Simulation start timeThis value is used in the SIMULATION statement to fix the value for the hour of the year at which the simulation is to begin. See chapter 2 of the TRNSYS manual (Volume I) for details. Month Day hour hour JAN 1 0 744 FEB 32 744 1416 MAR 60 1416 2160 APR 91 2160 2880 MAY 121 2880 3624 JUN 152 3624 4344 JUL 182 4344 5088 AUG 213 5088 5832 SEP 244 5832 6552 OCT 274 6552 7296 NOV 305 7296 8016 DEC 335 8016 8760 real-Inf+Inf00hrTime[;]hrunamedSimulation stop timeThis value is used in the SIMULATION statement to fix the value for the hour of the year at which the simulation is to end. See chapter 2 of the TRNSYS manual (Volume I) for details. Month Day hour hour JAN 1 0 744 FEB 32 744 1416 MAR 60 1416 2160 APR 91 2160 2880 MAY 121 2880 3624 JUN 152 3624 4344 JUL 182 4344 5088 AUG 213 5088 5832 SEP 244 5832 6552 OCT 274 6552 7296 NOV 305 7296 8016 DEC 335 8016 8760 real-Inf+Inf1688760hrTime[;]hrunamedSimulation time stepThis value is used in the SIMULATION statement to fix the value for the timestep to be used. See chapter 2 of the TRNSYS manual (Volume I) for details.real-Inf+Inf11hrTime[;]hrunamedSolution methodThis value is used in the SOLVER statement to determine which of the two build-in numerical solvers TRNSYS should use. 0 = successive method (old solver). Must be used for buildings and systems with a thermal capacity 1 = Powels method (new solver) suitable for systems with many non-linear equations (low capacity) like PV-systems See chapter 2 of the TRNSYS manual (Volume I) for detailed description of both methods.booleanSuccessive substitutionPowell's methodSuccessive substitutionSuccessive substitution--[;]-unamedThe minimum relaxation factorThe minimum relaxation factorreal0.01111--[;]-unamedThe maximum relaxation factorThe maximum relaxation factorreal1.001011--[;]-unamedEquation solverEquation solverinteger0200--[;]-unamedEquation tracePif this value is "True" (On), Trace messages will be generated in the deck file.booleanTrueFalseFalseFalse--[;]-unamed Debug modeTIf this value is "True" (On), Debug commands will be added to the TRNSYS input file.booleanTrueFalseFalseFalse--[;]-unamedTolerance integrationThis value is used in the TOLERANCES statement to specify the error tolerance controlling the integration error to be used during a simulation. See chapter 2 of the TRNSYS manual (Volume I) for details.real0+Inf0.0010.001 dimensionless dimensionless[;] dimensionlessunamedTolerance convergenceThis value is used in the TOLERANCES statement to specify the error tolerance controlling the convergence of input and output variables to be used during a simulation. See chapter 2 of the TRNSYS manual (Volume I) for details.real0+Inf0.0010.001 dimensionless dimensionless[;] dimensionlessunamedTolerance valuesThis flag specifies if tolerances are specified as relative or absolute values. Using absolute values is only recommended in rare special cases.boolean Relatives Absolutes Relatives Relatives--[;]-unamedBefore 'WARNING'RThis value is used in the LIMITS statement to set limit on the number of iterations that will be performed by TRNSYS during a time step before it is determined that the differential equations and/or algebraic equations are not converging and a WARNING message is printed out. See chapter 2 of the TRNSYS manual (Volume I) for details.integer-Inf+Inf3030--[;]-unamedBefore 'ERROR'This value is used in the LIMITS statement to set limit on the number of warnings before the simulation is terminated and an ERROR message is printed. See chapter 2 of the TRNSYS manual (Volume I) for details.integer-Inf+Inf3030--[;]-unamedBefore 'TRACE'This value is used in the LIMITS statement to set the limit on the number of iterations during a time step before non-converging components are traced. See chapter 2 of the TRNSYS manual (Volume I) for details.integer-Inf+Inf3030--[;]-unamedDiff. equation algorithm4This value is used in the DFQ statement to select one of three algorithms built into TRNSYS to numerically solve differential equations: 1 = Modified-Euler method 2 = Non-self-starting Heun's method 3 = Fourth-order Adams method See chapter 2 of the TRNSYS manual (Volume I) for details.integer-Inf+Inf11--[;]-unamedNumber of charactersThis value is used in the WIDTH statement to set the number of characters to be allowed on a line of TRNSYS output. See chapter 2 of the TRNSYS manual (Volume I) for details.integer1+Inf8072 dimensionless dimensionless[;] dimensionlessunamed List card%This value will add a LIST/NOLIST statement to turn on/off the listing of the TRNSYS input file. It is recommended that LIST be used because the detection where an error / warning occurs in the TRNSYS input file is much easier. See chapter 2 of the TRNSYS manual (Volume I) for details.booleanLISTNOLISTLISTLIST--[;]-unamedMap cardThis value is used to obtain a component output map listing which may be useful in debugging component interconnections. See chapter 2 of the TRNSYS manual (Volume I) for details.booleanMAPNo MAPNo MAPNo MAP--[;]-unamedDeck file nameThis is the name of the file IISiBat uses to generate the TRNSYS input file. When a simulation is started, this file will be passed to TRNSYS for processing. Relative and absolute pathnames may be used.string-Inf+InfBuildingProject4.dck--[;]-unamedSimulation card string--[;]-unamedWrite TRNEdit commandsIf this value is "True" (On), TRNSED commands will be added to the TRNSYS input file. This allows the TRNEdit application to directly read the file generated by IISiBat. Switching this option "On" will force IISiBat to declare many additional constants in the TRNSYS input file. To avoid exceeding the number of allowed constants, you should either not use this option with big projects or "lock" variables ("locked" variables are excluded from this mechanism and do not appear in TRNSED).booleanTrueFalseFalseFalse--[;]-unamedWrite Studio commands to deck;If this value is "True" (On), Simulation Studio Meta-Commands will be added to the TRNSYS input file. These commands are treated by TRNSYS like comments, i.e. they will not have any influence on the simulation. However, they allow Trnsys Studio to