Guide for Module Developers — EnergyPlus 8.6

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Module Example[LINK]

This example can be used as a template for new HVAC component modules. In particular, the commenting structure in the module and within the subroutines should be followed closely. Of course, there is no perfect example module – this one is particularly simple. Some others that might be examined are in files Humidifiers.f90, HVACHeatingCoils.f90 and PlantChillers.f90. Templates are also available as separate files.

In particular, the module template with routines contains structure and information pertinent to module development.

Note that in the following module, the “Data IPShortcuts” is not used – rather those variables are allocated within this module – likely because another module calls this one during input.

Module Fans

! Module containing the fan simulation routines

! MODULE INFORMATION:

! AUTHOR Richard J. Liesen

! DATE WRITTEN April 1998

! MODIFIED Shirey, May 2001

! RE-ENGINEERED na

! PURPOSE OF THIS MODULE:

! To encapsulate the data and algorithms required to

! manage the Fan System Component

! REFERENCES: none

! OTHER NOTES: none

! USE STATEMENTS:

! Use statements for data only modules

USE DataPrecisionGlobals

USE DataLoopNode

USE DataHVACGlobals, ONLY: TurnFansOn, TurnFansOff, Main, Cooling, Heating, Other, &

OnOffFanPartLoadFraction, SmallAirVolFlow, UnbalExhMassFlow, NightVentOn, cFanTypes, &

FanType_SimpleConstVolume, FanType_SimpleVAV, FanType_SimpleOnOff, FanType_ZoneExhaust

USE DataGlobals, ONLY: SetupOutputVariable, BeginEnvrnFlag, BeginDayFlag, MaxNameLength, &

ShowWarningError, ShowFatalError, ShowSevereError, HourofDay, SysSizingCalc, CurrentTime, &

OutputFileDebug, ShowContinueError, ShowRecurringWarningErrorAtEnd, WarmupFlag, &

ShowContinueErrorTimeStamp

Use DataEnvironment, ONLY: StdBaroPress, DayofMonth, Month, StdRhoAir

USE Psychrometrics, ONLY:PsyRhoAirFnPbTdbW, PsyTdbFnHW, PsyCpAirFnWTdb

! Use statements for access to subroutines in other modules

USE ScheduleManager

IMPLICIT NONE ! Enforce explicit typing of all variables

PRIVATE ! Everything private unless explicitly made public

!MODULE PARAMETER DEFINITIONS

!na

! DERIVED TYPE DEFINITIONS

TYPE FanEquipConditions

CHARACTER(len = MaxNameLength) :: FanName = ‘’ ! Name of the fan

CHARACTER(len = MaxNameLength) :: FanType = ‘’ ! Type of Fan ie. Simple, Vane axial, Centrifugal, etc.

CHARACTER(len = MaxNameLength) :: Schedule = ‘’ ! Fan Operation Schedule

INTEGER :: FanType_Num = 0 ! DataHVACGlobals fan type

Integer :: SchedPtr = 0 ! Pointer to the correct schedule

REAL(r64) :: InletAirMassFlowRate = 0.0 !MassFlow through the Fan being Simulated [kg/Sec]

REAL(r64) :: OutletAirMassFlowRate = 0.0

REAL(r64) :: MaxAirFlowRate = 0.0 !Max Specified Volume Flow Rate of Fan [m3/sec]

REAL(r64) :: MinAirFlowRate = 0.0 !Min Specified Volume Flow Rate of Fan [m3/sec]

REAL(r64) :: MaxAirMassFlowRate = 0.0 ! Max flow rate of fan in kg/sec

REAL(r64) :: MinAirMassFlowRate = 0.0 ! Min flow rate of fan in kg/sec

REAL(r64) :: InletAirTemp = 0.0

REAL(r64) :: OutletAirTemp = 0.0

REAL(r64) :: InletAirHumRat = 0.0

REAL(r64) :: OutletAirHumRat = 0.0

REAL(r64) :: InletAirEnthalpy = 0.0

REAL(r64) :: OutletAirEnthalpy = 0.0

REAL(r64) :: FanPower = 0.0 !Power of the Fan being Simulated [kW]

REAL(r64) :: FanEnergy = 0.0 !Fan energy in [kJ]

REAL(r64) :: FanRuntimeFraction = 0.0 !Fraction of the timestep that the fan operates

REAL(r64) :: DeltaTemp = 0.0 !Temp Rise across the Fan [C]

REAL(r64) :: DeltaPress = 0.0 !Delta Pressure Across the Fan [N/m2]

REAL(r64) :: FanEff = 0.0 !Fan total efficiency; motor and mechanical

REAL(r64) :: MotEff = 0.0 !Fan motor efficiency

REAL(r64) :: MotInAirFrac = 0.0 !Fraction of motor heat entering air stream

REAL(r64), Dimension(5):: FanCoeff = 0.0 !Fan Part Load Coefficients to match fan type

! Mass Flow Rate Control Variables

REAL(r64) :: MassFlowRateMaxAvail = 0.0

REAL(r64) :: MassFlowRateMinAvail = 0.0

REAL(r64) :: RhoAirStdInit = 0.0

INTEGER :: InletNodeNum = 0

INTEGER :: OutletNodeNum = 0

INTEGER :: NVPerfNum = 0

INTEGER :: FanPowerRatAtSpeedRatCurveIndex = 0

INTEGER :: FanEffRatioCurveIndex = 0

CHARACTER(len = MaxNameLength) :: EndUseSubcategoryName = ‘’

LOGICAL :: OneTimePowerRatioCheck = .TRUE. ! one time flag used for error message

LOGICAL :: OneTimeEffRatioCheck = .TRUE. ! one time flag used for error message

END TYPE FanEquipConditions

TYPE NightVentPerfData

CHARACTER(len = MaxNameLength) :: FanName = ‘’ ! Name of the fan that will use this data

REAL(r64) :: FanEff = 0.0 !Fan total efficiency; motor and mechanical

REAL(r64) :: DeltaPress = 0.0 !Delta Pressure Across the Fan [N/m2]

REAL(r64) :: MaxAirFlowRate = 0.0 !Max Specified Volume Flow Rate of Fan [m3/s]

REAL(r64) :: MaxAirMassFlowRate = 0.0 ! Max flow rate of fan in kg/sec

REAL(r64) :: MotEff = 0.0 !Fan motor efficiency

REAL(r64) :: MotInAirFrac = 0.0 !Fraction of motor heat entering air stream

END TYPE NightVentPerfData

!MODULE VARIABLE DECLARATIONS:

INTEGER :: NumFans = 0 ! The Number of Fans found in the Input

INTEGER :: NumNightVentPerf = 0 ! number of FAN:NIGHT VENT PERFORMANCE objects found in the input

