Line data Source code
1 : // EnergyPlus, Copyright (c) 1996-2023, The Board of Trustees of the University of Illinois,
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47 :
48 : #ifndef TranspiredCollector_hh_INCLUDED
49 : #define TranspiredCollector_hh_INCLUDED
50 :
51 : // ObjexxFCL Headers
52 : #include <ObjexxFCL/Array1D.hh>
53 :
54 : // EnergyPlus Headers
55 : #include <EnergyPlus/Data/BaseData.hh>
56 : #include <EnergyPlus/DataGlobals.hh>
57 : #include <EnergyPlus/DataVectorTypes.hh>
58 : #include <EnergyPlus/EnergyPlus.hh>
59 :
60 : namespace EnergyPlus {
61 :
62 : // Forward declarations
63 : struct EnergyPlusData;
64 :
65 : namespace TranspiredCollector {
66 :
67 : // Using/Aliasing
68 : using DataVectorTypes::Vector;
69 :
70 11 : struct UTSCDataStruct
71 : {
72 : // Members
73 : // from input data
74 : std::string Name;
75 : std::string OSCMName; // OtherSideConditionsModel
76 : int OSCMPtr; // OtherSideConditionsModel index
77 : int SchedPtr; // Availablity schedule
78 : Array1D_int InletNode; // Air system node "pointer", should be set to outdoor air
79 : Array1D_int OutletNode; // Air system node "pointer", outlet from UTSC
80 : Array1D_int ControlNode; // Air system node "pointer", should have mixed air setpoint
81 : Array1D_int ZoneNode; // Air system node "pointer", should have zone node
82 : int Layout; // 'Square' or 'Triangle'
83 : int Correlation; // which heat exchanger effectiveness model
84 : Real64 HoleDia; // Diameter of Perforations in Collector [m]
85 : Real64 Pitch; // Distance between Perforations in Collector [m]
86 : Real64 LWEmitt; // Thermal Emissivity of Collector Surface [dimensionless]
87 : Real64 SolAbsorp; // Solar Absorbtivity of Collector Surface [dimensionless]
88 : DataSurfaces::SurfaceRoughness CollRoughness; // surface roughness for exterior convection calcs.
89 : Real64 PlenGapThick; // Depth of Plenum Behind Collector [m]
90 : Real64 PlenCrossArea; // cross section area of plenum behind collector [m2]
91 : int NumSurfs; // a single collector can have multiple surfaces underneath it
92 : Array1D_int SurfPtrs; // = 0 ! array of pointers for participating underlying surfaces
93 : Real64 Height; // Overall Height of Collector [m]
94 : Real64 AreaRatio; // Ratio of actual surface are to projected surface area [dimensionless]
95 : Real64 CollectThick; // Thickness of collector absorber plate material. [m]
96 : Real64 Cv; // volume-based effectiveness of openings for wind-driven vent when Passive
97 : Real64 Cd; // discharge coefficient of openings for buoyancy-driven vent when Passive
98 : int NumOASysAttached; // =1 if no splitter, other wise set by Splitter object
99 : int FreeHeatSetPointSchedPtr; // used for controlling seperately from usual setpoint managers.
100 : int VsucErrIndex;
101 : // data from elswhere and calculated
102 : Real64 ActualArea; // Overall Area of Collect with surface corrugations.
103 : Real64 ProjArea; // Overall Area of Collector projected, as if flat [m2]
104 : Vector Centroid; // computed centroid
105 : Real64 Porosity; // fraction of absorber plate [--]
106 : bool IsOn; // .TRUE. means "on" or "ACTIVE" , .false means "off" or "PASSIVE
107 : Real64 Tplen; // modeled drybulb temperature for air between collector and wall [C]
108 : Real64 Tcoll; // modeled surface temperature for collector [C]
109 : Real64 TplenLast; // Old Value for modeled drybulb temp if air between collector and wall [C]
110 : Real64 TcollLast; // Old value for modeled surface temperature for collector [C]
111 : Real64 HrPlen; // Modeled radiation coef for OSCM [W/m2-C]
112 : Real64 HcPlen; // Modeled Convection coef for OSCM [W/m2-C]
113 : Real64 MdotVent; // air mass flow exchanging with ambient when passive.