better reconstruct a simulation project from a TRNSYS input file, using the File/Import function. This is useful for re-importing a modified TRNSYS Input file. If Meta-commands are not present in the import file, Trnsys Studio uses the ModelConfFile.conf file in the EXE directory to map UNIT declarations to PROFORMAs.booleanTrueFalseTrueTrue--[;]-unamedAutomatically launch pluginIf this option is selected, then if an executable file is defined in the comment for a model or in the outputs for an equation, then the executable is launched. Else, the classical dialog is opened.booleanTrueFalseFalseFalse--[;]-unamedDeck comment styleIf mode = 1, generate deck comments on one line, starting with "*". If mode = 2, generate deck comments on the same line, starting with "!". if mode = 3, don't generate deck comments.integer1322--[;]-unamedtrnDictionnary TEMPERATUREtrnModelInstancetrnPortNNCODBoolProperty|CODStringProperty^Port TPortCODEditProperties((>N>N (>:>: (bb (*b*b ((>b>b :: *:*:  CODCirclePort'Q-WP| ^ T ( CODConnectionNKQPCODFillProperties (5Vt CODTransform??DD ^Node10 TNodeCODImageComponentZC:\Trnsys17\Studio\Proformas\Output\Online Plotter\Online Plotter Without File\Type65d.bmpBM6(((Ը~_mkCSg?OhAPrL[gtˢfmuxqu^cS]wQ^gt򻤩x|ĮջӵV^vO]uɾ̩ѭǝrtvLYué͸ƩyyЩ̟rtwQ_žĦͽЪϤ_gˮؼӷѫϤǗgnֹÙİ~~ѫϤŖyϳѼΧϨ||zzxxwwѫΣؾʒssѠʦҪɒuussrrppЩӮ˖ҙ~~ɓ͙xxnnllkkiiӯǏϑnnkkggeebbW[yϧqqbbUUJNiuʻ΢®X[LXyVcxֱ·bdPZvR`myӻӯ¸_boIXͲcqɬmyԹؠӻξ^eƶ[eʽʻƴZeî\g츢؄cpӻv鞔koǺνؤmqǽüżٹӻckּɫmsο˵ɯָ̮ۼѺ((((+k:>b#??CODDWordProperty@6 ^Image TImage (CODTextComponent Temperature,, +cVt#??ADB CODIntProperty6CODFontPropertiesTimes New Roman  CODLineProperties  ^Text TText")BMvv( Xxwwww c?WIb#??$BA-./01)BMvv( X #3?:IE#??$B-./01CODRectComponent88::5Nt >  ^ Rectangle T Rectangle")jBMv6( @ , IS#?? pA-./01)kBMvv( P  ?K^ ?IIS#??$BpA-./01trnLayerMain # Temperature?.\Output\Online Plotter\Online Plotter Without File\Type65d.tmftrnMacroInstance                    @:%& ^Node()*C:\Trnsys17\Studio\Exe\..\Lib\NEWMACRO.bmpBM66(   #??-./012 First Macro** !:2#??A$B 5789:;Times New Roman => @A")BMvv( Xxwwww !+ #??BA-./01)BMvv( X !+ #??B-./01F@@::@:H> JK")jBMv6( @  #?? 0A-./01)kBMvv( P  ! +#??B0A-./01PDummy First MacronulltrnVariableSetSdCtrnVariableSetElementtrnVariableInstanceInput1string-Inf+Inf0anyany[;]otrnEquationInstanceyy (yy (ee ( ( (( ee ee |! "{ebh! "~! "}! "}0$`#??7CB%& ^Node2()*C:\Trnsys17\Studio\Exe\..\Lib\NEWEQUAT.bmpBM6(((xq|wwwépǯxq|wwwwwwĩÅsɱ£ÌvĊtؓ}xfnapgxr|zzz¦ƈvʲäƏyȊx؏xŅoŌw㣉ۖzgpbwnɊx°˳ĥКȯ£褉訌qɉẇrޞ՛ѕ~򪏭̌zIJ̵Ŧգ޽ϴ⩎ΙæӔ|ۡsωtˊtçΎ{ƴͶƧΤԺϥѤܽפқĬۙ¤ѐ}ȷηǨƧ豕֠Ŧ賙׳ɯ٧ᬔн޾輤ﳗԒʺϸȨҞmÃoΑyƧŦءએŦŦѤ©͠ĥ֔̽кɩʕݛﵘuoÃo᥋ǧ᫑͘åƨĤؖξѺʪӦ׶Ͳ᫑̗є}汖pʇsȊuȩ¤ۘһ˫綜ɸ޺ХٻդΚ㣊ﶚݚӼ̭̬嵛֪崘ˬޯѽӧⰘѿ޾ʲ粘ߜԽͭᄀno䯔̭̭緝٫ǩ̭ЦպϥɫĤ⟋տήđ|㡋ˍvǩҡoqίūǩϱœ¨㡍տϯТӺͮ䰖Ƒ~ϔ~ŭNxMqnгġ壏аԨҺ縞Ф׻Զ֦fskõšé祒ѱɪΧ¨ϣаԪծꊰƣĩ騕ҲҲҲɪҲҳ̮ҩծ齡ѵqzĸ̨¦쫗ӳӳӳӴӴӴԵԵԶԶշ˷»׻ͫԴ껝ҟפգգ֢ئ嵙ƩԷֹ׺ػؽͭӴӘ|œ㨉נ֢գ帞ھѲçǨsux{}㩉鼢Դ¤Ҳ؍i^`bfhjmqtwz}՝ַ׸כ|SNOQTVWY]_adԗzٺظعۢ֒pՌi։dوa^WPMMNY٤ĤŵܼۻۻۻڻڻԵŧ綘ܨ՟ל~טzۥñдı۹ɲż־պԷնԴڹ§˭ԳȯĽ¸ĺ((((e#??-./012 Radiation$$ U #??ADB 5789:<=?@A")BMvv( Xxwwww `v6#??$BA-./01)BMvv( X 0ep#??$B-./01F33::@p`HIJK")jBMv6( @ @t~#?? pA-./01)kBMvv( P  @ t~#??$BpA-./01PMain RadiationnullSuowdqsAZENstring-Inf+Infanyany[;] trnConnectiontrnLink0-3! "^[a00 ; 3#??dF6 ^Link TLink trnLinkShape000I3 > 6M26L26K26J2 ^Line TLine"sAI_H_0_0string-Inf+Infanyany[;]anyunameds 21- AI_H_0_0(ANGLE OF INCIDENCE FOR ORIENTATION H_0_0real-Inf+Inf00degreesDirection (Angle)[;]otrnModelInstance56DD (DD (00 (XX (XX ((XX 00 GMD AG! "0-3! "0-3! "XU[! "X U[! "$jo+j#??9D D%& ^Node9()PC:\Trnsys17\Studio\Proformas\Loads and Structures\Multi-Zone Building\Type56.bmpBM6(((#.#.ٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕU-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-ٖٕU-U-MMMPPPKKKKKKKKKKKKKKKKKKKKKKKKKKKKKKRNJaUJiZJg\Ob\S`YLOMJKKKKKKKKKKKKKKKJJJLLLU-U-U-U-U-U-U-ٖٕU-U-1f|||U-U-U-U-U-ٖٕU-U-󳳳~UQwwwԽU-U-U-U-ٖٕU-U-صbmjwwwU-U-ٖٕU-U-`k_yyyU-ٖٕU-U-ǟck_ʗgggU-ٖٕU-U-䴺bk_½pppU-ٖٕU-U-￿Ჸbk_ļoooU-ٖٕU-U-U-뿿Ჸbk_ĺoooU-ٖٕU-U-U-Ჸbk_ɺoooU-ٖٕU-U-U-ѼᲸbk_ɺyujU-ٖٕU-U-U-ѼᲸbk_ɺnosU-ٖٕU-U-U-ѼᲸbk_½nosU-ٖٕU-U-U-ḿak_nosU-ٖٕU-U-iih`c_ɺnosU-ٖٕU-U-qppNnosU-ٖٕU-fffnnnU-ٖٕU-U-OOOnnn|||oooiiiU-ٖٕU-U-U-RRRůeeeӐU-ٖٕU-U-U-U-TTTaaayyyU-ٖٕU-U-U-U-U-\\\٦XXX뜜U-ٖٕU-U-U-U-U-U-qqqvvv̟RRRU-ٖٕU-U-U-U-U-U-U-^^^ܲ﫫PPPU-ٖk%,۳6ёIQU-U-U-U-QQQݼ]]]󷷷U-U-ٖ^>wT.U-U-U-NNNȢxxxqqqԻU-U-U-ٖ^!JOU-U-U-WWW՛```U-U-U-U-ٖ^BiU-U-U-iii}}}ڨSSSU-U-U-U-U-ٖ^BiU-U-U-dddݶMMMU-U-U-U-U-U-ٖ^JOU-U-U-WWWbbbzzzU-U-U-U-U-U-U-U-ٖ^!T.U-U-U-üU-U-U-U-U-U-U-U-U-ٖ^>vU-U-U-U-U-ǾU-U-U-U-U-U-U-U-U-U-ٖ^U-U-U-U-U-U-U-пU-U-U-U-U-U-U-U-U-U-U-U-ٖ^JOU-U-U-U-U-U-U-U-̹U-U-U-U-U-U-U-U-U-U-U-U-U-ٖ^6ѐU-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-ٖ^,۳U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-ٖ^%U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-U-ٖ^^^^^^^^^^^^^lٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕٕ((((0X#??-./012Building!! +)Yj#??ADB 5789:<=?@A")BMvv( Xxwwww ޡMX#??$BA-./01)BMvv( X 0;#??$B-./01F55::?#q +jHIJK")jBMv6( @ N?I#?? pA-./01)kBMvv( P  ҡc ?I#??$BpA-./01QBuilding5.\Loads and Structures\Multi-Zone Building\Type56.tmfSo2qs 1- TAIR_ZONE_E4(air temperature of airnode, Zone ZONE_E4real-Inf+Inf00C Temperature[;]SPV vK[#??XXNNK[ "sLeft axis variableSNXThe specified variable which is to be plotted using the left Y-axis for scaling purposessimplestring+-Inf+InflabelZone_E4anyany[ ; ]osNb. of left-axis variablesSNXThe number of variables that will be plotted using the left Y-axis for scaling purposes.simpleinteger+01021- Dimensionless[ ; ]o2 qqsNb. of right-axis variablesSNWThe number of variables that will be plotted using the right axis for scaling purposes.simpleinteger+01021- Dimensionless[ ; ]-Nb. of right-axis variablesqsLeft axis minimumSN&The minimum value for the left Y-axis.simplereal+-Inf+Inf0.0-0.2- Dimensionless[ ; ]-Left axis minimumqsLeft axis maximumSN&The maximum value for the left Y-axis.simplereal+-Inf+Inf1000.01.2- Dimensionless[ ; ]-Left axis maximumqsRight axis minimumSN'The minimum value for the right Y-axis.simplereal+-Inf+Inf0.00.0- Dimensionless[ ; ]-Right axis minimumqsRight axis maximumSN'The maximum value for the right Y-axis.simplereal+-Inf+Inf1000.05000- Dimensionless[ ; ]-Right axis maximumqsNumber of plots per simulationSN9Number of plots per simulation. Use -1 for monthly plots.simpleinteger+-1+Inf11- Dimensionless[ ; ]-Number of plots per simulationqsX-axis gridpointsSNFThe number of grid points that the X-axis (time) will be divided into.simpleinteger+1+Inf1212- Dimensionless[ ; ]-X-axis gridpointsqsShut off Online w/o removingSNThis parameter can be used to shut off the ONLINE without removing from the assembly panel / input file, according to the following rules: -1 : don't display online >=0 : display onlinesimpleinteger+-1000- Dimensionless[ ; ]-Shut off Online w/o removingqsLogical unit for output fileSNThis parameter is not used in this mode since no ouptut file is created. Please use the "online plotter with file" if you want to simultaneously plot the data and print it to a file.simpleinteger+-1-1-1-1- Dimensionless[ ; ]-Logical unit for output fileqsOutput file unitsSNGThis parameter is not used in this mode since no output file is createdsimpleinteger+0000- Dimensionless[ ; ]-Output file unitsqsOutput file delimiterSNGThis parameter is not used in this mode since no output file is createdsimpleinteger+0000- Dimensionless[ ; ]-Output file delimiter -Nb. of left-axis variablesNb. of left-axis variables qanyLeft axis variable! "gndkjq k A#??DDɠA > "s 2- TSO_S4Soutside surface temperature ->WALL=OUTWALL:KNOWN BOUNDARY, Zone ZONE_E4 , Surface 4real-Inf+Inf00C Temperature[;]CunamedsInput to be printed-2SNInput to be printedsimplestring+-Inf+InflabelTZONEanyany[ ; ]o( ( ( ( ((   3#??oD@!D%& ^Node11()0C:\Trnsys17\Studio\lib\System_Output\Type25a.bmpBM6(((xTdg~舘ctxm}zףtM[_hw{\kpL[`N^cgx}TejK[`l}cruŋ\jnSbf{Sbfbsx{M]buIY]ڡtN\`fvz]lqjzM_dKY]hw{·ȾĊ]koRaf{_nsRciÂT`cLY]KZ^aptzŻQ_cjy}N]bTflҿΙ|dloZdfR^aIX[O^bfty~¸ɾXfj^mrTfl׮zajlXbeP]`HWZTcgjy}HW[sctz𳳲Ԫv^gjVadN[_IW[Yhlm|_nrXgkfv{~wѧs{~\ehT`cVbfpŰxඥĽѻ̳~۾ͤơfv{ɵŨcw}Ľѻ̳}ٮiz~vηtĽѻ̳bzwgx}m·ǩVr煙ji~Ğ紬vr{d\ktvhkk{vsŶオj~Ǖ^Khqsjkkyv˽·oziǺzfnpllk|y|yz}vƠԾvsqf{lxi}h[øġlZp]oǛt٬ȳּn̕ɱڵċuČx³ή»٫םϚӟܥ㮛ź׺أٙޟ㮛軬ɽۤ¸ܸޮߥ⟈竖븥ĵ개µ⹩䰜㸧((((@#??-./012System_Printer33 x&n(#??ADB 5789:<=?@A")BMvv( Xxwwww #??$BA-./01)BMvv( X $ #??$B-./01F88::|`5HIJK")jBMv6( @ h|2#?? pA-./01)kBMvv( P  غ#??$BpA-./01P OutputSystemSystem_Printer.\Trnsys17\Studio\lib\System_Output\Type25a.tmfSo 2q o 2o 2 qsPrinting intervalSNHThe time interval at which printing is to occur. If the time interval is less than zero, then the print interval will be measured in the absolute value of this parameter expressed in months. Examples: 1: print every hour -1: print every month The default value (STEP) is a TRNSYS parameter equal to the simulation time stepsimplereal+-12+InfSTEPSTEPhrTime[ ; ](hrPrinting intervalqs Start timeSNThe time of the year in hours at which printing is to start. The default value (START) is a TRNSYS parameter equal to the simulation start timesimplereal+0+InfSTARTSTARThrTime[ ; ](hr Start timeqs Stop timeSNThe time of the year in hours at which printing is to stop. The default value (STOP) is a TRNSYS parameter equal to the simulation stop timesimplereal+0+InfSTOPSTOPhrTime[ ; ](hr Stop timeqs Logical unitSNThis parameter sets the Fortran Logical Unit (File reference number) of the output file. It is used internally by TRNSYS to refer to the file. This parameter will automatically be assigned to a unique value by the TRNSYS Studiosimpleinteger+309993032- Dimensionless[ ; ](- Logical unitqsUnits printing modeSNSThis parameter is set to 2, so TRNSYS-supplied units are printed to the output filesimpleinteger+2222- Dimensionless[ ; ](-Units printing modeqsRelative or absolute start timeSNThis parameter controls whether the print intervals are relative or absolute 0: print at time intervals relative to the simulation start time 1: print at absolute time intervals For example, if the simulation start time is 0.5, the simulation time step is 0.25 and the printing time step is 1: If this parameter is set to 0, printing will occur at 0.5, 1.5, 2.5, etc. If this parameter is set to 1, printing will occur at 1, 2, 3, etc.simpleinteger+0100- Dimensionless[ ; ](-Relative or absolute start timeqsOverwrite or AppendSNThis parameter decides whether the file is appended to or overwritten: -1: Overwrite the output file 1: Append to the output filesimpleinteger+-11-1-1- Dimensionless[ ; ](-Overwrite or Appendqs Print headerSNThis parameters decides whether or not a header with input file information will be printed to the output file or not -1: Do not print header 1: Print headersimpleinteger+-11-1-1- Dimensionless[ ; ](- Print headerqs DelimiterSNThis parameter controls the delimiter used in the output file: 0: use tabs to delimit columns 1: use spaces to delimit columns 2: use commas to delimit columnssimpleinteger+0200- Dimensionless[ ; ](- Delimiterqs Print labelsSNThis parameter decides whether or not labels (variable descriptors) should be printed as column headers: -1: Do not print descriptors 1: Print descriptorssimpleinteger+-1111- Dimensionless[ ; ](- Print labels o 2trnExternalFile}Which file should contain the printed results? You can use the deck filename by entering "***", e.g. "***.out", or "***.dat" Type25a.txt***.out Logical unit 7How many variables are to be printed by this component?dqsInput to be printed-1SNInput to be printedsimplestring+-Inf+InflabelTZONEanyany[ ; ] anyInput to be printedq anyInput to be printedACunamedq o2qs1Logical unit for building description file (.bui)SN,The logical unit through which the building description file will be read. Each external file that TRNSYS reads from or writes to must be assigned a unique logical unit number in the TRNSYS input file. The building description file is created by the PREBID program and typically has a .BLD extension.simpleinteger+309993031- Dimensionless[ ; ]D-1Logical unit for building description file (.bui)qsStar network calculation switchSNThis parameter indicates whether the star network calculations should be performed only at the beginning of the simulation (=0) or at every timestep (=1). For most simulations, the star network can be calculated just at the beginning of the simulation. However, if the convective heat transfer coefficient at the inside surface of any of the walls in the building is variable (not a constant value), this parameter should be set to 1.simpleinteger+010001- Dimensionless[ ; ]D-Star network calculation switchqs*Weighting factor for operative temperatureSN<The weighting factor for the operative room temperature. The operative room temperature is a function of both the air and surface temperatures in the zone: Top = Aop*Tair + (1-Aop)*Tsurf (See manual for further information on equation) This temperature is used most often in room comfort analysis simulations.simplereal+0.01.00.500.5- Dimensionless[ ; ]D-*Weighting factor for operative temperatureo2>!Building description file (*.bui)BuildingProject4.b171Logical unit for building description file (.bui)8 82qs 1- TAMBAMBIENT TEMPERATUREreal-Inf+Inf00C Temperature[;]SPV! "Q##SS 蟳P3#??SS00;ɄP3 "PsDry bulb temperatureSN*The dry bulb temperature of the moist air.simplereal+-Inf+Inf00C Temperature[ ; ]oAA #AA #00 #SS #SS T00 00 GM0-3! "`0-3! "]S++j#??