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HeatBalanceSurfaceManager.cc
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HeatBalanceSurfaceManager.cc
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// EnergyPlus, Copyright (c) 1996-2024, The Board of Trustees of the University of Illinois,
// The Regents of the University of California, through Lawrence Berkeley National Laboratory
// (subject to receipt of any required approvals from the U.S. Dept. of Energy), Oak Ridge
// National Laboratory, managed by UT-Battelle, Alliance for Sustainable Energy, LLC, and other
// contributors. All rights reserved.
//
// NOTICE: This Software was developed under funding from the U.S. Department of Energy and the
// U.S. Government consequently retains certain rights. As such, the U.S. Government has been
// granted for itself and others acting on its behalf a paid-up, nonexclusive, irrevocable,
// worldwide license in the Software to reproduce, distribute copies to the public, prepare
// derivative works, and perform publicly and display publicly, and to permit others to do so.
//
// Redistribution and use in source and binary forms, with or without modification, are permitted
// provided that the following conditions are met:
//
// (1) Redistributions of source code must retain the above copyright notice, this list of
// conditions and the following disclaimer.
//
// (2) Redistributions in binary form must reproduce the above copyright notice, this list of
// conditions and the following disclaimer in the documentation and/or other materials
// provided with the distribution.
//
// (3) Neither the name of the University of California, Lawrence Berkeley National Laboratory,
// the University of Illinois, U.S. Dept. of Energy nor the names of its contributors may be
// used to endorse or promote products derived from this software without specific prior
// written permission.
//
// (4) Use of EnergyPlus(TM) Name. If Licensee (i) distributes the software in stand-alone form
// without changes from the version obtained under this License, or (ii) Licensee makes a
// reference solely to the software portion of its product, Licensee must refer to the
// software as "EnergyPlus version X" software, where "X" is the version number Licensee
// obtained under this License and may not use a different name for the software. Except as
// specifically required in this Section (4), Licensee shall not use in a company name, a
// product name, in advertising, publicity, or other promotional activities any name, trade
// name, trademark, logo, or other designation of "EnergyPlus", "E+", "e+" or confusingly
// similar designation, without the U.S. Department of Energy's prior written consent.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR
// IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY
// AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR
// CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
// SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR
// OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
// POSSIBILITY OF SUCH DAMAGE.
// C++ Headers
#include <algorithm>
#include <cassert>
#include <cmath>
// ObjexxFCL Headers
#include <ObjexxFCL/Array.functions.hh>
#include <ObjexxFCL/Array1D.hh>
#include <ObjexxFCL/Array2D.hh>
#include <ObjexxFCL/Fmath.hh>
#include <ObjexxFCL/string.functions.hh>
// EnergyPlus Headers
#include <AirflowNetwork/Solver.hpp>
#include <EnergyPlus/ChilledCeilingPanelSimple.hh>
#include <EnergyPlus/Construction.hh>
#include <EnergyPlus/ConvectionCoefficients.hh>
#include <EnergyPlus/CurveManager.hh>
#include <EnergyPlus/Data/EnergyPlusData.hh>
#include <EnergyPlus/DataContaminantBalance.hh>
#include <EnergyPlus/DataDaylighting.hh>
#include <EnergyPlus/DataDaylightingDevices.hh>
#include <EnergyPlus/DataEnvironment.hh>
#include <EnergyPlus/DataHeatBalFanSys.hh>
#include <EnergyPlus/DataHeatBalSurface.hh>
#include <EnergyPlus/DataHeatBalance.hh>
#include <EnergyPlus/DataLoopNode.hh>
#include <EnergyPlus/DataMoistureBalance.hh>
#include <EnergyPlus/DataMoistureBalanceEMPD.hh>
#include <EnergyPlus/DataRoomAirModel.hh>
#include <EnergyPlus/DataRuntimeLanguage.hh>
#include <EnergyPlus/DataSizing.hh>
#include <EnergyPlus/DataSurfaces.hh>
#include <EnergyPlus/DataSystemVariables.hh>
#include <EnergyPlus/DataViewFactorInformation.hh>
#include <EnergyPlus/DataWindowEquivalentLayer.hh>
#include <EnergyPlus/DataZoneEnergyDemands.hh>
#include <EnergyPlus/DataZoneEquipment.hh>
#include <EnergyPlus/DaylightingDevices.hh>
#include <EnergyPlus/DaylightingManager.hh>
#include <EnergyPlus/DisplayRoutines.hh>
#include <EnergyPlus/EcoRoofManager.hh>
#include <EnergyPlus/ElectricBaseboardRadiator.hh>
#include <EnergyPlus/FileSystem.hh>
#include <EnergyPlus/General.hh>
#include <EnergyPlus/HWBaseboardRadiator.hh>
#include <EnergyPlus/HeatBalFiniteDiffManager.hh>
#include <EnergyPlus/HeatBalanceAirManager.hh>
#include <EnergyPlus/HeatBalanceHAMTManager.hh>
#include <EnergyPlus/HeatBalanceIntRadExchange.hh>
#include <EnergyPlus/HeatBalanceKivaManager.hh>
#include <EnergyPlus/HeatBalanceSurfaceManager.hh>
#include <EnergyPlus/HighTempRadiantSystem.hh>
#include <EnergyPlus/InputProcessing/InputProcessor.hh>
#include <EnergyPlus/InternalHeatGains.hh>
#include <EnergyPlus/LowTempRadiantSystem.hh>
#include <EnergyPlus/MoistureBalanceEMPDManager.hh>
#include <EnergyPlus/OutputProcessor.hh>
#include <EnergyPlus/OutputReportPredefined.hh>
#include <EnergyPlus/OutputReportTabular.hh>
#include <EnergyPlus/Psychrometrics.hh>
#include <EnergyPlus/ScheduleManager.hh>
#include <EnergyPlus/SolarShading.hh>
#include <EnergyPlus/SteamBaseboardRadiator.hh>
#include <EnergyPlus/SurfaceGeometry.hh>
#include <EnergyPlus/SwimmingPool.hh>
#include <EnergyPlus/ThermalComfort.hh>
#include <EnergyPlus/TranspiredCollector.hh>
#include <EnergyPlus/UtilityRoutines.hh>
#include <EnergyPlus/WindowComplexManager.hh>
#include <EnergyPlus/WindowEquivalentLayer.hh>
#include <EnergyPlus/WindowManager.hh>
#include <EnergyPlus/WindowManagerExteriorData.hh>
#include <EnergyPlus/WindowManagerExteriorThermal.hh>
#include <EnergyPlus/ZoneTempPredictorCorrector.hh>
#include <WCECommon.hpp>
#include <WCEMultiLayerOptics.hpp>
#include <WCESingleLayerOptics.hpp>
#include <WCETarcog.hpp>
namespace EnergyPlus::HeatBalanceSurfaceManager {
// Module containing the routines dealing with the Heat Balance of the surfaces
// MODULE INFORMATION:
// MODIFIED DJS (PSU Dec 2006) to add ecoroof
// PURPOSE OF THIS MODULE:
// To encapsulate the data and algorithms required to
// manage the simluation of the surface heat balance for the building.