TYPE (FanEquipConditions), ALLOCATABLE, DIMENSION(:) :: Fan

TYPE (NightVentPerfData), ALLOCATABLE, DIMENSION(:) :: NightVentPerf

LOGICAL :: GetFanInputFlag = .True. ! Flag set to make sure you get input once

! Subroutine Specifications for the Module

! Driver/Manager Routines

Public SimulateFanComponents

! Get Input routines for module

PRIVATE GetFanInput

! Initialization routines for module

PRIVATE InitFan

PRIVATE SizeFan

! Algorithms for the module

Private SimSimpleFan

PRIVATE SimVariableVolumeFan

PRIVATE SimZoneExhaustFan

! Update routine to check convergence and update nodes

Private UpdateFan

! Reporting routines for module

Private ReportFan

CONTAINS

! MODULE SUBROUTINES:

!*************************************************************************

SUBROUTINE SimulateFanComponents(CompName,FirstHVACIteration)

! SUBROUTINE INFORMATION:

! AUTHOR Richard Liesen

! DATE WRITTEN February 1998

! MODIFIED na

! RE-ENGINEERED na

! PURPOSE OF THIS SUBROUTINE:

! This subroutine manages Fan component simulation.

! METHODOLOGY EMPLOYED:

! na

! REFERENCES:

! na

! USE STATEMENTS:

USE InputProcessor, ONLY: FindItemInList

IMPLICIT NONE ! Enforce explicit typing of all variables in this routine

! SUBROUTINE ARGUMENT DEFINITIONS:

CHARACTER(len = *), INTENT(IN) :: CompName

LOGICAL, INTENT (IN):: FirstHVACIteration

! SUBROUTINE PARAMETER DEFINITIONS:

! na

! INTERFACE BLOCK SPECIFICATIONS

! DERIVED TYPE DEFINITIONS

! na

! SUBROUTINE LOCAL VARIABLE DECLARATIONS:

INTEGER :: FanNum ! current fan number

LOGICAL,SAVE :: GetInputFlag = .True. ! Flag set to make sure you get input once

! FLOW:

! Obtains and Allocates fan related parameters from input file

IF (GetInputFlag) THEN !First time subroutine has been entered

CALL GetFanInput

GetInputFlag = .false.

End If

! Find the correct FanNumber with the AirLoop & CompNum from AirLoop Derived Type

!FanNum = AirLoopEquip(AirLoopNum)%ComponentOfTypeNum(CompNum)

! Determine which Fan given the Fan Name

FanNum = FindItemInList(CompName,Fan%FanName,NumFans)

IF (FanNum = = 0) THEN

CALL ShowFatalError(‘Fan not found =’//TRIM(CompName))

ENDIF

! With the correct FanNum Initialize

CALL InitFan(FanNum,FirstHVACIteration) ! Initialize all fan related parameters

! Calculate the Correct Fan Model with the current FanNum

IF (Fan(FanNum)%FanType_Num = = FanType_SimpleConstVolume) THEN

Call SimSimpleFan(FanNum)

Else IF (Fan(FanNum)%FanType_Num = = FanType_SimpleVAV) THEN

Call SimVariableVolumeFan(FanNum)

Else If (Fan(FanNum)%FanType_Num = = FanType_SimpleOnOff) THEN

Call SimOnOffFan(FanNum)

Else If (Fan(FanNum)%FanType_Num = = FanType_ZoneExhaust) THEN

Call SimZoneExhaustFan(FanNum)

End If

! Update the current fan to the outlet nodes

Call UpdateFan(FanNum)

! Report the current fan

Call ReportFan(FanNum)

RETURN

END SUBROUTINE SimulateFanComponents

! Get Input Section of the Module

!******************************************************************************

SUBROUTINE GetFanInput

! SUBROUTINE INFORMATION:

! AUTHOR Richard Liesen

! DATE WRITTEN April 1998

! MODIFIED Shirey, May 2001

! RE-ENGINEERED na

! PURPOSE OF THIS SUBROUTINE:

! Obtains input data for fans and stores it in fan data structures

! METHODOLOGY EMPLOYED:

! Uses “Get” routines to read in data.

! REFERENCES:

! na

! USE STATEMENTS:

USE InputProcessor

USE NodeInputManager, ONLY: GetOnlySingleNode

USE CurveManager, ONLY: GetCurveIndex

USE BranchNodeConnections, ONLY: TestCompSet

! USE DataIPShortCuts

IMPLICIT NONE ! Enforce explicit typing of all variables in this routine

! SUBROUTINE ARGUMENT DEFINITIONS:

! na

! SUBROUTINE PARAMETER DEFINITIONS:

! na

! INTERFACE BLOCK SPECIFICATIONS

! na

! DERIVED TYPE DEFINITIONS

! na

! SUBROUTINE LOCAL VARIABLE DECLARATIONS:

INTEGER :: FanNum ! The fan that you are currently loading input into

INTEGER :: NumSimpFan ! The number of Simple Const Vol Fans

INTEGER :: NumVarVolFan ! The number of Simple Variable Vol Fans

INTEGER :: NumOnOff ! The number of Simple on-off Fans

INTEGER :: NumZoneExhFan

INTEGER :: SimpFanNum

INTEGER :: OnOffFanNum

INTEGER :: VarVolFanNum

INTEGER :: ExhFanNum

INTEGER :: NVPerfNum

LOGICAL :: NVPerfFanFound

INTEGER :: NumAlphas

INTEGER :: NumNums

INTEGER :: IOSTAT

LOGICAL :: ErrorsFound = .false. ! If errors detected in input

LOGICAL :: IsNotOK ! Flag to verify name

LOGICAL :: IsBlank ! Flag for blank name

CHARACTER(len = *), PARAMETER :: RoutineName = ‘GetFanInput:’ ! include trailing blank space

CHARACTER(len = MaxNameLength+40),ALLOCATABLE, DIMENSION(:) :: cAlphaFieldNames

CHARACTER(len = MaxNameLength+40),ALLOCATABLE, DIMENSION(:) :: cNumericFieldNames

LOGICAL, ALLOCATABLE, DIMENSION(:) :: lNumericFieldBlanks

LOGICAL, ALLOCATABLE, DIMENSION(:) :: lAlphaFieldBlanks

CHARACTER(len = MaxNameLength),ALLOCATABLE, DIMENSION(:) :: cAlphaArgs

REAL(r64),ALLOCATABLE, DIMENSION(:) :: rNumericArgs

CHARACTER(len = MaxNameLength) :: cCurrentModuleObject

INTEGER :: NumParams

INTEGER :: MaxAlphas

INTEGER :: MaxNumbers

! Flow

MaxAlphas = 0

MaxNumbers = 0

NumSimpFan = GetNumObjectsFound(‘Fan:ConstantVolume’)