@CC%& ^Node5()C:\Trnsys17\Studio\Proformas\Physical Phenomena\Thermodynamic Properties\Psychrometrics\Dry Bulb and Relative Humidity Known\Type33e.bmpBM6(###.#.ۦΔদaa==LLۊ깹—uu׳bbBBKKۈң]]ՂDDQQuu㳳gg77qqⲲߎ88׊77\\޷uuPPUUݛ<<ؾ==eeUUKKvvҧaaxx@@tt>>ءvvCCtt⡡YYݕrr88׫77ddll99׀@@琐BBYY__ee॥vvPPAA``hhHHڋmmRRLL۝AAjjAAٴCC__||䚚nn憆vvGGڭ񕕟77mm狋TTllTTܱ嶶KK;;MMSSKKLLUUnn^^ޯRRUUrrTTܙMMM[[99MٌٌٌMnnⴴMٌٌMssMٌٌMff飣MٌMNN;;ٌٌyyٌM==jjM飣99``llMMLL~~嵵𝝝IIMM۝YYjj}}׳####&0S#??-./012Psychrometrics44  Te#??A0B 5789:<=?@A")BMvv( Xxwwww _HS#??BA-./01)BMvv( X {0;#??B-./01F88::kvF+jHIJK")jBMv6( @ <F#?? @A-./01)kBMvv( P  <F#??B@A-./01Psychrometricsm.\Physical Phenomena\Thermodynamic Properties\Psychrometrics\Dry Bulb and Relative Humidity Known\Type33e.tmfSoZ2qsDry bulb temp.SN$The dry bulb temperature of the air.simplereal+-Inf+Inf22.020C Temperature[ ; ]vpms! "d{((pp c ü2p3#??p00 p3 "yzsrelative humiditySNambient relative humiditysimplereal+-Inf+Inf00anyany[ ; ]oHH (pp (pp (HH (\\ ~HH \\ V\pms! "}pms! "~hg #??B0C%& ^Node4()fC:\Trnsys17\Studio\Proformas\Weather Data Reading and Processing\Standard Format\TMY2\Type109-TMY2.bmpBM6(((љՙdqҼZұW[̚&5ĕ}e~ft[lUiUiWtdƿeaɟUm"a*c=a<`>_@O-D'yN;u`*%SХݑBe)Y4]<\>V5Z:^@eKfKS4=!yYJWJЙw#LB>LP=?CK$S0^@_@AtK9o??[צj< 657CE_C867; ER.\:?!uSC¸ĭ}߾ՙÇz;8=BELf&aIC>96< L&`N?'rfԮ빲뺱鷰鷰鷰鷰鷰ݺYlsZm~Uq=XRUZkkEaTMG?8IfHZ@{E.ӮёyެUȧHW{\mcinxwtf[ULCOmf6eEC~rӮɶm۳T8-A̬]Ep34{pgaZQY[ Hg$og7S+_LӮʟ\ڲ4 .Sȝa€_a}wqm0ohf#gKg&{_-Q5¼ֱ֣C?:C>9C=8ѼXѧ. 1GΜUanԎ}{||tk g.flZP/ļײwnfȗCͭ8=}{yu_WORܬg՜}Җj6 *Mcͅħ}|l> Dxǜßƨ^]]%%$}U4-EgƨGGGuuuާva_jƨGGG555TSR~}{㪡ǩ999===㪡ȩWWW䧝ɪ______栖ͬ瓔坔ܸέ㻥ᨏउߜܙӘ}ҤÆhЮ㰈?ނɗvΜΜyX`͛ӯ䷖{JBץ|ΜΜyX`͛ӯ仚͊[׬ҤÆhӯ>>>忞ԝٱܸ԰ẛݽ׷׷׶նӵѲϱжεεʹʳɲɱȱįí­((((Hp#??-./012 Weather data// L.#??ADB 5789:<=?@A")BMvv( Xxwwww `"q{#??$BA-./01)BMvv( X H3q{#??$B-./01FKK::W HIJK")jBMv6( @ Xb >H#?? pA-./01)kBMvv( P  4uq{#??$BpA-./01 Weather dataK.\Weather Data Reading and Processing\Standard Format\TMY2\Type109-TMY2.tmfSo2qsGround reflectanceSNThe reflectance of the ground above which the surface is located.Typical values are 0.2 for ground not covered by snow and 0.7 forground covered by snow.simplereal+0.01.00.20.2- Dimensionless[ ; ]-Ground reflectanceqo7How many surfaces are to be evaluated by This Type 109?qsSlope of surface-1SNThe slope of the surface or tracking axis. The slope is positivewhen tilted in the direction of the azimuth. 0 = Horizontal90 = Vertical facing toward azimuthRefer to the abstract for details on slope specification for trackingsurfaces.simplereal+0+Inf0.090degreesDirection (Angle)[ ; ]degreesSlope of surfaceqsAzimuth of surface-1SN"The solar azimuth angle is the angle between the local meridian andthe projection of the line of sight of the sun onto the horizontalplane.0 = Facing equater90 = Facing west180 = Facing north270 = Facing eastRefer to the abstract for deatils on the azimuth parameter for tracking surfaces.simplereal+-360+3600.0AA_NdegreesDirection (Angle)[ ; ]degreesAzimuth of surfaceqsSlope of surface-2SNThe slope of the surface or tracking axis. The slope is positivewhen tilted in the direction of the azimuth. 0 = Horizontal90 = Vertical facing toward azimuthRefer to the abstract for details on slope specification for trackingsurfaces.simplereal+0+Inf0.090degreesDirection (Angle)[ ; ]degreesSlope of surfaceqsAzimuth of surface-2SN"The solar azimuth angle is the angle between the local meridian andthe projection of the line of sight of the sun onto the horizontalplane.0 = Facing equater90 = Facing west180 = Facing north270 = Facing eastRefer to the abstract for deatils on the azimuth parameter for tracking surfaces.simplereal+-360+3600.0AA_SdegreesDirection (Angle)[ ; ]degreesAzimuth of surfaceqsSlope of surface-3SNThe slope of the surface or tracking axis. The slope is positivewhen tilted in the direction of the azimuth. 0 = Horizontal90 = Vertical facing toward azimuthRefer to the abstract for details on slope specification for trackingsurfaces.simplereal+0+Inf0.090degreesDirection (Angle)[ ; ]degreesSlope of surfaceqsAzimuth of surface-3SN"The solar azimuth angle is the angle between the local meridian andthe projection of the line of sight of the sun onto the horizontalplane.0 = Facing equater90 = Facing west180 = Facing north270 = Facing eastRefer to the abstract for deatils on the azimuth parameter for tracking surfaces.simplereal+-360+3600.0AA_EdegreesDirection (Angle)[ ; ]degreesAzimuth of surfaceqsSlope of surface-4SNThe slope of the surface or tracking axis. The slope is positivewhen tilted in the direction of the azimuth. 0 = Horizontal90 = Vertical facing toward azimuthRefer to the abstract for details on slope specification for trackingsurfaces.simplereal+0+Inf0.090degreesDirection (Angle)[ ; ]degreesSlope of surfaceqsAzimuth of surface-4SN"The solar azimuth angle is the angle between the local meridian andthe projection of the line of sight of the sun onto the horizontalplane.0 = Facing equater90 = Facing west180 = Facing north270 = Facing eastRefer to the abstract for deatils on the azimuth parameter for tracking surfaces.simplereal+-360+3600.0AA_WdegreesDirection (Angle)[ ; ]degreesAzimuth of surfaceo2qsData Reader ModeSN~The mode of the weather data reader 109 : The value 2 means that Type 109 will read a Standard weather file in the TMY2 formatsimpleinteger+2222- Dimensionless[ ; ]-Data Reader Modeqs Logical unitSNThis parameter sets the Fortran Logical Unit (File reference number) of the output file. It is used internally by TRNSYS to refer to the file. This parameter will automatically be assigned to a unique value by the TRNSYS Studiosimpleinteger+309993030- Dimensionless[ ; ]- Logical unitqsSky model for diffuse radiationSNThis parameter selects the sky model used to calculate diffuse radiation on tilted surfaces. 