// REFERENCES:
// The heat balance method is outlined in the "TARP Reference Manual", NIST, NBSIR 83-2655, Feb 1983.
// The methods are also summarized in many BSO Theses and papers.
// OTHER NOTES:
// This module was created from IBLAST subroutines
void ManageSurfaceHeatBalance(EnergyPlusData &state)
{
// SUBROUTINE INFORMATION:
// AUTHOR Richard Liesen
// DATE WRITTEN January 1998
// PURPOSE OF THIS SUBROUTINE:
// This subroutine manages the heat surface balance method of calculating
// building thermal loads. It is called from the HeatBalanceManager
// at the time step level. This driver manages the calls to all of
// the other drivers and simulation algorithms.
if (state.dataHeatBalSurfMgr->ManageSurfaceHeatBalancefirstTime) DisplayString(state, "Initializing Surfaces");
InitSurfaceHeatBalance(state); // Initialize all heat balance related parameters
// Solve the zone heat balance 'Detailed' solution
// Call the outside and inside surface heat balances
if (state.dataHeatBalSurfMgr->ManageSurfaceHeatBalancefirstTime) DisplayString(state, "Calculate Outside Surface Heat Balance");
CalcHeatBalanceOutsideSurf(state);
if (state.dataHeatBalSurfMgr->ManageSurfaceHeatBalancefirstTime) DisplayString(state, "Calculate Inside Surface Heat Balance");
CalcHeatBalanceInsideSurf(state);
// The air heat balance must be called before the temperature history
// updates because there may be a radiant system in the building
if (state.dataHeatBalSurfMgr->ManageSurfaceHeatBalancefirstTime) DisplayString(state, "Calculate Air Heat Balance");
HeatBalanceAirManager::ManageAirHeatBalance(state);
// IF NECESSARY, do one final "average" heat balance pass. This is only
// necessary if a radiant system is present and it was actually on for
// part or all of the time step.
UpdateFinalSurfaceHeatBalance(state);
// Before we leave the Surface Manager the thermal histories need to be updated
if (state.dataHeatBal->AnyCTF || state.dataHeatBal->AnyEMPD) {
UpdateThermalHistories(state); // Update the thermal histories
}
if (state.dataHeatBal->AnyCondFD) {
for (int SurfNum = 1; SurfNum <= state.dataSurface->TotSurfaces; ++SurfNum) {
auto const &surface = state.dataSurface->Surface(SurfNum);
int const ConstrNum = surface.Construction;
if (ConstrNum <= 0) continue; // Shading surface, not really a heat transfer surface
if (state.dataConstruction->Construct(ConstrNum).TypeIsWindow) continue; // Windows simulated in Window module
if (surface.HeatTransferAlgorithm != DataSurfaces::HeatTransferModel::CondFD) continue;
state.dataHeatBalFiniteDiffMgr->SurfaceFD(SurfNum).UpdateMoistureBalance();
}
}
ThermalComfort::ManageThermalComfort(state, false); // "Record keeping" for the zone
ReportSurfaceHeatBalance(state);
if (state.dataGlobal->ZoneSizingCalc) OutputReportTabular::GatherComponentLoadsSurface(state);
CalcThermalResilience(state);
if (state.dataOutRptTab->displayThermalResilienceSummary) {
ReportThermalResilience(state);
}
if (state.dataOutRptTab->displayCO2ResilienceSummary) {
ReportCO2Resilience(state);
}
if (state.dataOutRptTab->displayVisualResilienceSummary) {
ReportVisualResilience(state);
}
state.dataHeatBalSurfMgr->ManageSurfaceHeatBalancefirstTime = false;
}
// Beginning Initialization Section of the Module
//******************************************************************************
void UpdateVariableAbsorptances(EnergyPlusData &state)
{
auto &s_mat = state.dataMaterial;
for (int surfNum : state.dataSurface->AllVaryAbsOpaqSurfaceList) {
auto const &thisConstruct = state.dataConstruction->Construct(state.dataSurface->Surface(surfNum).Construction);
auto const *thisMaterial = s_mat->materials(thisConstruct.LayerPoint(1));
assert(thisMaterial != nullptr);
if (thisMaterial->absorpVarCtrlSignal == Material::VariableAbsCtrlSignal::Scheduled) {
if (thisMaterial->absorpThermalVarSchedIdx > 0) {
state.dataHeatBalSurf->SurfAbsThermalExt(surfNum) =
max(min(ScheduleManager::GetCurrentScheduleValue(state, thisMaterial->absorpThermalVarSchedIdx), 0.9999), 0.0001);
}
if (thisMaterial->absorpSolarVarSchedIdx > 0) {
state.dataHeatBalSurf->SurfAbsSolarExt(surfNum) =
max(min(ScheduleManager::GetCurrentScheduleValue(state, thisMaterial->absorpThermalVarSchedIdx), 0.9999), 0.0001);
}
} else {
Real64 triggerValue;
if (thisMaterial->absorpVarCtrlSignal == Material::VariableAbsCtrlSignal::SurfaceTemperature) {
triggerValue = state.dataHeatBalSurf->SurfTempOut(surfNum);
} else if (thisMaterial->absorpVarCtrlSignal == Material::VariableAbsCtrlSignal::SurfaceReceivedSolarRadiation) {
triggerValue = state.dataHeatBal->SurfQRadSWOutIncident(surfNum);
} else { // controlled by heating cooling mode
int zoneNum = state.dataSurface->Surface(surfNum).Zone;
bool isCooling = (state.dataZoneEnergyDemand->ZoneSysEnergyDemand(zoneNum).TotalOutputRequired < 0);
triggerValue = static_cast<Real64>(isCooling);
}
if (thisMaterial->absorpThermalVarFuncIdx > 0) {
state.dataHeatBalSurf->SurfAbsThermalExt(surfNum) =
max(min(Curve::CurveValue(state, thisMaterial->absorpThermalVarFuncIdx, triggerValue), 0.9999), 0.0001);
}
if (thisMaterial->absorpSolarVarFuncIdx > 0) {
state.dataHeatBalSurf->SurfAbsSolarExt(surfNum) =
max(min(Curve::CurveValue(state, thisMaterial->absorpSolarVarFuncIdx, triggerValue), 0.9999), 0.0001);
}
}
}
}
void InitSurfaceHeatBalance(EnergyPlusData &state)
{
// SUBROUTINE INFORMATION:
// AUTHOR Richard J. Liesen
// DATE WRITTEN January 1998
// MODIFIED Nov. 1999, FCW,
// Move ComputeIntThermalAbsorpFactors
// so called every timestep
// MODIFIED Aug. 2017
// Add initializations of surface data to linked air node value if defined
// PURPOSE OF THIS SUBROUTINE:
// This subroutine is for surface initializations within the
// heat balance.
// METHODOLOGY EMPLOYED:
// Uses the status flags to trigger record keeping events.