IF (NumSimpFan > 0) THEN

CALL GetObjectDefMaxArgs(‘Fan:ConstantVolume’,NumParams,NumAlphas,NumNums)

MaxAlphas = MAX(MaxAlphas,NumAlphas)

MaxNumbers = MAX(MaxNumbers,NumNums)

ENDIF

NumVarVolFan = GetNumObjectsFound(‘Fan:VariableVolume’)

IF (NumVarVolFan > 0) THEN

CALL GetObjectDefMaxArgs(‘Fan:VariableVolume’,NumParams,NumAlphas,NumNums)

MaxAlphas = MAX(MaxAlphas,NumAlphas)

MaxNumbers = MAX(MaxNumbers,NumNums)

ENDIF

NumOnOff = GetNumObjectsFound(‘Fan:OnOff’)

IF (NumOnOff > 0) THEN

CALL GetObjectDefMaxArgs(‘Fan:OnOff’,NumParams,NumAlphas,NumNums)

MaxAlphas = MAX(MaxAlphas,NumAlphas)

MaxNumbers = MAX(MaxNumbers,NumNums)

ENDIF

NumZoneExhFan = GetNumObjectsFound(‘Fan:ZoneExhaust’)

IF (NumZoneExhFan > 0) THEN

CALL GetObjectDefMaxArgs(‘Fan:ZoneExhaust’,NumParams,NumAlphas,NumNums)

MaxAlphas = MAX(MaxAlphas,NumAlphas)

MaxNumbers = MAX(MaxNumbers,NumNums)

ENDIF

NumNightVentPerf = GetNumObjectsFound(‘FanPerformance:NightVentilation’)

IF (NumNightVentPerf > 0) THEN

CALL GetObjectDefMaxArgs(‘FanPerformance:NightVentilation’,NumParams,NumAlphas,NumNums)

MaxAlphas = MAX(MaxAlphas,NumAlphas)

MaxNumbers = MAX(MaxNumbers,NumNums)

ENDIF

ALLOCATE(cAlphaArgs(MaxAlphas))

cAlphaArgs = ‘’

ALLOCATE(cAlphaFieldNames(MaxAlphas))

cAlphaFieldNames = ‘’

ALLOCATE(lAlphaFieldBlanks(MaxAlphas))

lAlphaFieldBlanks = .false.

ALLOCATE(cNumericFieldNames(MaxNumbers))

cNumericFieldNames = ‘’

ALLOCATE(lNumericFieldBlanks(MaxNumbers))

lNumericFieldBlanks = .false.

ALLOCATE(rNumericArgs(MaxNumbers))

rNumericArgs = 0.0

NumFans = NumSimpFan + NumVarVolFan + NumZoneExhFan+NumOnOff

IF (NumFans > 0) THEN

ALLOCATE(Fan(NumFans))

ENDIF

DO SimpFanNum = 1, NumSimpFan

FanNum = SimpFanNum

cCurrentModuleObject = ‘Fan:ConstantVolume’

CALL GetObjectItem(TRIM(cCurrentModuleObject),SimpFanNum,cAlphaArgs,NumAlphas, &

rNumericArgs,NumNums,IOSTAT, &

NumBlank = lNumericFieldBlanks,AlphaBlank = lAlphaFieldBlanks, &

AlphaFieldNames = cAlphaFieldNames,NumericFieldNames = cNumericFieldNames)

IsNotOK = .false.

IsBlank = .false.

CALL VerifyName(cAlphaArgs(1),Fan%FanName,FanNum-1,IsNotOK,IsBlank,TRIM(cCurrentModuleObject)//‘Name’)

IF (IsNotOK) THEN

ErrorsFound = .true.

IF (IsBlank) cAlphaArgs(1) = ‘xxxxx’

ENDIF

Fan(FanNum)%FanName = cAlphaArgs(1)

Fan(FanNum)%FanType = cCurrentModuleObject

Fan(FanNum)%Schedule = cAlphaArgs(2)

Fan(FanNum)%SchedPtr = GetScheduleIndex(cAlphaArgs(2))

IF (Fan(FanNum)%SchedPtr = = 0) THEN

IF (lAlphaFieldBlanks(2)) THEN

CALL ShowSevereError(RoutineName//TRIM(cCurrentModuleObject)//‘:’//TRIM(cAlphaFieldNames(2))// &

‘is required, missing for’//TRIM(cAlphaFieldNames(1))//‘=’//TRIM(cAlphaArgs(1)))

ELSE

CALL ShowSevereError(RoutineName//TRIM(cCurrentModuleObject)//‘: invalid’//TRIM(cAlphaFieldNames(2))// &

‘entered =’//TRIM(cAlphaArgs(2))// &

‘for’//TRIM(cAlphaFieldNames(1))//‘=’//TRIM(cAlphaArgs(1)))

END IF

ErrorsFound = .true.

END IF

! Fan(FanNum)%Control = ‘CONSTVOLUME’

Fan(FanNum)%FanType_Num = FanType_SimpleConstVolume

Fan(FanNum)%FanEff = rNumericArgs(1)

Fan(FanNum)%DeltaPress = rNumericArgs(2)

Fan(FanNum)%MaxAirFlowRate = rNumericArgs(3)

IF (Fan(FanNum)%MaxAirFlowRate = = 0.0) THEN

CALL ShowWarningError(TRIM(cCurrentModuleObject)//’ = “’//TRIM(Fan(FanNum)%FanName)// &

‘" has specified 0.0 max air flow rate. It will not be used in the simulation.’)

ENDIF

Fan(FanNum)%MotEff = rNumericArgs(4)

Fan(FanNum)%MotInAirFrac = rNumericArgs(5)

Fan(FanNum)%MinAirFlowRate = 0.0

Fan(FanNum)%InletNodeNum = &

GetOnlySingleNode(cAlphaArgs(3),ErrorsFound,TRIM(cCurrentModuleObject),cAlphaArgs(1), &

NodeType_Air,NodeConnectionType_Inlet,1,ObjectIsNotParent)

Fan(FanNum)%OutletNodeNum = &

GetOnlySingleNode(cAlphaArgs(4),ErrorsFound,TRIM(cCurrentModuleObject),cAlphaArgs(1), &

NodeType_Air,NodeConnectionType_Outlet,1,ObjectIsNotParent)

IF (NumAlphas > 4) THEN

Fan(FanNum)%EndUseSubcategoryName = cAlphaArgs(5)

ELSE

Fan(FanNum)%EndUseSubcategoryName = ‘General’

END IF

CALL TestCompSet(TRIM(cCurrentModuleObject),cAlphaArgs(1),cAlphaArgs(3),cAlphaArgs(4),‘Air Nodes’)

END DO ! end Number of Simple FAN Loop

DO VarVolFanNum = 1, NumVarVolFan

FanNum = NumSimpFan + VarVolFanNum

cCurrentModuleObject = ‘Fan:VariableVolume’

CALL GetObjectItem(TRIM(cCurrentModuleObject),VarVolFanNum,cAlphaArgs,NumAlphas, &

rNumericArgs,NumNums,IOSTAT, &

NumBlank = lNumericFieldBlanks,AlphaBlank = lAlphaFieldBlanks, &

AlphaFieldNames = cAlphaFieldNames,NumericFieldNames = cNumericFieldNames)

IsNotOK = .false.