1: Isotropic sky model 2: Hay and Davies model 3: Reindl model 4: Perez model Note: The Perez model is usually considered to be the best available modelsimpleinteger+1444- Dimensionless[ ; ]-Sky model for diffuse radiationqs Tracking modeSN,This parameter is used to indicate that the surfaces on which the tilted surface radiation is calculated are tracking the sun. 1: Fixed surface 2: Single axis tracking, vertical axis (fixed slope, variable azimuth) 3: Single-axis tracking, axis is in the plane of the surface 4: Two-axis trackingsimpleinteger+1411- Dimensionless[ ; ]- Tracking modeo2>Weather data fileBC:\Users\MAlHamahmy\Documents\Masdar\CTF\Weather Data\x - Copy.TM2).\Weather\US-TMY2\US-WI-Madison-14837.tm2 Logical unitmm2qsAmbient temperatureSNambient temperaturesimplereal+-Inf+Inf00C Temperature[ ; ]yCAmbient temperatureqqs wind velocitySN wind speedsimplereal+-Inf+Inf00m/sVelocity[ ; ]m/s wind velocityqswind directionSNwind direction N=0, E=90simplereal+-Inf+Inf00degreesDirection (Angle)[ ; ]degreeswind directionqsAtmospheric pressureSNAtmospheric pressuresimplereal+-Inf+Inf00PaPressure[ ; ]PaAtmospheric pressureqsuserdefined data 2SN/Sixth value read from data file (if PAR 2 > 5).simplereal+-Inf+Inf00anyany[ ; ]anyuserdefined data 2qsuserdefined data 3SN1Seventh value read from data file (if PAR 2 > 6).simplereal+-Inf+Inf00anyany[ ; ]anyuserdefined data 3qsuserdefined data 4SN.Eigth value read from data file (if PAR 2 > 7)simplereal+-Inf+Inf00anyany[ ; ]anyuserdefined data 4qs(extraterrestrial radiation on horizontalSN/Ninth value read from data file (if PAR 2 > 8).simplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ] kJ/hr.m^2(extraterrestrial radiation on horizontalqssolar zenith angleSN/Tenth value read from data file (if PAR 2 > 9).simplereal+-360+36000degreesDirection (Angle)[ ; ]^p#??p p "s&angle of incidence for tilted surface -4SNsimplereal+-Inf+Inf00degreesDirection (Angle)[ ; ]o7How many surfaces are to be evaluated by This Type 109?qs!total radiation on tilted surface-1SN5Eighteenth value read from data file (if PAR 2 = 18).simplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ]sInput8string-Inf+Inf0anyany[;]uanyunamed kJ/hr.m^2!total radiation on tilted surfaceqs beam radiation on tilted surface-1SNsimplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ]sInput9string-Inf+Inf0anyany[;]uanyunamed kJ/hr.m^2 beam radiation on tilted surfaceqs'sky diffuse radiation on tilted surface-1SNsimplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ] kJ/hr.m^2'sky diffuse radiation on tilted surfaceqs4ground reflected diffuse radiation on tilted surface-1SNsimplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ] kJ/hr.m^24ground reflected diffuse radiation on tilted surfaceqs&angle of incidence for tilted surface -1SNsimplereal+-Inf+Inf00degreesDirection (Angle)[ ; ]sInput10string-Inf+Inf0anyany[;]uanyunameddegrees&angle of incidence for tilted surface qsslope of tilted surface-1SNsimplereal+-Inf+Inf00degreesDirection (Angle)[ ; ]degreesslope of tilted surfaceqs!total radiation on tilted surface-2SN5Eighteenth value read from data file (if PAR 2 = 18).simplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ]sInput11string-Inf+Inf0anyany[;]uanyunamed kJ/hr.m^2!total radiation on tilted surfaceqs beam radiation on tilted surface-2SNsimplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ]sInput12string-Inf+Inf0anyany[;]uanyunamed kJ/hr.m^2 beam radiation on tilted surfaceqs'sky diffuse radiation on tilted surface-2SNsimplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ] kJ/hr.m^2'sky diffuse radiation on tilted surfaceqs4ground reflected diffuse radiation on tilted surface-2SNsimplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ] kJ/hr.m^24ground reflected diffuse radiation on tilted surfaceqs&angle of incidence for tilted surface -2SNsimplereal+-Inf+Inf00degreesDirection (Angle)[ ; ]sInput13string-Inf+Inf0anyany[;]uanyunameddegrees&angle of incidence for tilted surface qsslope of tilted surface-2SNsimplereal+-Inf+Inf00degreesDirection (Angle)[ ; ]degreesslope of tilted surfaceqs!total radiation on tilted surface-3SN5Eighteenth value read from data file (if PAR 2 = 18).simplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ]sInput14string-Inf+Inf0anyany[;]uanyunamed kJ/hr.m^2!total radiation on tilted surfaceqs beam radiation on tilted surface-3SNsimplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ]sInput15string-Inf+Inf0anyany[;]uanyunamed kJ/hr.m^2 beam radiation on tilted surfaceqs'sky diffuse radiation on tilted surface-3SNsimplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ] kJ/hr.m^2'sky diffuse radiation on tilted surfaceqs4ground reflected diffuse radiation on tilted surface-3SNsimplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ] kJ/hr.m^24ground reflected diffuse radiation on tilted surfaceqs&angle of incidence for tilted surface -3SNsimplereal+-Inf+Inf00degreesDirection (Angle)[ ; ] sInput16string-Inf+Inf0anyany[;]u anyunameddegrees&angle of incidence for tilted surface qsslope of tilted surface-3SNsimplereal+-Inf+Inf00degreesDirection (Angle)[ ; ]degreesslope of tilted surfaceqs!total radiation on tilted surface-4SN5Eighteenth value read from data file (if PAR 2 = 18).simplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ]sInput17string-Inf+Inf0anyany[;]uanyunamed kJ/hr.m^2!total radiation on tilted surfaceqs beam radiation on tilted surface-4SNsimplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ]sInput18string-Inf+Inf0anyany[;]uanyunamed kJ/hr.m^2 beam radiation on tilted surfaceqs'sky diffuse radiation on tilted surface-4SNsimplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ] kJ/hr.m^2'sky diffuse radiation on tilted surfaceqs4ground reflected