizing(1).DesHeatVolFlow = 1.6;
+    state->dataSize->TermUnitFinalZoneSizing(1).DesHeatVolFlowMax = 1.7;
+    thisSys.SizeSys(*state);
+    expectedZoneMinAirFracDes = std::min(1.0, state->dataSize->TermUnitFinalZoneSizing(1).DesCoolVolFlowMin / thisSys.MaxAirVolFlowRate);
+    // DesHeatVolFlowMax is NOT limiting flow rate
+    expectedMaxAirVolFractionDuringReheat = state->dataSize->TermUnitFinalZoneSizing(1).DesHeatVolFlow / thisSys.MaxAirVolFlowRate;
+    EXPECT_EQ(expectedZoneMinAirFracDes, thisSys.ZoneMinAirFracDes);
+    EXPECT_EQ(1.0, thisSys.MaxAirVolFractionDuringReheat);
+    EXPECT_EQ(expectedMaxAirVolFractionDuringReheat, thisSys.MaxAirVolFractionDuringReheat);
+
+    // test Maximum Flow Fraction During Reheat for cooling dominated
+    thisSys.MaxAirVolFlowRate = DataSizing::AutoSize;
+    thisSys.ZoneMinAirFracDes = DataSizing::AutoSize;
+    thisSys.MaxAirVolFlowRateDuringReheat = DataSizing::AutoSize;
+    thisSys.MaxAirVolFractionDuringReheat = DataSizing::AutoSize;
+    state->dataSize->TermUnitFinalZoneSizing(1).DesHeatVolFlow = 1.4;
+    state->dataSize->TermUnitFinalZoneSizing(1).DesHeatVolFlowMax = 1.3;
+    thisSys.SizeSys(*state);
+    expectedZoneMinAirFracDes = std::min(1.0, state->dataSize->TermUnitFinalZoneSizing(1).DesCoolVolFlowMin / thisSys.MaxAirVolFlowRate);
+    // DesHeatVolFlowMax is limiting flow rate
+    expectedMaxAirVolFractionDuringReheat = state->dataSize->TermUnitFinalZoneSizing(1).DesHeatVolFlowMax / thisSys.MaxAirVolFlowRate;
+    EXPECT_EQ(expectedZoneMinAirFracDes, thisSys.ZoneMinAirFracDes);
+    EXPECT_EQ(1.0, thisSys.MaxAirVolFractionDuringReheat);
+    EXPECT_EQ(expectedMaxAirVolFractionDuringReheat, thisSys.MaxAirVolFractionDuringReheat);
 }
 
 TEST_F(EnergyPlusFixture, setATMixerSizingProperties_Test)

tst/EnergyPlus/unit/VAVDefMinMaxFlow.unit.cc

@@ -490,8 +490,12 @@ TEST_F(EnergyPlusFixture, VAVDefMinMaxFlowTestSizing2)
     state->dataSingleDuct->sd_airterminal(1).ZoneFloorArea = state->dataHeatBal->Zone(1).FloorArea;
     UpdateTermUnitFinalZoneSizing(*state); // Fills the TermUnitFinalZoneSizing array
     state->dataSingleDuct->sd_airterminal(1).SizeSys(*state);
+    Real64 heatVolFlow = (state->dataSize->FinalZoneSizing(state->dataSize->CurZoneEqNum).DesHeatVolFlow >
+                          state->dataSize->FinalZoneSizing(state->dataSize->CurZoneEqNum).DesHeatVolFlowMax)
+                             ? state->dataSize->FinalZoneSizing(state->dataSize->CurZoneEqNum).DesHeatVolFlowMax
+                             : state->dataSize->FinalZoneSizing(state->dataSize->CurZoneEqNum).DesHeatVolFlow;
     EXPECT_NEAR(state->dataSingleDuct->sd_airterminal(state->dataSize->CurZoneEqNum).ZoneMinAirFracDes, 0.348739, 0.000001);
-    EXPECT_NEAR(state->dataSingleDuct->sd_airterminal(state->dataSize->CurZoneEqNum).MaxAirVolFlowRateDuringReheat, 0.196047, 0.000001);
+    EXPECT_NEAR(state->dataSingleDuct->sd_airterminal(state->dataSize->CurZoneEqNum).MaxAirVolFlowRateDuringReheat, heatVolFlow, 0.000001);
 
     state->dataLoopNodes->Node.deallocate();
     state->dataZoneEquip->ZoneEquipConfig.deallocate();