IsBlank = .false.

CALL VerifyName(cAlphaArgs(1),Fan%FanName,FanNum-1,IsNotOK,IsBlank,TRIM(cCurrentModuleObject)//‘Name’)

IF (IsNotOK) THEN

ErrorsFound = .true.

IF (IsBlank) cAlphaArgs(1) = ‘xxxxx’

ENDIF

Fan(FanNum)%FanName = cAlphaArgs(1)

Fan(FanNum)%FanType = cCurrentModuleObject

Fan(FanNum)%Schedule = cAlphaArgs(2)

Fan(FanNum)%SchedPtr = GetScheduleIndex(cAlphaArgs(2))

IF (Fan(FanNum)%SchedPtr = = 0) THEN

IF (lAlphaFieldBlanks(2)) THEN

CALL ShowSevereError(RoutineName//TRIM(cCurrentModuleObject)//‘:’//TRIM(cAlphaFieldNames(2))// &

‘is required, missing for’//TRIM(cAlphaFieldNames(1))//‘=’//TRIM(cAlphaArgs(1)))

ELSE

CALL ShowSevereError(RoutineName//TRIM(cCurrentModuleObject)//‘: invalid’//TRIM(cAlphaFieldNames(2))// &

‘entered =’//TRIM(cAlphaArgs(2))// &

‘for’//TRIM(cAlphaFieldNames(1))//‘=’//TRIM(cAlphaArgs(1)))

END IF

ErrorsFound = .true.

ENDIF

! Fan(FanNum)%Control = ‘VARIABLEVOLUME’

Fan(FanNum)%FanType_Num = FanType_SimpleVAV

Fan(FanNum)%FanEff = rNumericArgs(1)

Fan(FanNum)%DeltaPress = rNumericArgs(2)

Fan(FanNum)%MaxAirFlowRate = rNumericArgs(3)

IF (Fan(FanNum)%MaxAirFlowRate = = 0.0) THEN

CALL ShowWarningError(TRIM(cCurrentModuleObject)//’ = “’//TRIM(Fan(FanNum)%FanName)// &

‘" has specified 0.0 max air flow rate. It will not be used in the simulation.’)

ENDIF

Fan(FanNum)%MinAirFlowRate = rNumericArgs(4)

Fan(FanNum)%MotEff = rNumericArgs(5)

Fan(FanNum)%MotInAirFrac = rNumericArgs(6)

Fan(FanNum)%FanCoeff(1) = rNumericArgs(7)

Fan(FanNum)%FanCoeff(2) = rNumericArgs(8)

Fan(FanNum)%FanCoeff(3) = rNumericArgs(9)

Fan(FanNum)%FanCoeff(4) = rNumericArgs(10)

Fan(FanNum)%FanCoeff(5) = rNumericArgs(11)

IF (Fan(FanNum)%FanCoeff(1) = = 0.0 .and. Fan(FanNum)%FanCoeff(2) = = 0.0 .and. &

Fan(FanNum)%FanCoeff(3) = = 0.0 .and. Fan(FanNum)%FanCoeff(4) = = 0.0 .and. &

Fan(FanNum)%FanCoeff(5) = = 0.0) THEN

CALL ShowWarningError(‘Fan Coefficients are all zero. No Fan power will be reported.’)

CALL ShowContinueError(‘For’//TRIM(cCurrentModuleObject)//‘, Fan =’//TRIM(cAlphaArgs(1)))

ENDIF

Fan(FanNum)%InletNodeNum = &

GetOnlySingleNode(cAlphaArgs(3),ErrorsFound,TRIM(cCurrentModuleObject),cAlphaArgs(1), &

NodeType_Air,NodeConnectionType_Inlet,1,ObjectIsNotParent)

Fan(FanNum)%OutletNodeNum = &

GetOnlySingleNode(cAlphaArgs(4),ErrorsFound,TRIM(cCurrentModuleObject),cAlphaArgs(1), &

NodeType_Air,NodeConnectionType_Outlet,1,ObjectIsNotParent)

IF (NumAlphas > 4) THEN

Fan(FanNum)%EndUseSubcategoryName = cAlphaArgs(5)

ELSE

Fan(FanNum)%EndUseSubcategoryName = ‘General’

END IF

CALL TestCompSet(TRIM(cCurrentModuleObject),cAlphaArgs(1),cAlphaArgs(3),cAlphaArgs(4),‘Air Nodes’)

END DO ! end Number of Variable Volume FAN Loop

DO ExhFanNum = 1, NumZoneExhFan

FanNum = NumSimpFan + NumVarVolFan + ExhFanNum

cCurrentModuleObject = ‘Fan:ZoneExhaust’

CALL GetObjectItem(TRIM(cCurrentModuleObject),ExhFanNum,cAlphaArgs,NumAlphas, &

rNumericArgs,NumNums,IOSTAT, &

NumBlank = lNumericFieldBlanks,AlphaBlank = lAlphaFieldBlanks, &

AlphaFieldNames = cAlphaFieldNames,NumericFieldNames = cNumericFieldNames)

IsNotOK = .false.

IsBlank = .false.

CALL VerifyName(cAlphaArgs(1),Fan%FanName,FanNum-1,IsNotOK,IsBlank,TRIM(cCurrentModuleObject)//‘Name’)

IF (IsNotOK) THEN

ErrorsFound = .true.

IF (IsBlank) cAlphaArgs(1) = ‘xxxxx’

ENDIF

Fan(FanNum)%FanName = cAlphaArgs(1)

Fan(FanNum)%FanType = cCurrentModuleObject

Fan(FanNum)%Schedule = cAlphaArgs(2)

Fan(FanNum)%SchedPtr = GetScheduleIndex(cAlphaArgs(2))

IF (Fan(FanNum)%SchedPtr = = 0) THEN

IF (lAlphaFieldBlanks(2)) THEN

CALL ShowSevereError(RoutineName//TRIM(cCurrentModuleObject)//‘:’//TRIM(cAlphaFieldNames(2))// &

‘is required, missing for’//TRIM(cAlphaFieldNames(1))//‘=’//TRIM(cAlphaArgs(1)))

ELSE

CALL ShowSevereError(RoutineName//TRIM(cCurrentModuleObject)//‘: invalid’//TRIM(cAlphaFieldNames(2))// &

‘entered =’//TRIM(cAlphaArgs(2))// &

‘for’//TRIM(cAlphaFieldNames(1))//‘=’//TRIM(cAlphaArgs(1)))

END IF

ErrorsFound = .true.