diffuse radiation on tilted surface-4SNsimplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ] kJ/hr.m^24ground reflected diffuse radiation on tilted surfaceqqsslope of tilted surface-4SNsimplereal+-Inf+Inf00degreesDirection (Angle)[ ; ]degreesslope of tilted surfacedegrees&angle of incidence for tilted surface sInput19string-Inf+Inf0anyany[;]uanyunamed s(angle of incidence on horizontal surfaceSN4Sixteenth value read from data file (if PAR 2 > 15).simplereal+-Inf+Inf00degreesDirection (Angle)[ ; ]!degrees(angle of incidence on horizontal surfacesInput7string-Inf+Inf0anyany[;]u!anyunameds#sky diffuse radiation on horizontalSN5Fourteenth value read from data file (if PAR 2 > 13).simplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ]$VSY! "(VV ԙY%pV#??p::V!pV "&'sbeam radiation on horitonzalSN5Thirteenth value read from data file (if PAR 2 > 12).simplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ]/sInput5string-Inf+Inf0anyany[;]u0anyunamed. kJ/hr.m^2beam radiation on horitonzals Beam radiation on the horizontalSNsimplereal+0+Inf00 kJ/hr.m^2Flux[ ; ]oV V  #y y  #yy 'V!V! 'g!g! #'y!y! +gg djV!SY$! "8*y!v|$! ":+@4#??CzC%& ^Node6()gC:\Trnsys17\Studio\Proformas\Physical Phenomena\Sky Temperature\calculate cloudiness factor\Type69b.bmpBM6(#'t#.#.߾޼۶ڵׯׯ֭ԩԩԩ޽۷ڵذ׮ԩԩӦѢѢѢѢѢѢѢѢ޽۷ڵ֯ѮϧѢѢϟ͚͚͚͚͚͚͚͚͚͚ϟѢѢ޽۷۶׮Ϭϟ͚̘ʔʔʔȔȔʔʔʔʔʔ̘͚ϟѢӧժ׮۶۷޽۷ڵ׮Ԩ۲͚̘ɓȑƌƌȓƌҲڱϵڵ۷޽۷ڵ׮ԩѢϟ̙ʕȑƍŊ……ү…Ӳ}rn㳘׮ڵ۷ڵׯժӧϟʙȑƌĉ…~Ԩѽ~~vnocvvlQHKH¼ׯڵذ׮ӧР̚~|wwҤԨwwxkrkwl{n>6?=׮ذ׮ӧѢ͚̝{vtpppppppżpcpdpdpdthMEӧ׮ԩѢϟ̙ҥ{uqmjiiiiii湲pcpcpdpdpd\Q _[ѢԩԩѢ͚ʔС֬uqmieaaaaaa͸tpcpcpdpdB:daѢԩӦϟ̘ȑ˗Ĉ˗qmgc^ZZZZZZ⪣xpcWM,'1-ϟӦ׮Ѣ͚ʔƍÆ|unic_XTTTTTTڢȹ丱LC50QMvnٱ͚ѢժѢ͚ʔƍ…~wԨ˦uLLLM^ӟ˖͚ѢժѢ͚ʔƍ…~…ܷڵرmEIMYȑʔϢժѢ͚ʔƍ…ŋݺ͛ZTLqҦpJELTʷƍ΢ժϞ˗ȑĉˤe^WPHB;htjBHPȵĉœΞӦϞ˗ȑĉƐme^WPnТdWHPȷĉȑ˗ϞӦѢ͚ʔƍ͛piai”͙̙̰XLTƶ촎ǔ͚ѢժѢ͚ʔƍ͛pipӦwEEpkIMT½źͽ˚ѢժѢ͚ʔƍʘpjƍ}MLLLLMQXĸ̚ѢժѢ͚ʔƍŌغuĈ_XTTTTTTX_µܹɓʔ͚ѢժӦϟ̘ȑĉϟc^ZZZZZZ^Ѣ.(öץȑ̘ϟӦ׮ԩѢ͚ʔƍɒieaaaaaae϶ƍʔ͚ѢԩذԩѢϟ̙ȑƌǎmjiiiiiij}ȑ̙ϟѢԩذ׮ӧѢ͚ʔȑŊǎڻȐtppppppppzιʔ͚Ѣӧ׮ڵذ׮ӧР̙ʔȑŊōƓ~|wwwwwwww|̙Рӧ׮ذ۷ڵׯժӧϟ̙ʕȑƌĉ…~~~~~~ϻٱժׯڵ޽۷ڵ׮ԩѢϟșȑƍŊ…………̺Ԥ……ѿծ׮ڵ۷߾޽۷ڵ׮ԨӪɓȑƌƌƌС߻ƌƌȑľԫׯڵ۷޽޽۷۶׮ժխխ̟͚̘ʔʔʔ̘С͛ʔʔ̘׮۶۷޽޽۷ڵׯ׮ӧѢѢϟ͚͚͚͚͚СС͚͚͚ϟذڵ۷޽޽۷ڵذ׮ԩԩӦѢѢѢѢѢѢѢѢѢѢӦԩԩ׮ذڵ۷޽##''zDNVy!#??-./012Sky temp## ЄD"3#??A@B 5789:<=?@A")BMvv( Xxwwww JZz!#??BA-./01)BMvv( X @r(z#??B-./01F88::; @4HIJK")jBMv6( @ LV#?? `A-./01)kBMvv( P  vW"z#??B`A-./01QSky tempL.\Physical Phenomena\Sky Temperature\calculate cloudiness factor\Type69b.tmfS3o42qsFictive sky temperatureSNsimplereal+-Inf+Inf00C Temperature[ ; ]PCFictive sky temperatureqsCloudiness factor of the skySNsimplereal+010000- dimensionless[ ; ]P-Cloudiness factor of the skyo42qsmode for cloudiness factorSNIn this mode, the cloudiness factor is calculated using a correlation that depends on the ratio of diffuse to global radiation.simpleinteger+0000- Dimensionless[ ; ]U-mode for cloudiness factorqsheight over sea levelSNsimplereal+0+Inf00mLength[ ; ]Umheight over sea levelo42EE2qsAmbient temperatureSNsimplereal+-Inf+Inf00C Temperature[ ; ]3f>(%+e=8V%V3#??0:0:!V! V3 "^sDew point temperature.SN+The dew point temperature of the moist air.simplereal+-Inf+Inf00C Temperature[ ; ]YbCDew point temperature.s+Dew point temperature at ambient conditionsSNsimplereal+-Inf+Inf200C Temperature[ ; ]3bC+Dew point temperature at ambient conditions]X\CAmbient temperatureqdq2qs#Diffuse radiation on the horizontalSNsimplereal+0+Inf00 kJ/hr.m^2Flux[ ; ]3& kJ/hr.m^2#Diffuse radiation on the horizontal. kJ/hr.m^2 Beam radiation on the horizontal%h kJ/hr.m^2#sky diffuse radiation on horizontalsInput6string-Inf+Inf0anyany[;]u$anyunamed0stotal radiation on horizontalSN2Twelfth value read from data file (if PAR 2 > 11).simplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ]j kJ/hr.m^2total radiation on horizontalsInput4string-Inf+Inf0anyany[;]ujanyunamedssolar azimuth angleSN3Eleventh value read from data file (if PAR 2 > 10).simplereal+-360+36000degreesDirection (Angle)[ ; ]mdegreessolar azimuth anglesInput2string-Inf+Inf0anyany[;]umanyunamedtdegreessolar zenith angleqnqkq/q%qs0ground reflected diffuse radiation on horizontalSN4Fifteenth value read from data file (if PAR 2 > 14).simplereal+-Inf+Inf00 kJ/hr.m^2Flux[ ; ] kJ/hr.m^20ground reflected diffuse radiation on horizontalq"qsslope of horizontal surfaceSN6Seventeenth value read from data file (if PAR 2 > 16).simplereal+-Inf+Inf00degreesDirection (Angle)[ ; ]degreesslope of horizontal surfaceqanyrelative humiditysPercent relative humiditySN/The percent relative humidity of the moist air.simplereal+0.0100.060.050- dimensionless[ ; ]v-Percent relative humidityxCDry bulb temp.qzqsPressureSNGTotal system pressure, i.e. atmospheric pressure for ambient conditionssimplereal+0+Inf11atmPressure[ ; ]vatmPressureYoZ2qsPsychrometrics modeSNThis mode indicates to the general psychrometrics routine that thedry bulb temperature and the percent realtive humidity will be used tocalculate the remaining moist air properties.simpleinteger+2222- dimensionless[ ; ]~-Psychrometrics modeqs Wet bulb modeSNLShould the wet bulb temperature be calculated as an output if it is not supplied as one of the inputs? 0 ---> Do not calculate the wet bulb temperature 1 ---> Calculate the wet bulb temperatureIf the wet bulb temperature is not required as an output, this parameter should be set to zero to reduce the required computational effort.simpleinteger+0111- dimensionless[ ; ]~- Wet bulb modeqs Error modeSNThe error mode indicates the error handling procedure to the generalpsychrometrics routine: 1 ---> Only one warning condition will be printed throughout the simulation 2 ---> Warnings will be printed every timestep that warning conditions occursimpleinteger+1221- dimensionless[ ; ]~- Error modeoZ2!K2 qsHumidity ratioSNHThe absolute humidity ratio of the moist air (kg's H2O / kg of dry air).simplereal+-Inf+Inf00- dimensionless[ ; ]Y-Humidity ratioqsWet bulb temperatureSN*The wet bulb temperature of the moist air.simplereal+-Inf+Inf00C Temperature[ ; ]YCWet bulb temperatureqsEnthalpySNThe enthalpy of the moist air.simplereal+-Inf+Inf00kJ/kgSpecific Energy[ ; ]YkJ/kgEnthalpyqsDensity of mixtureSN%The density of the air-water mixture.simplereal+-Inf+Inf00kg/m^3Density[ ; ]Ykg/m^3Density of mixtureqsDensity of dry airSN The density of the dry air