// // Using/Aliasing
// using namespace SolarShading;
// using HeatBalanceIntRadExchange::CalcInteriorRadExchange;
// using HeatBalFiniteDiffManager::InitHeatBalFiniteDiff;
// using InternalHeatGains::ManageInternalHeatGains;
//
// auto &Surface = state.dataSurface->Surface;
//
if (state.dataHeatBalSurfMgr->InitSurfaceHeatBalancefirstTime) DisplayString(state, "Initializing Outdoor environment for Surfaces");
// set zone level wind dir to global value
// Initialize zone outdoor environmental variables
// Bulk Initialization for Temperatures & WindSpeed
// using the zone, modify the zone Dry/Wet BulbTemps
// Initialize surface outdoor environmental variables
// Bulk Initialization for Temperatures & WindSpeed
// using the surface centroids, modify the surface Dry/Wet BulbTemps
DataSurfaces::SetSurfaceOutBulbTempAt(state);
DataSurfaces::CheckSurfaceOutBulbTempAt(state);
DataSurfaces::SetSurfaceWindSpeedAt(state);
DataSurfaces::SetSurfaceWindDirAt(state);
if (state.dataGlobal->AnyLocalEnvironmentsInModel) {
for (int SurfNum = 1; SurfNum <= state.dataSurface->TotSurfaces; ++SurfNum) {
if (state.dataSurface->Surface(SurfNum).SurfLinkedOutAirNode > 0) {
auto const &linkedNode = state.dataLoopNodes->Node(state.dataSurface->Surface(SurfNum).SurfLinkedOutAirNode);
state.dataSurface->SurfOutDryBulbTemp(SurfNum) = linkedNode.OutAirDryBulb;
state.dataSurface->SurfOutWetBulbTemp(SurfNum) = linkedNode.OutAirWetBulb;
state.dataSurface->SurfOutWindSpeed(SurfNum) = linkedNode.OutAirWindSpeed;
state.dataSurface->SurfOutWindDir(SurfNum) = linkedNode.OutAirWindDir;
}
}
}
// Overwriting surface and zone level environmental data with EMS override value
if (state.dataGlobal->AnyEnergyManagementSystemInModel) {
for (int SurfNum = 1; SurfNum <= state.dataSurface->TotSurfaces; ++SurfNum) {
if (state.dataSurface->SurfOutDryBulbTempEMSOverrideOn(SurfNum)) {
state.dataSurface->SurfOutDryBulbTemp(SurfNum) = state.dataSurface->SurfOutDryBulbTempEMSOverrideValue(SurfNum);
}
if (state.dataSurface->SurfOutWetBulbTempEMSOverrideOn(SurfNum)) {
state.dataSurface->SurfOutWetBulbTemp(SurfNum) = state.dataSurface->SurfOutWetBulbTempEMSOverrideValue(SurfNum);
}
if (state.dataSurface->SurfWindSpeedEMSOverrideOn(SurfNum)) {
state.dataSurface->SurfOutWindSpeed(SurfNum) = state.dataSurface->SurfWindSpeedEMSOverrideValue(SurfNum);
}
if (state.dataSurface->SurfWindDirEMSOverrideOn(SurfNum)) {
state.dataSurface->SurfOutWindDir(SurfNum) = state.dataSurface->SurfWindDirEMSOverrideValue(SurfNum);
}
if (state.dataSurface->SurfViewFactorGroundEMSOverrideOn(SurfNum)) {
state.dataSurface->Surface(SurfNum).ViewFactorGround = state.dataSurface->SurfViewFactorGroundEMSOverrideValue(SurfNum);
}
}
}
// Do the Begin Simulation initializations
if (state.dataGlobal->BeginSimFlag) {
AllocateSurfaceHeatBalArrays(state); // Allocate the Module Arrays before any inits take place
state.dataHeatBalSurf->InterZoneWindow =
std::any_of(state.dataViewFactor->EnclSolInfo.begin(),
state.dataViewFactor->EnclSolInfo.end(),
[](DataViewFactorInformation::EnclosureViewFactorInformation const &e) { return e.HasInterZoneWindow; });
}
if (state.dataGlobal->BeginSimFlag || state.dataGlobal->AnySurfPropOverridesInModel) {
for (int zoneNum = 1; zoneNum <= state.dataGlobal->NumOfZones; ++zoneNum) {
for (int spaceNum : state.dataHeatBal->Zone(zoneNum).spaceIndexes) {
auto const &thisSpace = state.dataHeatBal->space(spaceNum);
int const firstSurf = thisSpace.HTSurfaceFirst;
int const lastSurf = thisSpace.HTSurfaceLast;
for (int SurfNum = firstSurf; SurfNum <= lastSurf; ++SurfNum) {
int ConstrNum = state.dataSurface->SurfActiveConstruction(SurfNum); // SurfActiveConstruction set above
auto const &thisConstruct = state.dataConstruction->Construct(ConstrNum);
state.dataHeatBalSurf->SurfAbsSolarInt(SurfNum) = thisConstruct.InsideAbsorpSolar;
state.dataHeatBalSurf->SurfAbsThermalInt(SurfNum) = thisConstruct.InsideAbsorpThermal;
state.dataHeatBalSurf->SurfRoughnessExt(SurfNum) = thisConstruct.OutsideRoughness;
state.dataHeatBalSurf->SurfAbsSolarExt(SurfNum) = thisConstruct.OutsideAbsorpSolar;
state.dataHeatBalSurf->SurfAbsThermalExt(SurfNum) = thisConstruct.OutsideAbsorpThermal;
}
}
}
}
// variable thermal solar absorptance overrides
UpdateVariableAbsorptances(state);
// Do the Begin Environment initializations
if (state.dataGlobal->BeginEnvrnFlag) {
if (state.dataHeatBalSurfMgr->InitSurfaceHeatBalancefirstTime) DisplayString(state, "Initializing Temperature and Flux Histories");
InitThermalAndFluxHistories(state); // Set initial temperature and flux histories
}
// Calc movable insulation properties
if (state.dataSurface->AnyMovableInsulation) {
EvalOutsideMovableInsulation(state);
EvalInsideMovableInsulation(state);
}
// There are no daily initializations done in this portion of the surface heat balance
// There are no hourly initializations done in this portion of the surface heat balance
GetGroundSurfacesReflectanceAverage(state);
// Need to be called each timestep in order to check if surface points to new construction (EMS) and if does then
// complex fenestration needs to be initialized for additional states
SolarShading::TimestepInitComplexFenestration(state);
// Calculate exterior-surface multipliers that account for anisotropy of
// sky radiance
if (state.dataEnvrn->SunIsUp && state.dataEnvrn->DifSolarRad > 0.0) {
SolarShading::AnisoSkyViewFactors(state);
} else {
state.dataSolarShading->SurfAnisoSkyMult = 0.0;
}