ELSE

IF (HasFractionalScheduleValue(Fan(FanNum)%SchedPtr)) THEN

CALL ShowWarningError(TRIM(cCurrentModuleObject)//’ = “’//TRIM(Fan(FanNum)%FanName)// &

‘" has fractional values in Schedule =’//TRIM(cAlphaArgs(2))//‘. Only 0.0 in the schedule value turns the fan off.’)

ENDIF

ENDIF

! Fan(FanNum)%Control = ‘CONSTVOLUME’

Fan(FanNum)%FanType_Num = FanType_ZoneExhaust

Fan(FanNum)%FanEff = rNumericArgs(1)

Fan(FanNum)%DeltaPress = rNumericArgs(2)

Fan(FanNum)%MaxAirFlowRate = rNumericArgs(3)

Fan(FanNum)%MotEff = 1.0

Fan(FanNum)%MotInAirFrac = 1.0

Fan(FanNum)%MinAirFlowRate = 0.0

Fan(FanNum)%RhoAirStdInit = StdRhoAir

Fan(FanNum)%MaxAirMassFlowRate = Fan(FanNum)%MaxAirFlowRate * Fan(FanNum)%RhoAirStdInit

IF (Fan(FanNum)%MaxAirFlowRate = = 0.0) THEN

CALL ShowWarningError(TRIM(cCurrentModuleObject)//’ = “’//TRIM(Fan(FanNum)%FanName)// &

‘" has specified 0.0 max air flow rate. It will not be used in the simulation.’)

ENDIF

Fan(FanNum)%InletNodeNum = &

GetOnlySingleNode(cAlphaArgs(3),ErrorsFound,TRIM(cCurrentModuleObject),cAlphaArgs(1), &

NodeType_Air,NodeConnectionType_Inlet,1,ObjectIsNotParent)

Fan(FanNum)%OutletNodeNum = &

GetOnlySingleNode(cAlphaArgs(4),ErrorsFound,TRIM(cCurrentModuleObject),cAlphaArgs(1), &

NodeType_Air,NodeConnectionType_Outlet,1,ObjectIsNotParent)

IF (NumAlphas > 4) THEN

Fan(FanNum)%EndUseSubcategoryName = cAlphaArgs(5)

ELSE

Fan(FanNum)%EndUseSubcategoryName = ‘General’

END IF

! Component sets not setup yet for zone equipment

! CALL TestCompSet(TRIM(cCurrentModuleObject),cAlphaArgs(1),cAlphaArgs(3),cAlphaArgs(4),‘Air Nodes’)

END DO ! end of Zone Exhaust Fan loop

DO OnOffFanNum = 1, NumOnOff

FanNum = NumSimpFan + NumVarVolFan + NumZoneExhFan + OnOffFanNum

cCurrentModuleObject = ‘Fan:OnOff’

CALL GetObjectItem(TRIM(cCurrentModuleObject),OnOffFanNum,cAlphaArgs,NumAlphas, &

rNumericArgs,NumNums,IOSTAT, &

NumBlank = lNumericFieldBlanks,AlphaBlank = lAlphaFieldBlanks, &

AlphaFieldNames = cAlphaFieldNames,NumericFieldNames = cNumericFieldNames)

IsNotOK = .false.

IsBlank = .false.

CALL VerifyName(cAlphaArgs(1),Fan%FanName,FanNum-1,IsNotOK,IsBlank,TRIM(cCurrentModuleObject)//‘Name’)

IF (IsNotOK) THEN

ErrorsFound = .true.

IF (IsBlank) cAlphaArgs(1) = ‘xxxxx’

ENDIF

Fan(FanNum)%FanName = cAlphaArgs(1)

Fan(FanNum)%FanType = cCurrentModuleObject

Fan(FanNum)%Schedule = cAlphaArgs(2)

Fan(FanNum)%SchedPtr = GetScheduleIndex(cAlphaArgs(2))

IF (Fan(FanNum)%SchedPtr = = 0) THEN

IF (lAlphaFieldBlanks(2)) THEN

CALL ShowSevereError(RoutineName//TRIM(cCurrentModuleObject)//‘:’//TRIM(cAlphaFieldNames(2))// &

‘is required, missing for’//TRIM(cAlphaFieldNames(1))//‘=’//TRIM(cAlphaArgs(1)))

ELSE

CALL ShowSevereError(RoutineName//TRIM(cCurrentModuleObject)//‘: invalid’//TRIM(cAlphaFieldNames(2))// &

‘entered =’//TRIM(cAlphaArgs(2))// &

‘for’//TRIM(cAlphaFieldNames(1))//‘=’//TRIM(cAlphaArgs(1)))

END IF

ErrorsFound = .true.

ENDIF

! Fan(FanNum)%Control = ‘ONOFF’

Fan(FanNum)%FanType_Num = FanType_SimpleOnOff

Fan(FanNum)%FanEff = rNumericArgs(1)

Fan(FanNum)%DeltaPress = rNumericArgs(2)

Fan(FanNum)%MaxAirFlowRate = rNumericArgs(3)

IF (Fan(FanNum)%MaxAirFlowRate = = 0.0) THEN

CALL ShowWarningError(TRIM(cCurrentModuleObject)//’ = “’//TRIM(Fan(FanNum)%FanName)// &

‘" has specified 0.0 max air flow rate. It will not be used in the simulation.’)

ENDIF

! the following two structure variables are set here, as well as in InitFan, for the Heat Pump:Water Heater object

! (Standard Rating procedure may be called before BeginEnvirFlag is set to TRUE, if so MaxAirMassFlowRate = 0)

Fan(FanNum)%RhoAirStdInit = StdRhoAir

Fan(FanNum)%MaxAirMassFlowRate = Fan(FanNum)%MaxAirFlowRate * Fan(FanNum)%RhoAirStdInit

Fan(FanNum)%MotEff = rNumericArgs(4)

Fan(FanNum)%MotInAirFrac = rNumericArgs(5)

Fan(FanNum)%MinAirFlowRate = 0.0

Fan(FanNum)%InletNodeNum = &

GetOnlySingleNode(cAlphaArgs(3),ErrorsFound,TRIM(cCurrentModuleObject),cAlphaArgs(1), &

NodeType_Air,NodeConnectionType_Inlet,1,ObjectIsNotParent)

Fan(FanNum)%OutletNodeNum = &

GetOnlySingleNode(cAlphaArgs(4),ErrorsFound,TRIM(cCurrentModuleObject),cAlphaArgs(1), &