114 : Real64 HdeltaNPL; // lenth scale for buoyancy-driven vent when Passive [m]
115 : Real64 TairHX; // air drybulb of air leaving collector when Active [C]
116 : Real64 InletMDot; // flow rate from outdoor mixer controller
117 : Real64 InletTempDB;
118 : Real64 Tilt; // Tilt from area weighted average of underlying surfaces
119 : Real64 Azimuth; // Azimuth from area weighted average of underlying surfaces
120 : Real64 QdotSource; // Source/sink term
121 : // reporting data
122 : Real64 Isc; // total incident solar on collector [W]
123 : Real64 HXeff; // heat exchanger effectiveness [--]
124 : Real64 Vsuction; // Average suction face velocity [m/s]
125 : Real64 PassiveACH; // air changes per hour when passive [1/hr]
126 : Real64 PassiveMdotVent; // Total Nat Vent air change rate [kg/s]
127 : Real64 PassiveMdotWind; // Nat Vent air change rate from Wind-driven [kg/s]
128 : Real64 PassiveMdotTherm; // Nat. Vent air change rate from buoyancy-driven flow [kg/s]
129 : Real64 PlenumVelocity; // effective velocity inside plenum [m/s]
130 : Real64 SupOutTemp; // supply air outlet temperature [C]
131 : Real64 SupOutHumRat; // supply air outlet humidity ratio [kg water/kg dry air]
132 : Real64 SupOutEnth; // supply air outlet enthalpy [J/kg]
133 : Real64 SupOutMassFlow; // supply air outlet mass flow rate [kg/s]
134 : Real64 SensHeatingRate; // rate of sensible heat being added to the supply (primary) air [W]
135 : Real64 SensHeatingEnergy; // sensible heat added to the supply (primary) air [J]
136 : Real64 SensCoolingRate; // rate of sensible heat being removed from the supply (primary) air [W]
137 : Real64 SensCoolingEnergy; // sensible heat removed from the supply (primary) air [J]
138 : Real64 UTSCEfficiency; // Total Efficiency (with wall) SensHeatingRate/IncidentRadiation[--]
139 : Real64 UTSCCollEff; // Collector-only Efficiency [--]
140 :
141 : // Default Constructor
142 6 : UTSCDataStruct()
143 6 : : OSCMPtr(0), SchedPtr(0), Layout(0), Correlation(0), HoleDia(0.0), Pitch(0.0), LWEmitt(0.0), SolAbsorp(0.0),
144 : CollRoughness(DataSurfaces::SurfaceRoughness::VeryRough), PlenGapThick(0.0), PlenCrossArea(0.0), NumSurfs(0), Height(0.0),
145 : AreaRatio(0.0), CollectThick(0.0), Cv(0.0), Cd(0.0), NumOASysAttached(0), FreeHeatSetPointSchedPtr(0), VsucErrIndex(0), ActualArea(0.0),
146 : ProjArea(0.0), Centroid(0.0, 0.0, 0.0), Porosity(0.0), IsOn(false), Tplen(0.0), Tcoll(0.0), TplenLast(22.5), TcollLast(22.0),
147 : HrPlen(0.0), HcPlen(0.0), MdotVent(0.0), HdeltaNPL(0.0), TairHX(0.0), InletMDot(0.0), InletTempDB(0.0), Tilt(0.0), Azimuth(0.0),
148 : QdotSource(0.0), Isc(0.0), HXeff(0.0), Vsuction(0.0), PassiveACH(0.0), PassiveMdotVent(0.0), PassiveMdotWind(0.0),
149 : PassiveMdotTherm(0.0), PlenumVelocity(0.0), SupOutTemp(0.0), SupOutHumRat(0.0), SupOutEnth(0.0), SupOutMassFlow(0.0),
150 6 : SensHeatingRate(0.0), SensHeatingEnergy(0.0), SensCoolingRate(0.0), SensCoolingEnergy(0.0), UTSCEfficiency(0.0), UTSCCollEff(0.0)
151 : {
152 6 : }
153 : };
154 :
155 : void SimTranspiredCollector(EnergyPlusData &state,
156 : std::string_view CompName, // component name
157 : int &CompIndex // component index (to reduce string compares during simulation)
158 : );
159 :
160 : void GetTranspiredCollectorInput(EnergyPlusData &state);
161 :
162 : void InitTranspiredCollector(EnergyPlusData &state, int const UTSCNum); // compindex already checked in calling routine
163 :
164 : void CalcActiveTranspiredCollector(EnergyPlusData &state, int const UTSCNum);
165 :
166 : void CalcPassiveTranspiredCollector(EnergyPlusData &state, int const UTSCNum);
167 :
168 : void UpdateTranspiredCollector(EnergyPlusData &state, int const UTSCNum);
169 :
170 : void SetUTSCQdotSource(EnergyPlusData &state,
171 : int const UTSCNum,
172 : Real64 const QSource // source term in Watts
173 : );
174 :
175 : void GetTranspiredCollectorIndex(EnergyPlusData &state, int const SurfacePtr, int &UTSCIndex);
176 :
177 : void GetUTSCTsColl(EnergyPlusData &state, int const UTSCNum, Real64 &TsColl);
178 :
179 : int GetAirInletNodeNum(EnergyPlusData &state, std::string const &UTSCName, bool &ErrorsFound);
180 :
181 : int GetAirOutletNodeNum(EnergyPlusData &state, std::string const &UTSCName, bool &ErrorsFound);
182 :
183 : } // namespace TranspiredCollector
184 :
185 771 : struct TranspiredCollectorData : BaseGlobalStruct
186 : {
187 :
188 : int NumUTSC = 0; // number of transpired collectors in model
189 : Array1D_bool CheckEquipName;
190 : bool GetInputFlag = true; // First time, input is gotten
191 :
192 : EPVector<TranspiredCollector::UTSCDataStruct> UTSC;
193 : bool MyOneTimeFlag = true;
194 : bool MySetPointCheckFlag = true;
195 :
196 : Array1D_bool MyEnvrnFlag;
197 :
198 0 : void clear_state() override
199 : {
200 0 : this->NumUTSC = 0;
201 0 : this->GetInputFlag = true;
202 0 : this->UTSC.deallocate();
203 0 : this->MyOneTimeFlag = true;
204 0 : this->MySetPointCheckFlag = true;
205 0 : this->MyEnvrnFlag.deallocate();
206 0 : }
207 :
208 : // Default Constructor
209 771 : TranspiredCollectorData() = default;
210 : };
211 : } // namespace EnergyPlus
212 :
213 : #endif
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