// Set shading flag for exterior windows (except flags related to daylighting) and
// window construction (unshaded or shaded) to be used in heat balance calculation
if (state.dataHeatBalSurfMgr->InitSurfaceHeatBalancefirstTime) DisplayString(state, "Initializing Window Shading");
SolarShading::WindowShadingManager(state);
SolarShading::CheckGlazingShadingStatusChange(state);
// Calculate factors that are used to determine how much long-wave radiation from internal
// gains is absorbed by interior surfaces
if (state.dataHeatBalSurfMgr->InitSurfaceHeatBalancefirstTime) DisplayString(state, "Computing Interior Absorption Factors");
if (state.dataHeatBalSurfMgr->InitSurfaceHeatBalancefirstTime) HeatBalanceIntRadExchange::InitInteriorRadExchange(state);
ComputeIntThermalAbsorpFactors(state);
// Calculate factors for diffuse solar absorbed by room surfaces and interior shades
if (state.dataHeatBalSurfMgr->InitSurfaceHeatBalancefirstTime) DisplayString(state, "Computing Interior Diffuse Solar Absorption Factors");
ComputeIntSWAbsorpFactors(state);
if (state.dataHeatBalSurf->InterZoneWindow) {
if (state.dataHeatBalSurfMgr->InitSurfaceHeatBalancefirstTime) {
DisplayString(state, "Computing Interior Diffuse Solar Exchange through Interzone Windows");
}
ComputeDifSolExcZonesWIZWindows(state);
}
Dayltg::initDaylighting(state, state.dataHeatBalSurfMgr->InitSurfaceHeatBalancefirstTime);
HeatBalanceIntRadExchange::CalcInteriorRadExchange(
state, state.dataHeatBalSurf->SurfInsideTempHist(1), 0, state.dataHeatBalSurf->SurfQdotRadNetLWInPerArea, _, "Main");
if (state.dataSurface->AirflowWindows) SolarShading::WindowGapAirflowControl(state);
// The order of these initializations is important currently. Over time we hope to
// take the appropriate parts of these inits to the other heat balance managers
if (state.dataHeatBalSurfMgr->InitSurfaceHeatBalancefirstTime) DisplayString(state, "Initializing Solar Heat Gains");
InitSolarHeatGains(state);
Dayltg::manageDaylighting(state);
if (state.dataHeatBalSurfMgr->InitSurfaceHeatBalancefirstTime) DisplayString(state, "Initializing Internal Heat Gains");
InternalHeatGains::ManageInternalHeatGains(state, false);
if (state.dataHeatBalSurfMgr->InitSurfaceHeatBalancefirstTime) DisplayString(state, "Initializing Interior Solar Distribution");
InitIntSolarDistribution(state);
if (state.dataHeatBalSurfMgr->InitSurfaceHeatBalancefirstTime) DisplayString(state, "Initializing Interior Convection Coefficients");
Convect::InitIntConvCoeff(state, state.dataHeatBalSurf->SurfTempInTmp);
if (state.dataGlobal->BeginSimFlag) { // Now's the time to report surfaces, if desired
// if (firstTime) CALL DisplayString('Reporting Surfaces')
// CALL ReportSurfaces
if (state.dataHeatBalSurfMgr->InitSurfaceHeatBalancefirstTime) DisplayString(state, "Gathering Information for Predefined Reporting");
GatherForPredefinedReport(state);
}
// Initialize the temperature history terms for conduction through the surfaces
if (state.dataHeatBal->AnyCondFD) {
HeatBalFiniteDiffManager::InitHeatBalFiniteDiff(state);
}
for (int zoneNum = 1; zoneNum <= state.dataGlobal->NumOfZones; ++zoneNum) { // Loop through all surfaces...
for (int spaceNum : state.dataHeatBal->Zone(zoneNum).spaceIndexes) {
auto const &thisSpace = state.dataHeatBal->space(spaceNum);
int const firstSurfOpaque = thisSpace.OpaqOrIntMassSurfaceFirst;
int const lastSurfOpaque = thisSpace.OpaqOrIntMassSurfaceLast;
for (int SurfNum = firstSurfOpaque; SurfNum <= lastSurfOpaque; ++SurfNum) {
auto const &surface = state.dataSurface->Surface(SurfNum);
if (surface.HeatTransferAlgorithm != DataSurfaces::HeatTransferModel::CTF &&
surface.HeatTransferAlgorithm != DataSurfaces::HeatTransferModel::EMPD)
continue;
// Outside surface temp of "normal" windows not needed in Window5 calculation approach
// Window layer temperatures are calculated in CalcHeatBalanceInsideSurf
int const ConstrNum = surface.Construction;
auto const &construct = state.dataConstruction->Construct(ConstrNum);
state.dataHeatBalSurf->SurfCTFConstOutPart(SurfNum) = 0.0;
state.dataHeatBalSurf->SurfCTFConstInPart(SurfNum) = 0.0;
if (construct.NumCTFTerms <= 1) continue;
for (int Term = 1; Term <= construct.NumCTFTerms; ++Term) {
// [ l11 ] == ( 1, Term + 1, SurfNum ), [ l12 ] == ( 1, Term + 1, SurfNum )
// Sign convention for the various terms in the following two equations
// is based on the form of the Conduction Transfer Function equation
// given by:
// Qin,now = (Sum of)(Y Tout) - (Sum of)(Z Tin) + (Sum of)(F Qin,old)
// Qout,now = (Sum of)(X Tout) - (Sum of)(Y Tin) + (Sum of)(F Qout,old)
// In both equations, flux is positive from outside to inside.
// Tuned Aliases and linear indexing
Real64 const ctf_cross(construct.CTFCross[Term]);
Real64 const TH11(state.dataHeatBalSurf->SurfOutsideTempHist(Term + 1)(SurfNum));
Real64 const TH12(state.dataHeatBalSurf->SurfInsideTempHist(Term + 1)(SurfNum));
Real64 const QH11(state.dataHeatBalSurf->SurfOutsideFluxHist(Term + 1)(SurfNum));
Real64 const QH12(state.dataHeatBalSurf->SurfInsideFluxHist(Term + 1)(SurfNum));
state.dataHeatBalSurf->SurfCTFConstInPart(SurfNum) +=
ctf_cross * TH11 - construct.CTFInside[Term] * TH12 + construct.CTFFlux[Term] * QH12;
state.dataHeatBalSurf->SurfCTFConstOutPart(SurfNum) +=
construct.CTFOutside[Term] * TH11 - ctf_cross * TH12 + construct.CTFFlux[Term] * QH11;
}
}
}
}
if (state.dataHeatBal->AnyInternalHeatSourceInInput) {
for (int zoneNum = 1; zoneNum <= state.dataGlobal->NumOfZones; ++zoneNum) { // Loop through all surfaces...