NodeType_Air,NodeConnectionType_Outlet,1,ObjectIsNotParent)

IF (NumAlphas > 4 .AND. .NOT. lAlphaFieldBlanks(5)) THEN

Fan(FanNum)%FanPowerRatAtSpeedRatCurveIndex = GetCurveIndex(cAlphaArgs(5))

END IF

IF (NumAlphas > 5 .AND. .NOT. lAlphaFieldBlanks(6)) THEN

Fan(FanNum)%FanEffRatioCurveIndex = GetCurveIndex(cAlphaArgs(6))

END IF

IF (NumAlphas > 6 .AND. .NOT. lAlphaFieldBlanks(7)) THEN

Fan(FanNum)%EndUseSubcategoryName = cAlphaArgs(7)

ELSE

Fan(FanNum)%EndUseSubcategoryName = ‘General’

END IF

CALL TestCompSet(TRIM(cCurrentModuleObject),cAlphaArgs(1),cAlphaArgs(3),cAlphaArgs(4),‘Air Nodes’)

END DO ! end Number of Simple ON-OFF FAN Loop

cCurrentModuleObject = ‘FanPerformance:NightVentilation’

NumNightVentPerf = GetNumObjectsFound(TRIM(cCurrentModuleObject))

IF (NumNightVentPerf > 0) THEN

ALLOCATE(NightVentPerf(NumNightVentPerf))

NightVentPerf%FanName = ‘’

NightVentPerf%FanEff = 0.0

NightVentPerf%DeltaPress = 0.0

NightVentPerf%MaxAirFlowRate = 0.0

NightVentPerf%MotEff = 0.0

NightVentPerf%MotInAirFrac = 0.0

NightVentPerf%MaxAirMassFlowRate = 0.0

END IF

! input the night ventilation performance objects

DO NVPerfNum = 1,NumNightVentPerf

CALL GetObjectItem(TRIM(cCurrentModuleObject),NVPerfNum,cAlphaArgs,NumAlphas, &

rNumericArgs,NumNums,IOSTAT, &

NumBlank = lNumericFieldBlanks,AlphaBlank = lAlphaFieldBlanks, &

AlphaFieldNames = cAlphaFieldNames,NumericFieldNames = cNumericFieldNames)

IsNotOK = .false.

IsBlank = .false.

CALL VerifyName(cAlphaArgs(1),NightVentPerf%FanName,NVPerfNum-1,IsNotOK,IsBlank,TRIM(cCurrentModuleObject)//‘Name’)

IF (IsNotOK) THEN

ErrorsFound = .true.

IF (IsBlank) cAlphaArgs(1) = ‘xxxxx’

ENDIF

NightVentPerf(NVPerfNum)%FanName = cAlphaArgs(1)

NightVentPerf(NVPerfNum)%FanEff = rNumericArgs(1)

NightVentPerf(NVPerfNum)%DeltaPress = rNumericArgs(2)

NightVentPerf(NVPerfNum)%MaxAirFlowRate = rNumericArgs(3)

NightVentPerf(NVPerfNum)%MotEff = rNumericArgs(4)

NightVentPerf(NVPerfNum)%MotInAirFrac = rNumericArgs(5)

! find the corresponding fan

NVPerfFanFound = .FALSE.

DO FanNum = 1,NumFans

IF (NightVentPerf(NVPerfNum)%FanName = = Fan(FanNum)%FanName) THEN

NVPerfFanFound = .TRUE.

Fan(FanNum)%NVPerfNum = NVPerfNum

EXIT

END IF

END DO

IF ( .NOT. NVPerfFanFound) THEN

CALL ShowSevereError(TRIM(cCurrentModuleObject)//‘, fan name not found =’//TRIM(cAlphaArgs(1)))

ErrorsFound = .true.

END IF

END DO

DEALLOCATE(cAlphaArgs)

DEALLOCATE(cAlphaFieldNames)

DEALLOCATE(lAlphaFieldBlanks)

DEALLOCATE(cNumericFieldNames)

DEALLOCATE(lNumericFieldBlanks)

DEALLOCATE(rNumericArgs)

IF (ErrorsFound) THEN

CALL ShowFatalError(RoutineName//‘Errors found in input. Program terminates.’)

ENDIF

Do FanNum = 1,NumFans

! Setup Report variables for the Fans

CALL SetupOutputVariable(‘Fan Electric Power[W]’, Fan(FanNum)%FanPower, ‘System’,‘Average’,Fan(FanNum)%FanName)

CALL SetupOutputVariable(‘Fan Delta Temp[C]’, Fan(FanNum)%DeltaTemp, ‘System’,‘Average’,Fan(FanNum)%FanName)

CALL SetupOutputVariable(‘Fan Electric Consumption[J]’, Fan(FanNum)%FanEnergy, ‘System’,‘Sum’,Fan(FanNum)%FanName, &

ResourceTypeKey = ‘Electric’,GroupKey = ‘System’, &

EndUseKey = ‘Fans’,EndUseSubKey = Fan(FanNum)%EndUseSubcategoryName)

END DO

DO OnOffFanNum = 1, NumOnOff

FanNum = NumSimpFan + NumVarVolFan + NumZoneExhFan + OnOffFanNum

CALL SetupOutputVariable(‘On/Off Fan Runtime Fraction’, Fan(FanNum)%FanRuntimeFraction, ‘System’,‘Average’, &

Fan(FanNum)%FanName)

END DO

RETURN

END SUBROUTINE GetFanInput

! End of Get Input subroutines for the HB Module

!******************************************************************************

! Beginning Initialization Section of the Module

!******************************************************************************

SUBROUTINE InitFan(FanNum,FirstHVACIteration)

! SUBROUTINE INFORMATION:

! AUTHOR Richard J. Liesen

! DATE WRITTEN February 1998

! MODIFIED na

! RE-ENGINEERED na

! PURPOSE OF THIS SUBROUTINE:

! This subroutine is for initializations of the Fan Components.

! METHODOLOGY EMPLOYED:

! Uses the status flags to trigger initializations.

! REFERENCES:

! na

! USE STATEMENTS:

USE DataSizing, ONLY: CurSysNum

USE DataAirLoop, ONLY: AirLoopControlInfo

IMPLICIT NONE ! Enforce explicit typing of all variables in this routine

! SUBROUTINE ARGUMENT DEFINITIONS:

LOGICAL, INTENT (IN):: FirstHVACIteration

Integer, Intent(IN) :: FanNum

! SUBROUTINE PARAMETER DEFINITIONS:

! na

! INTERFACE BLOCK SPECIFICATIONS

! na

! DERIVED TYPE DEFINITIONS

! na

! SUBROUTINE LOCAL VARIABLE DECLARATIONS:

Integer :: InletNode

Integer :: OutletNode

Integer :: InNode

Integer :: OutNode

LOGICAL,SAVE :: MyOneTimeFlag = .true.