only.simplereal+-Inf+Inf00kg/m^3Density[ ; ]Ykg/m^3Density of dry airqsPercent relative humidity SN/The percent relative humidity of the moist air.simplereal+-Inf+Inf00- dimensionless[ ; ]YPs 2- RELHUMAMBRELATIVE AMBIENT HUMIDITYreal-Inf+Inf00%any[;]%unamed-Percent relative humidity qXqcqsStatusSNA warning flag indicating improper conditions input to this unit. 0 ---> No warning 1 ---> A pressure greater than 5 atmospheres was specified 2 ---> The given enthalpy is less than that possible for the given humidity ratio 3 ---> A humidity ratio less than zero was specified 4 ---> A wet bulb temperature was supplied that is greater than the dry bulb temperature 5 ---> A dew point temperature was supplied that is greater than the dry bulb temperature 6 ---> A wet bulb temperature lower than that for dry air has been specified 7 ---> A relative humidity less than 0 percent has been specified 8 ---> A relative humidity greater than 100 percent has been specified 9 ---> A humidity ratio has been specified that is greater than the humidity ratio for saturated air at the given temperature10 ---> An enthalpy has been specified that is greater than the enthalpy for saturated air at the given temperature11 ---> An enthalpy has been specified that is less than the enthalpy for dry air at the given temperature12 ---> Correlation out of range - check the input values13 ---> Correlation out of range - check the input valuessimpleinteger+-Inf+Inf00- dimensionless[ ; ]Y-Status]OWCDry bulb temperatures 4- TSGRDGROUND TEMPERATUREreal-Inf+Inf00C Temperature[;]WCunamedOXNCunamedqqs 3- TSKYFIKTIVE SKY TEMPERATUREreal-Inf+Inf00C Temperature[;]Cunamedqqs 5- AZENSOLAR ZENITH ANGLEreal-Inf+Inf00degreesDirection (Angle)[;]degreesunamedqs 6- AAZMSOLAR AZIMUTH ANGLEreal-Inf+Inf00degreesDirection (Angle)[;]sAAZMstring-Inf+Infanyany[;]anyunameddegreesunamedqs 7- IT_N_180_90+INCIDENT RADIATION FOR ORIENTATION N_180_90real-Inf+Inf00 kJ/hr.m^2Flux[;]s IT_N_180_90string-Inf+Infanyany[;]anyunamed kJ/hr.m^2unamedqs 8- IT_S_0_90)INCIDENT RADIATION FOR ORIENTATION S_0_90real-Inf+Inf00 kJ/hr.m^2Flux[;]s IT_S_0_90string-Inf+Infanyany[;]anyunamed kJ/hr.m^2unamedqs 9- IT_E_270_90+INCIDENT RADIATION FOR ORIENTATION E_270_90real-Inf+Inf00 kJ/hr.m^2Flux[;]s IT_E_270_90string-Inf+Infanyany[;]anyunamed kJ/hr.m^2unamedqs 10- IT_W_90_90*INCIDENT RADIATION FOR ORIENTATION W_90_90real-Inf+Inf00 kJ/hr.m^2Flux[;]s IT_W_90_90string-Inf+Infanyany[;]anyunamed kJ/hr.m^2unamedqs 11- IT_H_0_0(INCIDENT RADIATION FOR ORIENTATION H_0_0real-Inf+Inf00 kJ/hr.m^2Flux[;]sIT_H_0_0string-Inf+Infanyany[;]!! "~I{FL n#?? "sLower input valueSNLower input temperature: The temperature difference that will be compared to the dead bands is Th (Input 1) minus Tl (this input). Refer to the abstract for more details.simplereal+-Inf+Inf10.00anyany[ ; ]o (FF (FF (-- (2-2- ((F-F- 22 ,2"F-C*I0! "FCI! "!! "!! "P-  S?#??D@D%& ^Node8()C:\Trnsys17\Studio\Proformas\Controllers\Differential Controller w_ Hysteresis\generic\Solver 0 (Successive Substitution) Control Strategy\Type2d.bmpBM6(((#.#.420*'$)&#)&#(%"(%"(%"($!($!($ '$ '# '#'#'#&"&"&"&!&!&!%!% % % % $$$$&!2/,+(%ƪŨħ{wtsmjie_\[U}R|QyMtGrDqCn?k:j9g5a0& )'$˲ǬveU]OB~}e|xuZnkjf`]\V~S}RzNuHsErDo@l;k:g5$)&$̳rbq}jV|ycNtnkjf`]\V~S}RzNuHsErDo@l;j9$)'$͵ufXɮxlZE:/{gS{ePB6*v`Jnkjf`]\V~S}RzNuHsErDo@k:$)'$ϸh\P̳xf-'!m[pw}iTdjtnkjf`]\V~S}RzNuHsErDn?$*'%й"+% pn]4,%E:0}iU 2) C6+utnkjf`]\V~S}RzNuHsEqC% *(%ҼѺйɱ̳Ū|{vxutnkjf`]\V~S}RzNuHrD% *(&Կtspnn|ir`dUGdUGbSCaRBaRA`O>_M<^L;^L:\J7\H6[H5pR`]\V~S}RzNtG% *(&wW`]\V~S}RyM% *(&ıMF> fKf`]\V~S|Q&!*)'ǵŲӽѺйpɮǫƩŨ¤|xu fLjf`]\V}R&!*)'ʹȶŲӽѺs ̳ɮǫƩŨ¤yol u]F`_e`]\U&!+)(˺˺ȶŲӽm`UȰ̳ɮǫƩŨ¤wcP*!jf`][&"+)(ο̻˺ȶŲ#paʹ̳ɮǫƩŨkPkjf`\&"+*(̻˺ȶŲɲʹ̳ɮǫƩŨweR+#tnkjf_&"+*(̻˺ȶ2.)rcζʹ̳ɮǫƩpXutnkje&",*)̻˵ζʹ̳ɮǫƩygV |xutnki'#,*)3/+rdйζʹ̳ɮǫ¥eTD|xutnj'#,+*ɺǸwİѺйζʹ̳ɮǫ u_|xutm'#,+*ŲӽѺйζʹ̳ɮ xd¤|xus'# ,+*ğoWt($ ,+*nWw($ ,,+{zxtspzii\OfXKeWHdUGdUGbSCaRBu{($!-,,̻˺ȶŲӽѺйζƮɮèŨ($!-,,̻˺ȶŲӽɳ5/)%!vetA8/ç,&^PA(%"-,,̻˺ȶŲviйxA90vfV (%"--,̻˺ȶŲ]TJѺDZw1+%l\Nħ(%".--̻˺ȶŲj^R|xiZ~m]Ũ)&#..-̻˺ȶŲrWMCʱuƪ)&#///ο˺ʹǵıԿҼйϸ͵̳˲*(%777///..------,-,,-,,-,+,,+,+*,+*,+*,+),*)+*)+*(+)(+)(+)'*)'*)'*(&*(&*(&*'%)'%)'$)'$)&$)'$+(&542ż((((wF-#??-./012Lights &X .N?#??ADB 5789:<=?@A")BMvv( Xxwwww tG"Q-#??$BA-./01)BMvv( X `[GQ#??$B-./01F55::7; S?HIJK")jBMv6( @ `#?? pA-./01)kBMvv( P  BaGQ#??$BpA-./01PControlsLightsz.\Controllers\Differential Controller w_ Hysteresis\generic\Solver 0 (Successive Substitution) Control Strategy\Type2d.tmfSo2qsOutput control functionSNQOutput control function: The output control function may be ON (=1) or OFF (=0).simplereal+0.01.000- Dimensionless[ ; ]~! "cs`pfv ts F*#??F-]-]60F* "sInput1string-Inf+Inf0anyany[;]ov ( ( ( ( ((  ! "\ c#??@ D.D%& ^Node3()*C:\Trnsys17\Studio\Exe\..\Lib\NEWEQUAT.bmpBM6(((xq|wwwépǯxq|wwwwwwĩÅsɱ£ÌvĊtؓ}xfnapgxr|zzz¦ƈvʲäƏyȊx؏xŅoŌw㣉ۖzgpbwnɊx°˳ĥКȯ£褉訌qɉẇrޞ՛ѕ~򪏭̌zIJ̵Ŧգ޽ϴ⩎ΙæӔ|ۡsωtˊtçΎ{ƴͶƧΤԺϥѤܽפқĬۙ¤ѐ}ȷηǨƧ豕֠Ŧ賙׳ɯ٧ᬔн޾輤ﳗԒʺϸȨҞmÃoΑyƧŦءએŦŦѤ©͠ĥ֔̽кɩʕݛﵘuoÃo᥋ǧ᫑͘åƨĤؖξѺʪӦ׶Ͳ᫑̗є}汖pʇsȊuȩ¤ۘһ˫綜ɸ޺ХٻդΚ㣊ﶚݚӼ̭̬嵛֪崘ˬޯѽӧⰘѿ޾ʲ粘ߜԽͭᄀno䯔̭̭緝٫ǩ̭ЦպϥɫĤ⟋տήđ|㡋ˍvǩҡoqίūǩϱœ¨㡍տϯТӺͮ䰖Ƒ~ϔ~ŭNxMqnгġ壏аԨҺ縞Ф׻Զ֦fskõšé祒ѱɪΧ¨ϣаԪծꊰƣĩ騕ҲҲҲɪҲҳ̮ҩծ齡ѵqzĸ̨¦쫗ӳӳӳӴӴӴԵԵԶԶշ˷»׻ͫԴ껝ҟפգգ֢ئ嵙ƩԷֹ׺ػؽͭӴӘ|œ㨉נ֢գ帞ھѲçǨsux{}㩉鼢Դ¤Ҳ؍i^`bfhjmqtwz}՝ַ׸כ|SNOQTVWY]_adԗzٺظعۢ֒pՌi։dوa^WPMMNY٤ĤŵܼۻۻۻڻڻԵŧ綘ܨ՟ל~טzۥñдı۹ɲż־պԷնԴڹ§˭ԳȯĽ¸ĺ((((*#??-./012 Shading+Light22 c#??ADB 5789:<=?@A")BMvv( Xxwwww (Y#??$BA-./01)BMvv( X ? #??$B-./01F33::ŹW uHIJK")jBMv6( @ {/w#?? pA-./01)kBMvv( P  =-#??$BpA-./01 Shading+LightnullSodqsBRIGHTstring-Inf+Infanyany[;] L"U#??XXU "  s 29- BRIGHTINPUTreal-Inf+Inf00anyany[;] anyunamedanyunamed od]od  trnEquationInput1 ! 27trnEquationLexemeInput1  !   27dq anyunamed.