for (int spaceNum : state.dataHeatBal->Zone(zoneNum).spaceIndexes) {
auto const &thisSpace = state.dataHeatBal->space(spaceNum);
int const firstSurfOpaque = thisSpace.OpaqOrIntMassSurfaceFirst;
int const lastSurfOpaque = thisSpace.OpaqOrIntMassSurfaceLast;
for (int SurfNum = firstSurfOpaque; SurfNum <= lastSurfOpaque; ++SurfNum) {
auto const &surface = state.dataSurface->Surface(SurfNum);
int const ConstrNum = surface.Construction;
auto const &construct = state.dataConstruction->Construct(ConstrNum);
if (!construct.SourceSinkPresent) continue;
if (surface.HeatTransferAlgorithm != DataSurfaces::HeatTransferModel::CTF &&
surface.HeatTransferAlgorithm != DataSurfaces::HeatTransferModel::EMPD)
continue;
state.dataHeatBalFanSys->CTFTsrcConstPart(SurfNum) = 0.0;
state.dataHeatBalFanSys->CTFTuserConstPart(SurfNum) = 0.0;
if (construct.NumCTFTerms <= 1) continue;
for (int Term = 1; Term <= construct.NumCTFTerms; ++Term) {
Real64 const TH11(state.dataHeatBalSurf->SurfOutsideTempHist(Term + 1)(SurfNum));
Real64 const TH12(state.dataHeatBalSurf->SurfInsideTempHist(Term + 1)(SurfNum));
Real64 const QsrcHist1(state.dataHeatBalSurf->SurfQsrcHist(SurfNum, Term + 1));
state.dataHeatBalSurf->SurfCTFConstInPart(SurfNum) += construct.CTFSourceIn[Term] * QsrcHist1;
state.dataHeatBalSurf->SurfCTFConstOutPart(SurfNum) += construct.CTFSourceOut[Term] * QsrcHist1;
state.dataHeatBalFanSys->CTFTsrcConstPart(SurfNum) +=
construct.CTFTSourceOut[Term] * TH11 + construct.CTFTSourceIn[Term] * TH12 + construct.CTFTSourceQ[Term] * QsrcHist1 +
construct.CTFFlux[Term] * state.dataHeatBalSurf->SurfTsrcHist(SurfNum, Term + 1);
state.dataHeatBalFanSys->CTFTuserConstPart(SurfNum) +=
construct.CTFTUserOut[Term] * TH11 + construct.CTFTUserIn[Term] * TH12 + construct.CTFTUserSource[Term] * QsrcHist1 +
construct.CTFFlux[Term] * state.dataHeatBalSurf->SurfTuserHist(SurfNum, Term + 1);
}
}
} // ...end of surfaces DO loop for initializing temperature history terms for the surface heat balances
}
}
// Zero out all of the radiant system heat balance coefficient arrays
for (int zoneNum = 1; zoneNum <= state.dataGlobal->NumOfZones; ++zoneNum) { // Loop through all surfaces...
for (int spaceNum : state.dataHeatBal->Zone(zoneNum).spaceIndexes) {
auto const &thisSpace = state.dataHeatBal->space(spaceNum);
int const firstSurf = thisSpace.HTSurfaceFirst;
int const lastSurf = thisSpace.HTSurfaceLast;
for (int SurfNum = firstSurf; SurfNum <= lastSurf; ++SurfNum) {
state.dataHeatBalFanSys->RadSysTiHBConstCoef(SurfNum) = 0.0;
state.dataHeatBalFanSys->RadSysTiHBToutCoef(SurfNum) = 0.0;
state.dataHeatBalFanSys->RadSysTiHBQsrcCoef(SurfNum) = 0.0;
state.dataHeatBalFanSys->RadSysToHBConstCoef(SurfNum) = 0.0;
state.dataHeatBalFanSys->RadSysToHBTinCoef(SurfNum) = 0.0;
state.dataHeatBalFanSys->RadSysToHBQsrcCoef(SurfNum) = 0.0;
state.dataHeatBalFanSys->QRadSysSource(SurfNum) = 0.0;
state.dataHeatBalFanSys->QPVSysSource(SurfNum) = 0.0;
state.dataHeatBalFanSys->QPoolSurfNumerator(SurfNum) = 0.0;
state.dataHeatBalFanSys->PoolHeatTransCoefs(SurfNum) = 0.0;
} // ...end of Zone Surf loop
}
} // ...end of Zone loop
for (int surfNum : state.dataSurface->allGetsRadiantHeatSurfaceList) {
auto &thisSurfQRadFromHVAC = state.dataHeatBalFanSys->surfQRadFromHVAC(surfNum);
thisSurfQRadFromHVAC.HTRadSys = 0.0;
thisSurfQRadFromHVAC.HWBaseboard = 0.0;
thisSurfQRadFromHVAC.SteamBaseboard = 0.0;
thisSurfQRadFromHVAC.ElecBaseboard = 0.0;
thisSurfQRadFromHVAC.CoolingPanel = 0.0;
}
if (state.dataGlobal->ZoneSizingCalc) GatherComponentLoadsSurfAbsFact(state);
if (state.dataHeatBalSurfMgr->InitSurfaceHeatBalancefirstTime) {
DisplayString(state, "Completed Initializing Surface Heat Balance");
}
state.dataHeatBalSurfMgr->InitSurfaceHeatBalancefirstTime = false;
}
void GatherForPredefinedReport(EnergyPlusData &state)
{
// SUBROUTINE INFORMATION:
// AUTHOR Jason Glazer
// DATE WRITTEN August 2006
// PURPOSE OF THIS SUBROUTINE:
// This subroutine reports the information for the predefined reports
// related to envelope components.