LOGICAL, ALLOCATABLE,Save, DIMENSION(:) :: MyEnvrnFlag

LOGICAL, ALLOCATABLE,Save, DIMENSION(:) :: MySizeFlag

! FLOW:

IF (MyOneTimeFlag) THEN

ALLOCATE(MyEnvrnFlag(NumFans))

ALLOCATE(MySizeFlag(NumFans))

MyEnvrnFlag = .TRUE.

MySizeFlag = .TRUE.

MyOneTimeFlag = .false.

END IF

IF ( .NOT. SysSizingCalc .AND. MySizeFlag(FanNum)) THEN

CALL SizeFan(FanNum)

! Set the loop cycling flag

IF (Fan(FanNum)%Control = = ‘ONOFF’) THEN

IF (CurSysNum > 0) THEN

AirLoopControlInfo(CurSysNum)%CyclingFan = .TRUE.

END IF

END IF

MySizeFlag(FanNum) = .FALSE.

END IF

! Do the Begin Environment initializations

IF (BeginEnvrnFlag .and. MyEnvrnFlag(FanNum)) THEN

!For all Fan inlet nodes convert the Volume flow to a mass flow

InNode = Fan(FanNum)%InletNodeNum

OutNode = Fan(FanNum)%OutletNodeNum

Fan(FanNum)%RhoAirStdInit = PsyRhoAirFnPbTdbW(StdBaroPress,20.0,0.0)

!Change the Volume Flow Rates to Mass Flow Rates

Fan(FanNum)%MaxAirMassFlowRate = Fan(FanNum)%MaxAirFlowRate * Fan(FanNum)%RhoAirStdInit

Fan(FanNum)%MinAirMassFlowRate = Fan(FanNum)%MinAirFlowRate * Fan(FanNum)%RhoAirStdInit

!Init the Node Control variables

Node(OutNode)%MassFlowRateMax = Fan(FanNum)%MaxAirMassFlowRate

Node(OutNode)%MassFlowRateMin = Fan(FanNum)%MinAirMassFlowRate

!Initialize all report variables to a known state at beginning of simulation

Fan(FanNum)%FanPower = 0.0

Fan(FanNum)%DeltaTemp = 0.0

Fan(FanNum)%FanEnergy = 0.0

MyEnvrnFlag(FanNum) = .FALSE.

END IF

IF (.not. BeginEnvrnFlag) THEN

MyEnvrnFlag(FanNum) = .true.

ENDIF

! Do the Begin Day initializations

! none

! Do the begin HVAC time step initializations

! none

! Do the following initializations (every time step): This should be the info from

! the previous components outlets or the node data in this section.

! Do a check and make sure that the max and min available(control) flow is

! between the physical max and min for the Fan while operating.

InletNode = Fan(FanNum)%InletNodeNum

OutletNode = Fan(FanNum)%OutletNodeNum

Fan(FanNum)%MassFlowRateMaxAvail = MIN(Node(OutletNode)%MassFlowRateMax, &

Node(InletNode)%MassFlowRateMaxAvail)

Fan(FanNum)%MassFlowRateMinAvail = MIN(MAX(Node(OutletNode)%MassFlowRateMin, &

Node(InletNode)%MassFlowRateMinAvail), &

Node(InletNode)%MassFlowRateMaxAvail)

! Load the node data in this section for the component simulation

!

!First need to make sure that the massflowrate is between the max and min avail.

IF (Fan(FanNum)%FanType .NE. ‘ZONE EXHAUST FAN’) THEN

Fan(FanNum)%InletAirMassFlowRate = Min(Node(InletNode)%MassFlowRate, &

Fan(FanNum)%MassFlowRateMaxAvail)

Fan(FanNum)%InletAirMassFlowRate = Max(Fan(FanNum)%InletAirMassFlowRate, &

Fan(FanNum)%MassFlowRateMinAvail)

ELSE ! zone exhaust fans - always run at the max

Fan(FanNum)%MassFlowRateMaxAvail = Fan(FanNum)%MaxAirMassFlowRate

Fan(FanNum)%MassFlowRateMinAvail = 0.0

Fan(FanNum)%InletAirMassFlowRate = Fan(FanNum)%MassFlowRateMaxAvail

END IF

!Then set the other conditions

Fan(FanNum)%InletAirTemp = Node(InletNode)%Temp

Fan(FanNum)%InletAirHumRat = Node(InletNode)%HumRat

Fan(FanNum)%InletAirEnthalpy = Node(InletNode)%Enthalpy

RETURN

END SUBROUTINE InitFan

SUBROUTINE SizeFan(FanNum)

! SUBROUTINE INFORMATION:

! AUTHOR Fred Buhl

! DATE WRITTEN September 2001

! MODIFIED na

! RE-ENGINEERED na

! PURPOSE OF THIS SUBROUTINE:

! This subroutine is for sizing Fan Components for which flow rates have not been

! specified in the input.

! METHODOLOGY EMPLOYED:

! Obtains flow rates from the zone or system sizing arrays.

! REFERENCES:

! na

! USE STATEMENTS:

USE DataSizing

IMPLICIT NONE ! Enforce explicit typing of all variables in this routine

! SUBROUTINE ARGUMENT DEFINITIONS:

Integer, Intent(IN) :: FanNum

! SUBROUTINE PARAMETER DEFINITIONS:

! na

! INTERFACE BLOCK SPECIFICATIONS

! na

! DERIVED TYPE DEFINITIONS

! na

! SUBROUTINE LOCAL VARIABLE DECLARATIONS:

REAL :: FanMinAirFlowRate

EXTERNAL ReportSizingOutput

FanMinAirFlowRate = 0.0

IF (Fan(FanNum)%MaxAirFlowRate = = AutoSize) THEN

IF (CurSysNum > 0) THEN

CALL CheckSysSizing(‘FAN:’//TRIM(Fan(FanNum)%FanType)// ‘:’ // TRIM(Fan(FanNum)%Control), &

Fan(FanNum)%FanName)

SELECT CASE(CurDuctType)

CASE(Main)

Fan(FanNum)%MaxAirFlowRate = FinalSysSizing(CurSysNum)%DesMainVolFlow

FanMinAirFlowRate = CalcSysSizing(CurSysNum)%SysAirMinFlowRat * CalcSysSizing(CurSysNum)%DesMainVolFlow

CASE(Cooling)

Fan(FanNum)%MaxAirFlowRate = FinalSysSizing(CurSysNum)%DesCoolVolFlow

FanMinAirFlowRate = CalcSysSizing(CurSysNum)%SysAirMinFlowRat * CalcSysSizing(CurSysNum)%DesCoolVolFlow