+1u[#??FXX3[ "sInput control functionSNInput control function: The input control function is used to promote controller stability by the use of hysteresis. The control decision will be based on the dead band conditions and controller state at the previous timestep (this input). Refer to the abstract for more details on control theory. In most applications, the output control signal from this component is hooked up to this input.simplereal+0100- Dimensionless[ ; ]-Input control function-Output control functiono2qsNo. of oscillationsSN|The number of control oscillations allowed in one timestep before the controller is ""Stuck"" so that the calculations can be solved. This parameter should be set to an odd number so that short-term results are not biased. Refer to section 4.4 for more details on control theory in simulations. Note: This controller momde REQUIRES the use of SOLVER 0 (Successive substitution)simpleinteger+1+Inf55- Dimensionless[ ; ]#-No. of oscillationsqsHigh limit cut-outSN+High limit cut-out: The controller will set the controller to the OFF position, regardless of the dead bands, if the temperature being monitored (Input 3) exceeds the high limit cut-out. The controller will remain OFF until the monitored temperature falls below the high limit cut-out temperature.simplereal+-Inf+Inf100.040000anyany[ ; ]#anyHigh limit cut-outo2`NOTE: This controller can only be used with Solver 0 (Successive substitution) 2qsUpper input valueSNUpper input temperature: The temperature difference that will be compared to the dead bands is Th (this input) minus Tl (Input 2). Refer to the abstract for more details.simplereal+-Inf+Inf20.00anyany[ ; ]anyUpper input valueqqsMonitoring valueSNTemperature to monitor for high-limit cut-out checking. The controller signal will be set to OFF if this Input exceeds the high limit cut-out temperature (Parameter 4) The controller will remain OFF until this input falls below the high limit cut-out.simplereal+-Inf+Inf20.00anyany[ ; ]anyMonitoring valueq"qsUpper dead bandSNnThe upper dead band temperature difference is used in the following way in the controller: The controller is ON if it was previously OFF and Th (Input 1) minus Tl (Input 2) is greater than the upper dead band. Otherwise the controller is OFF. The controller is ON if it was previously ON and Th (Input 1) minus Tl (Input 2) is greater than the lower dead band. Otherwise the controller is OFF. Upper dead band should be greater than the lower dead band in most applications. Refer to section 4.4 of Volume 1 of the TRNSYS documentation set for help in choosing optimal and stable values of the controller dead bands.simplereal+-Inf+Inf10.00anyany[ ; ]"%! ")&,3(("" N <#??""996[< "2s Eoth_L_offstring-Inf+Infanyany[;]ov ( ( ("" ("" 6  5B!,4#??CC%& ^Node7()*C:\Trnsys17\Studio\Exe\..\Lib\NEWEQUAT.bmpBM6(((xq|wwwépǯxq|wwwwwwĩÅsɱ£ÌvĊtؓ}xfnapgxr|zzz¦ƈvʲäƏyȊx؏xŅoŌw㣉ۖzgpbwnɊx°˳ĥКȯ£褉訌qɉẇrޞ՛ѕ~򪏭̌zIJ̵Ŧգ޽ϴ⩎ΙæӔ|ۡsωtˊtçΎ{ƴͶƧΤԺϥѤܽפқĬۙ¤ѐ}ȷηǨƧ豕֠Ŧ賙׳ɯ٧ᬔн޾輤ﳗԒʺϸȨҞmÃoΑyƧŦءએŦŦѤ©͠ĥ֔̽кɩʕݛﵘuoÃo᥋ǧ᫑͘åƨĤؖξѺʪӦ׶Ͳ᫑̗є}汖pʇsȊuȩ¤ۘһ˫綜ɸ޺ХٻդΚ㣊ﶚݚӼ̭̬嵛֪崘ˬޯѽӧⰘѿ޾ʲ粘ߜԽͭᄀno䯔̭̭緝٫ǩ̭ЦպϥɫĤ⟋տήđ|㡋ˍvǩҡoqίūǩϱœ¨㡍տϯТӺͮ䰖Ƒ~ϔ~ŭNxMqnгġ壏аԨҺ縞Ф׻Զ֦fskõšé祒ѱɪΧ¨ϣаԪծꊰƣĩ騕ҲҲҲɪҲҳ̮ҩծ齡ѵqzĸ̨¦쫗ӳӳӳӴӴӴԵԵԶԶշ˷»׻ͫԴ껝ҟפգգ֢ئ嵙ƩԷֹ׺ػؽͭӴӘ|œ㨉נ֢գ帞ھѲçǨsux{}㩉鼢Դ¤Ҳ؍i^`bfhjmqtwz}՝ַ׸כ|SNOQTVWY]_adԗzٺظعۢ֒pՌi։dوa^WPMMNY٤ĤŵܼۻۻۻڻڻԵŧ綘ܨ՟ל~טzۥñдı۹ɲż־պԷնԴڹ§˭ԳȯĽ¸ĺ(((("#??-./012Light Thresholds99 7+#4#??ADB 5789:<=?@A")BMvv( Xxwwww "#??$BA-./01)BMvv( X Vf #??$B-./01F33::@R4HIJK")jBMv6( @ U3 #?? pA-./01)kBMvv( P  ( #??$BpA-./01Light ThresholdsnullSo<db;o<do<ds Toth_L_onstring-Inf+Infanyany[;];1anyunamed<-3.6*0-3.6*0:<-3.6*0-3.6*0dqWq:9anyunamedsLower dead bandSNvThe lower dead band temperature difference is used in the folllowing way in the controller: The controller is ON if it was previously ON and Th (Input 1) minus T (Input 2) is greater than the lower dead band. Otherwise the controller is OFF. The controller is ON if it was previously OFF and Th (Input 1) minus Tl (Input 2) is greater than the upper dead band. Otherwise the controller is OFF. Refer to section 4.4 of Volume 1 of the TRNSYS documentation set for help in determining optimum and stable values of the controller dead bands. In most applications, the upper dead band should be greater than the lower dead band.simplereal+-Inf+Inf2.00anyany[ ; ]9anyLower dead band1W0anyUpper dead bandqdanyLower input valueanyunamed kJ/hr.m^2unamedqs 12- IB_N_180_900INCIDENT BEAM RADIATION FOR ORIENTATION N_180_90real-Inf+Inf00 kJ/hr.m^2Flux[;]s IB_N_180_90string-Inf+Infanyany[;]hanyunamedg kJ/hr.m^2unamedqs 13- IB_S_0_90.INCIDENT BEAM RADIATION FOR ORIENTATION S_0_90real-Inf+Inf00 kJ/hr.m^2Flux[;]s IB_S_0_90string-Inf+Infanyany[;]lanyunamedk kJ/hr.m^2unamedqs 14- IB_E_270_900INCIDENT BEAM RADIATION FOR ORIENTATION E_270_90real-Inf+Inf00 kJ/hr.m^2Flux[;]s IB_E_270_90string-Inf+Infanyany[;]panyunamedo kJ/hr.m^2unamedqs 15- IB_W_90_90/INCIDENT BEAM RADIATION FOR ORIENTATION W_90_90real-Inf+Inf00 kJ/hr.m^2Flux[;]s IB_W_90_90string-Inf+Infanyany[;]tanyunameds kJ/hr.m^2unamedqs 16- IB_H_0_0-INCIDENT BEAM RADIATION FOR ORIENTATION H_0_0real-Inf+Inf00 kJ/hr.m^2Flux[;]sIB_H_0_0string-Inf+Infanyany[;]xanyunamedw kJ/hr.m^2unamedqs 17- AI_N_180_90+ANGLE OF INCIDENCE FOR ORIENTATION N_180_90real-Inf+Inf00degreesDirection (Angle)[;]s AI_N_180_90string-Inf+Infanyany[;]|anyunamed{degreesunamedqs 18- AI_S_0_90)ANGLE OF INCIDENCE FOR ORIENTATION S_0_90real-Inf+Inf00degreesDirection (Angle)[;]s AI_S_0_90string-Inf+Infanyany[;]anyunameddegreesunamedqs 19- AI_E_270_90+ANGLE OF INCIDENCE FOR ORIENTATION E_270_90real-Inf+Inf00degreesDirection (Angle)[;]s AI_E_270_90string-Inf+Infanyany[;]anyunameddegreesunamedqs 20- AI_W_90_90*ANGLE OF INCIDENCE FOR ORIENTATION W_90_90real-Inf+Inf00degreesDirection (Angle)[;]s AI_W_90_90string-Inf+Infanyany[;]anyunameddegreesunamedqqs 22- GRDREF3GROUND REFLECTION FOR SKY DIFFUSE RADIATION SHADINGreal-Inf+Inf00.2- Dimensionless[;]-unamedqs 23- CNAT_1INPUTreal-Inf+Inf00anyany[;]anyunamedqs 24- T_COOL_ONINPUTreal-Inf+Inf00anyany[;]anyunamedqs 25- MS_N_180_90INPUTreal-Inf+Inf00anyany[;]anyunamedqs 26- MS_S_0_90INPUTreal-Inf+Inf00anyany[;]anyunamedqs 27- MS_E_270_90INPUTreal-Inf+Inf00anyany[;]anyunamedqs 28- MS_W_90_90INPUTreal-Inf+Inf00anyany[;]anyunamedqdegreesunamed|xtplhanyunamedqqqyqsID_H_0_0string-Inf+Infanyany[;]anyunamedqqqiq}qqmqqqqqqquqowd00owdt}h}wInput17Input17iwInput9 * LT(AI_N_180_90,90) Input9 *  LT (  AI_N_180_90 ,90)mwInput12Input12w Max(Input4,0)Max(Input4 , 0 ) qwInput15Input15uwInput18Input18yw Max(Input5,0)Max(Input5 , 0 ) }wInput10Input10wInput13Input13wInput16Input16wInput1Input1wInput19Input19wInput6Input6wInput2 - Input3Input2 -  Input3 wInput8Input8wInput7Input7wInput11Input11wInput14Input14drqoqsInput3string-Inf+Inf0anyany[;]uIMFJLP! 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