// SUBROUTINE LOCAL VARIABLE DECLARATIONS:
std::string surfName;
Real64 mult;
Real64 curAzimuth;
Real64 curTilt;
Real64 windowArea;
Real64 frameWidth;
Real64 frameArea;
Real64 dividerArea;
// counts for object count report
int SurfaceClassCount = int(DataSurfaces::SurfaceClass::Num);
Array1D_int numSurfaces(SurfaceClassCount);
Array1D_int numExtSurfaces(SurfaceClassCount);
int frameDivNum;
bool isExterior;
Array1D<Real64> computedNetArea; // holds the gross wall area minus the window and door areas
// the following variables are for the CalcNominalWindowCond call but only SHGCSummer is needed
Real64 nomCond;
Real64 SHGCSummer;
Real64 TransSolNorm;
Real64 TransVisNorm;
Real64 nomUfact;
int errFlag;
int curWSC;
// following variables are totals for fenestration table
Real64 windowAreaWMult(0.0);
Real64 fenTotArea(0.0);
Real64 fenTotAreaNorth(0.0);
Real64 fenTotAreaNonNorth(0.0);
Real64 ufactArea(0.0);
Real64 ufactAreaNorth(0.0);
Real64 ufactAreaNonNorth(0.0);
Real64 shgcArea(0.0);
Real64 shgcAreaNorth(0.0);
Real64 shgcAreaNonNorth(0.0);
Real64 vistranArea(0.0);
Real64 vistranAreaNorth(0.0);
Real64 vistranAreaNonNorth(0.0);
Real64 intFenTotArea(0.0);
Real64 intUfactArea(0.0);
Real64 intShgcArea(0.0);
Real64 intVistranArea(0.0);
bool isNorth;
constexpr std::array<std::string_view, static_cast<int>(DataSurfaces::WinShadingType::Num)> WindowShadingTypeNames = {
"No Shade", // 0
"Shade Off", // 1
"Interior Shade",
"Switchable Glazing",
"Exterior Shade",
"Exterior Screen",
"Interior Blind",
"Exterior Blind",
"Between Glass Shade",
"Between Glass Blind",
};
constexpr std::array<std::string_view, static_cast<int>(DataSurfaces::WindowShadingControlType::Num)> WindowShadingControlTypeNames = {
"Uncontrolled",
"AlwaysOn",
"AlwaysOff",
"OnIfScheduleAllows",
"OnIfHighSolarOnWindow",
"OnIfHighHorizontalSolar",
"OnIfHighOutdoorAirTemperature",
"OnIfHighZoneAirTemperature",
"OnIfHighZoneCooling",
"OnIfHighGlare",
"MeetDaylightIlluminanceSetpoint",
"OnNightIfLowOutdoorTempAndOffDay",
"OnNightIfLowInsideTempAndOffDay",
"OnNightIfHeatingAndOffDay",
"OnNightIfLowOutdoorTempAndOnDayIfCooling",
"OnNightIfHeatingAndOnDayIfCooling",
"OffNightAndOnDayIfCoolingAndHighSolarOnWindow",
"OnNightAndOnDayIfCoolingAndHighSolarOnWindow",
"OnIfHighOutdoorAirTempAndHighSolarOnWindow",
"OnIfHighOutdoorAirTempAndHighHorizontalSolar",
"OnIfHighZoneAirTempAndHighSolarOnWindow",
"OnIfHighZoneAirTempAndHighHorizontalSolar"};
constexpr std::array<std::string_view, static_cast<int>(DataSurfaces::NfrcProductOptions::Num)> NfrcProductNames = {
"CasementDouble", "CasementSingle", "DualAction",
"Fixed", "Garage", "Greenhouse",
"HingedEscape", "HorizontalSlider", "Jal",
"Pivoted", "ProjectingSingle", "ProjectingDual",
"DoorSidelite", "Skylight", "SlidingPatioDoor",
"CurtainWall", "SpandrelPanel", "SideHingedDoor",
"DoorTransom", "TropicalAwning", "TubularDaylightingDevice",
"VerticalSlider"};
constexpr std::array<Real64, static_cast<int>(DataSurfaces::NfrcProductOptions::Num)> NfrcWidth = {
// width in meters from Table 4-3 of NFRC 100-2020
1.200, 0.600, 1.200, // CasementDouble, CasementSingle, DualAction,
1.200, 2.134, 1.500, // Fixed, Garage, Greenhouse,
1.500, 1.500, 1.200, // HingedEscape, HorizontalSlider, Jal,
1.200, 1.500, 1.500, // Pivoted, ProjectingSingle, ProjectingDual,
0.600, 1.200, 2.000, // DoorSidelite, Skylight, SlidingPatioDoor,
2.000, 2.000, 1.920, // CurtainWall, SpandrelPanel, SideHingedDoor,
2.000, 1.500, 0.350, // DoorTransom, TropicalAwning, TubularDaylightingDevice,
1.200 // VerticalSlider,
};
constexpr std::array<Real64, static_cast<int>(DataSurfaces::NfrcProductOptions::Num)> NfrcHeight = {
// height in meters from Table 4-3 of NFRC 100-2020
1.500, 1.500, 1.500, // CasementDouble, CasementSingle, DualAction,
1.500, 2.134, 1.200, // Fixed, Garage, Greenhouse,
1.200, 1.200, 1.500, // HingedEscape, HorizontalSlider, Jal,
1.500, 1.200, 0.600, // Pivoted, ProjectingSingle, ProjectingDual,
2.090, 1.200, 2.000, // DoorSidelite, Skylight, SlidingPatioDoor,
2.000, 1.200, 2.090, // CurtainWall, SpandrelPanel, SideHingedDoor,
0.600, 1.200, 0.350, // DoorTransom, TropicalAwning, TubularDaylightingDevice,
1.500 // VerticalSlider,
};
constexpr std::array<DataSurfaces::NfrcVisionType, static_cast<int>(DataSurfaces::NfrcProductOptions::Num)> NfrcVision = {
DataSurfaces::NfrcVisionType::DualHorizontal, DataSurfaces::NfrcVisionType::Single,
DataSurfaces::NfrcVisionType::DualVertical, // CasementDouble, CasementSingle, DualAction,
DataSurfaces::NfrcVisionType::Single, DataSurfaces::NfrcVisionType::Single,
DataSurfaces::NfrcVisionType::Single, // Fixed, Garage, Greenhouse,
DataSurfaces::NfrcVisionType::Single, DataSurfaces::NfrcVisionType::DualHorizontal,
DataSurfaces::NfrcVisionType::Single, // HingedEscape, HorizontalSlider, Jal,
DataSurfaces::NfrcVisionType::Single, DataSurfaces::NfrcVisionType::Single,
DataSurfaces::NfrcVisionType::DualHorizontal, // Pivoted, ProjectingSingle, ProjectingDual,
DataSurfaces::NfrcVisionType::Single, DataSurfaces::NfrcVisionType::Single,
DataSurfaces::NfrcVisionType::DualHorizontal, // DoorSidelite, Skylight, SlidingPatioDoor,
DataSurfaces::NfrcVisionType::Single, DataSurfaces::NfrcVisionType::Single,
DataSurfaces::NfrcVisionType::Single, // CurtainWall, SpandrelPanel, SideHingedDoor,
DataSurfaces::NfrcVisionType::Single, DataSurfaces::NfrcVisionType::Single,
DataSurfaces::NfrcVisionType::Single, // DoorTransom, TropicalAwning, TubularDaylightingDevice,
DataSurfaces::NfrcVisionType::DualVertical // VerticalSlider
};
numSurfaces = 0;
numExtSurfaces = 0;
computedNetArea.allocate(state.dataSurface->TotSurfaces);
computedNetArea = 0.0; // start at zero, add wall area and subtract window and door area
// set up for EIO <FenestrationAssembly> output
if (state.dataHeatBal->TotFrameDivider > 0 && state.dataGeneral->Constructions) {
print(state.files.eio,
"{}\n",
"! <FenestrationAssembly>,Construction Name,Frame and Divider Name,NFRC Product Type,"
"Assembly U-Factor {W/m2-K},Assembly SHGC,Assembly Visible Transmittance");
}
static constexpr std::string_view FenestrationAssemblyFormat("FenestrationAssembly,{},{},{},{:.3R},{:.3R},{:.3R}\n");
std::vector<std::pair<int, int>> uniqConsFrame;
std::pair<int, int> consAndFrame;
// set up for EIO <FenestrationShadedState> output
bool fenestrationShadedStateHeaderShown(false);
static constexpr std::string_view FenestrationShadedStateFormat("FenestrationShadedState,{},{:.3R},{:.3R},{:.3R},{},{},{:.3R},{:.3R},{:.3R}\n");
std::vector<std::pair<int, int>> uniqShdConsFrame;
std::pair<int, int> shdConsAndFrame;
for (int iSurf : state.dataSurface->AllSurfaceListReportOrder) {
auto &surface = state.dataSurface->Surface(iSurf);
surfName = surface.Name;
// only exterior surfaces including underground
if ((surface.ExtBoundCond == DataSurfaces::ExternalEnvironment) || (surface.ExtBoundCond == DataSurfaces::Ground) ||
(surface.ExtBoundCond == DataSurfaces::GroundFCfactorMethod) || (surface.ExtBoundCond == DataSurfaces::KivaFoundation)) {
isExterior = true;
switch (surface.Class) {
case DataSurfaces::SurfaceClass::Wall:
case DataSurfaces::SurfaceClass::Floor:
case DataSurfaces::SurfaceClass::Roof: {
auto const &construct = state.dataConstruction->Construct(surface.Construction);
auto const &thisZone = state.dataHeatBal->Zone(surface.Zone);
mult = thisZone.Multiplier * thisZone.ListMultiplier;
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchOpCons, surfName, construct.Name);
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchOpZone, surfName, thisZone.Name);
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchOpRefl, surfName, 1 - construct.OutsideAbsorpSolar);
OutputReportPredefined::PreDefTableEntry(
state, state.dataOutRptPredefined->pdchOpUfactNoFilm, surfName, state.dataHeatBal->NominalU(surface.Construction), 3);
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchOpGrArea, surfName, surface.GrossArea * mult);
computedNetArea(iSurf) += surface.GrossArea * mult;
curAzimuth = surface.Azimuth;
// Round to two decimals, like the display in tables
// (PreDefTableEntry uses a fortran style write, that rounds rather than trim)
curAzimuth = round(curAzimuth * 100.0) / 100.0;
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchOpAzimuth, surfName, curAzimuth);
curTilt = surface.Tilt;
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchOpTilt, surfName, curTilt);
if ((curTilt >= 60.0) && (curTilt < 180.0)) {
if ((curAzimuth >= 315.0) || (curAzimuth < 45.0)) {
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchOpDir, surfName, "N");
} else if ((curAzimuth >= 45.0) && (curAzimuth < 135.0)) {
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchOpDir, surfName, "E");
} else if ((curAzimuth >= 135.0) && (curAzimuth < 225.0)) {
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchOpDir, surfName, "S");
} else if ((curAzimuth >= 225.0) && (curAzimuth < 315.0)) {
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchOpDir, surfName, "W");
}
}
} break;
case DataSurfaces::SurfaceClass::Window:
case DataSurfaces::SurfaceClass::TDD_Dome: {
auto &construct = state.dataConstruction->Construct(surface.Construction);
auto const &thisZone = state.dataHeatBal->Zone(surface.Zone);
mult = thisZone.Multiplier * thisZone.ListMultiplier * surface.Multiplier;
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenCons, surfName, construct.Name);
// if the construction report is requested the SummerSHGC is already calculated
if (construct.SummerSHGC != 0) {
SHGCSummer = construct.SummerSHGC;
TransVisNorm = construct.VisTransNorm;
} else {
// must calculate Summer SHGC
if (!construct.WindowTypeEQL) {
Window::CalcNominalWindowCond(state, surface.Construction, 2, nomCond, SHGCSummer, TransSolNorm, TransVisNorm, errFlag);
construct.SummerSHGC = SHGCSummer;
construct.VisTransNorm = TransVisNorm;
construct.SolTransNorm = TransSolNorm;
}
}
// include the frame area if present
windowArea = surface.GrossArea;
frameArea = 0.0;
dividerArea = 0.0;
frameDivNum = surface.FrameDivider;
if (frameDivNum != 0) {
auto const &frameDivider = state.dataSurface->FrameDivider(frameDivNum);
frameWidth = frameDivider.FrameWidth;
frameArea = (surface.Height + 2.0 * frameWidth) * (surface.Width + 2.0 * frameWidth) - (surface.Height * surface.Width);
windowArea += frameArea;
dividerArea = frameDivider.DividerWidth * (frameDivider.HorDividers * surface.Width + frameDivider.VertDividers * surface.Height -
frameDivider.HorDividers * frameDivider.VertDividers * frameDivider.DividerWidth);
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenFrameDivName, surfName, frameDivider.Name);
OutputReportPredefined::PreDefTableEntry(
state, state.dataOutRptPredefined->pdchFenFrameConductance, surfName, frameDivider.FrameConductance, 3);
OutputReportPredefined::PreDefTableEntry(
state, state.dataOutRptPredefined->pdchFenDividerConductance, surfName, frameDivider.DividerConductance, 3);
// report the selected NRFC product type (specific sizes) and the NFRC rating for the assembly (glass + frame + divider)
std::string_view NFRCname = NfrcProductNames[static_cast<int>(frameDivider.NfrcProductType)];
const Real64 windowWidth = NfrcWidth[static_cast<int>(frameDivider.NfrcProductType)];
const Real64 windowHeight = NfrcHeight[static_cast<int>(frameDivider.NfrcProductType)];
const DataSurfaces::NfrcVisionType vision = NfrcVision[static_cast<int>(frameDivider.NfrcProductType)];
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenAssemNfrcType, surfName, NFRCname);
Real64 uValueAssembly = 0.0;
Real64 shgcAssembly = 0.0;
Real64 vtAssembly = 0.0;
Window::GetWindowAssemblyNfrcForReport(
state, iSurf, surface.Construction, windowWidth, windowHeight, vision, uValueAssembly, shgcAssembly, vtAssembly);
if (state.dataWindowManager->inExtWindowModel->isExternalLibraryModel()) {
state.dataHeatBal->NominalU(surface.Construction) =
Window::GetIGUUValueForNFRCReport(state, iSurf, surface.Construction, windowWidth, windowHeight);
SHGCSummer = Window::GetSHGCValueForNFRCReporting(state, iSurf, surface.Construction, windowWidth, windowHeight);
}
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenAssemUfact, surfName, uValueAssembly, 3);
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenAssemSHGC, surfName, shgcAssembly, 3);
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenAssemVisTr, surfName, vtAssembly, 3);
// output EIO <FenestrationAssembly> for each unique combination of construction and frame/divider
if (state.dataGeneral->Constructions) {
consAndFrame = std::make_pair(surface.Construction, frameDivNum);
if (std::find(uniqConsFrame.begin(), uniqConsFrame.end(), consAndFrame) == uniqConsFrame.end()) {
uniqConsFrame.push_back(consAndFrame);
print(state.files.eio,
FenestrationAssemblyFormat,
construct.Name,
frameDivider.Name,
NFRCname,
uValueAssembly,
shgcAssembly,
vtAssembly);
}
}
}
windowAreaWMult = windowArea * mult;
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenAreaOf1, surfName, windowArea);
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenFrameAreaOf1, surfName, frameArea);
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenDividerAreaOf1, surfName, dividerArea);
OutputReportPredefined::PreDefTableEntry(
state, state.dataOutRptPredefined->pdchFenGlassAreaOf1, surfName, windowArea - (frameArea + dividerArea));
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenArea, surfName, windowAreaWMult);
computedNetArea(surface.BaseSurf) -= windowAreaWMult;
nomUfact = state.dataHeatBal->NominalU(surface.Construction);
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenUfact, surfName, nomUfact, 3);
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenSHGC, surfName, SHGCSummer, 3);
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenVisTr, surfName, TransVisNorm, 3);
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenParent, surfName, surface.BaseSurfName);
curAzimuth = surface.Azimuth;
// Round to two decimals, like the display in tables
curAzimuth = round(curAzimuth * 100.0) / 100.0;
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenAzimuth, surfName, curAzimuth);
isNorth = false;
curTilt = surface.Tilt;
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenTilt, surfName, curTilt);
if ((curTilt >= 60.0) && (curTilt < 180.0)) {
if ((curAzimuth >= 315.0) || (curAzimuth < 45.0)) {
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenDir, surfName, "N");
isNorth = true;
} else if ((curAzimuth >= 45.0) && (curAzimuth < 135.0)) {
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenDir, surfName, "E");
} else if ((curAzimuth >= 135.0) && (curAzimuth < 225.0)) {
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenDir, surfName, "S");
} else if ((curAzimuth >= 225.0) && (curAzimuth < 315.0)) {
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenDir, surfName, "W");
}
}
// Report table for every shading control state
const unsigned int totalStates = surface.windowShadingControlList.size();
if (frameDivNum != 0) {
auto const &frameDivider = state.dataSurface->FrameDivider(frameDivNum);
for (unsigned int i = 0; i < totalStates; ++i) {
const Real64 windowWidth = NfrcWidth[static_cast<int>(frameDivider.NfrcProductType)];
const Real64 windowHeight = NfrcHeight[static_cast<int>(frameDivider.NfrcProductType)];
const DataSurfaces::NfrcVisionType vision = NfrcVision[static_cast<int>(frameDivider.NfrcProductType)];
const int stateConstrNum = surface.shadedConstructionList[i];
const Real64 stateUValue = Window::GetIGUUValueForNFRCReport(state, iSurf, stateConstrNum, windowWidth, windowHeight);
const Real64 stateSHGC = Window::GetSHGCValueForNFRCReporting(state, iSurf, stateConstrNum, windowWidth, windowHeight);
std::string const &constructionName = state.dataConstruction->Construct(stateConstrNum).Name;
OutputReportPredefined::PreDefTableEntry(
state, state.dataOutRptPredefined->pdchFenShdFrameDiv, constructionName, frameDivider.Name);
OutputReportPredefined::PreDefTableEntry(
state, state.dataOutRptPredefined->pdchFenShdUfact, constructionName, stateUValue, 3);
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenShdSHGC, constructionName, stateSHGC, 3);
OutputReportPredefined::PreDefTableEntry(state,
state.dataOutRptPredefined->pdchFenShdVisTr,
constructionName,
state.dataConstruction->Construct(stateConstrNum).VisTransNorm,
3);
Real64 stateAssemblyUValue{0.0};
Real64 stateAssemblySHGC{0.0};
Real64 stateAssemblyVT{0.0};
Window::GetWindowAssemblyNfrcForReport(
state, iSurf, stateConstrNum, windowWidth, windowHeight, vision, stateAssemblyUValue, stateAssemblySHGC, stateAssemblyVT);
std::string_view NFRCname = NfrcProductNames[static_cast<int>(frameDivider.NfrcProductType)];
OutputReportPredefined::PreDefTableEntry(
state, state.dataOutRptPredefined->pdchFenShdAssemNfrcType, constructionName, NFRCname);
OutputReportPredefined::PreDefTableEntry(
state, state.dataOutRptPredefined->pdchFenShdAssemUfact, constructionName, stateAssemblyUValue, 3);
OutputReportPredefined::PreDefTableEntry(
state, state.dataOutRptPredefined->pdchFenShdAssemSHGC, constructionName, stateAssemblySHGC, 3);
OutputReportPredefined::PreDefTableEntry(
state, state.dataOutRptPredefined->pdchFenShdAssemVisTr, constructionName, stateAssemblyVT, 3);
if (state.dataGeneral->Constructions) {
if (!fenestrationShadedStateHeaderShown) {
print(state.files.eio,
"{}\n",
"! <FenestrationShadedState>,Construction Name,Glass U-Factor {W/m2-K},"
"Glass SHGC, Glass Visible Transmittance, Frame and Divider Name,NFRC Product Type,"
"Assembly U-Factor {W/m2-K},Assembly SHGC,Assembly Visible Transmittance");
fenestrationShadedStateHeaderShown = true;
}
shdConsAndFrame = std::make_pair(stateConstrNum, frameDivNum);
if (std::find(uniqShdConsFrame.begin(), uniqShdConsFrame.end(), shdConsAndFrame) == uniqShdConsFrame.end()) {
uniqShdConsFrame.push_back(shdConsAndFrame);
print(state.files.eio,
FenestrationShadedStateFormat,
constructionName,
stateUValue,
stateSHGC,
state.dataConstruction->Construct(stateConstrNum).VisTransNorm,
frameDivider.Name,
NFRCname,
stateAssemblyUValue,
stateAssemblySHGC,
stateAssemblyVT);
}
}
}
}
curWSC = surface.activeWindowShadingControl;
// compute totals for area weighted averages
fenTotArea += windowAreaWMult;
ufactArea += nomUfact * windowAreaWMult;
shgcArea += SHGCSummer * windowAreaWMult;
vistranArea += TransVisNorm * windowAreaWMult;
if (isNorth) {
fenTotAreaNorth += windowAreaWMult;
ufactAreaNorth += nomUfact * windowAreaWMult;
shgcAreaNorth += SHGCSummer * windowAreaWMult;
vistranAreaNorth += TransVisNorm * windowAreaWMult;
} else {
fenTotAreaNonNorth += windowAreaWMult;
ufactAreaNonNorth += nomUfact * windowAreaWMult;
shgcAreaNonNorth += SHGCSummer * windowAreaWMult;
vistranAreaNonNorth += TransVisNorm * windowAreaWMult;
}
// shading
if (surface.HasShadeControl) {
OutputReportPredefined::PreDefTableEntry(state, state.dataOutRptPredefined->pdchFenSwitchable, surfName, "Yes");
OutputReportPredefined::PreDefTableEntry(
state, state.dataOutRptPredefined->pdchWscName, surfName, state.dataSurface->WindowShadingControl(curWSC).Name);
// shading report
OutputReportPredefined::PreDefTableEntry(
state,
state.dataOutRptPredefined->pdchWscShading,
surfName,
WindowShadingTypeNames[int(state.dataSurface->WindowShadingControl(curWSC).ShadingType)]);
OutputReportPredefined::PreDefTableEntry(
state,
state.dataOutRptPredefined->pdchWscControl,
surfName,
WindowShadingControlTypeNames[int(state.dataSurface->WindowShadingControl(curWSC).shadingControlType)]);
// output list of all possible shading contructions for shaded windows including those with storms
std::string names;