CASE(Heating)

Fan(FanNum)%MaxAirFlowRate = FinalSysSizing(CurSysNum)%DesHeatVolFlow

FanMinAirFlowRate = CalcSysSizing(CurSysNum)%SysAirMinFlowRat * CalcSysSizing(CurSysNum)%DesHeatVolFlow

CASE(Other)

Fan(FanNum)%MaxAirFlowRate = FinalSysSizing(CurSysNum)%DesMainVolFlow

FanMinAirFlowRate = CalcSysSizing(CurSysNum)%SysAirMinFlowRat * CalcSysSizing(CurSysNum)%DesMainVolFlow

CASE DEFAULT

Fan(FanNum)%MaxAirFlowRate = FinalSysSizing(CurSysNum)%DesMainVolFlow

FanMinAirFlowRate = CalcSysSizing(CurSysNum)%SysAirMinFlowRat * CalcSysSizing(CurSysNum)%DesMainVolFlow

END SELECT

ELSE IF (CurZoneEqNum > 0) THEN

CALL CheckZoneSizing(‘FAN:’ // TRIM(Fan(FanNum)%FanType) // ‘:’ // TRIM(Fan(FanNum)%Control), &

Fan(FanNum)%FanName)

IF (.NOT. ZoneHeatingOnlyFan) THEN

Fan(FanNum)%MaxAirFlowRate = MAX(FinalZoneSizing(CurZoneEqNum)%DesCoolVolFlow, &

FinalZoneSizing(CurZoneEqNum)%DesHeatVolFlow)

ELSE

Fan(FanNum)%MaxAirFlowRate = FinalZoneSizing(CurZoneEqNum)%DesHeatVolFlow

END IF

END IF

IF (Fan(FanNum)%MaxAirFlowRate < SmallAirVolFlow) THEN

Fan(FanNum)%MaxAirFlowRate = 0.0

END IF

CALL ReportSizingOutput(‘FAN:’ // TRIM(Fan(FanNum)%FanType) // ‘:’ // TRIM(Fan(FanNum)%Control), &

Fan(FanNum)%FanName, ‘Max Flow Rate [m3/s]’, Fan(FanNum)%MaxAirFlowRate)

IF (Fan(FanNum)%Control = = ‘VARIABLEVOLUME’) THEN

CALL CheckSysSizing(‘FAN:’ // TRIM(Fan(FanNum)%FanType) // ‘:’ // TRIM(Fan(FanNum)%Control), &

Fan(FanNum)%FanName)

Fan(FanNum)%MinAirFlowRate = FanMinAirFlowRate

CALL ReportSizingOutput(‘FAN:’ // TRIM(Fan(FanNum)%FanType) // ‘:’ // TRIM(Fan(FanNum)%Control), &

Fan(FanNum)%FanName, ‘Min Flow Rate [m3/s]’, Fan(FanNum)%MinAirFlowRate)

END IF

END IF

RETURN

END SUBROUTINE SizeFan

! End Initialization Section of the Module

!******************************************************************************

! Begin Algorithm Section of the Module

!******************************************************************************

SUBROUTINE SimSimpleFan(FanNum)

! SUBROUTINE INFORMATION:

! AUTHOR Unknown

! DATE WRITTEN Unknown

! MODIFIED na

! RE-ENGINEERED na

! PURPOSE OF THIS SUBROUTINE:

! This subroutine simulates the simple constant volume fan.

! METHODOLOGY EMPLOYED:

! Converts design pressure rise and efficiency into fan power and temperature rise

! Constant fan pressure rise is assumed.

! REFERENCES:

! ASHRAE HVAC 2 Toolkit, page 2-3 (FANSIM)

! USE STATEMENTS:

! na

IMPLICIT NONE ! Enforce explicit typing of all variables in this routine

! SUBROUTINE ARGUMENT DEFINITIONS:

Integer, Intent(IN) :: FanNum

! SUBROUTINE PARAMETER DEFINITIONS:

! na

! INTERFACE BLOCK SPECIFICATIONS

! na

! DERIVED TYPE DEFINITIONS

! na

! SUBROUTINE LOCAL VARIABLE DECLARATIONS:

Real RhoAir

Real DeltaPress ! [N/M^2]

Real FanEff

Real MassFlow ! [kg/sec]

Real Tin ! [C]

Real Win

Real FanShaftPower ! power delivered to fan shaft

Real PowerLossToAir ! fan and motor loss to air stream (watts)

DeltaPress = Fan(FanNum)%DeltaPress

FanEff = Fan(FanNum)%FanEff

! For a Constant Volume Simple Fan the Max Flow Rate is the Flow Rate for the fan

Tin = Fan(FanNum)%InletAirTemp

Win = Fan(FanNum)%InletAirHumRat

RhoAir = Fan(FanNum)%RhoAirStdInit

MassFlow = MIN(Fan(FanNum)%InletAirMassFlowRate,Fan(FanNum)%MaxAirMassFlowRate)

MassFlow = MAX(MassFlow,Fan(FanNum)%MinAirMassFlowRate)

!

!Determine the Fan Schedule for the Time step

If( ( GetCurrentScheduleValue(Fan(FanNum)%SchedPtr)>0.0 .and. Massflow>0.0 .or. TurnFansOn .and. Massflow>0.0) &

.and. .NOT.TurnFansOff ) Then

!Fan is operating

Fan(FanNum)%FanPower = MassFlow*DeltaPress/(FanEff*RhoAir) ! total fan power

FanShaftPower = Fan(FanNum)%MotEff * Fan(FanNum)%FanPower ! power delivered to shaft

PowerLossToAir = FanShaftPower + (Fan(FanNum)%FanPower - FanShaftPower) * Fan(FanNum)%MotInAirFrac

Fan(FanNum)%OutletAirEnthalpy = Fan(FanNum)%InletAirEnthalpy + PowerLossToAir/MassFlow

! This fan does not change the moisture or Mass Flow across the component

Fan(FanNum)%OutletAirHumRat = Fan(FanNum)%InletAirHumRat

Fan(FanNum)%OutletAirMassFlowRate = MassFlow

Fan(FanNum)%OutletAirTemp = PsyTdbFnHW(Fan(FanNum)%OutletAirEnthalpy,Fan(FanNum)%OutletAirHumRat)

Else

!Fan is off and not operating no power consumed and mass flow rate.

Fan(FanNum)%FanPower = 0.0

FanShaftPower = 0.0

PowerLossToAir = 0.0

Fan(FanNum)%OutletAirMassFlowRate = 0.0

Fan(FanNum)%OutletAirHumRat = Fan(FanNum)%InletAirHumRat

Fan(FanNum)%OutletAirEnthalpy = Fan(FanNum)%InletAirEnthalpy

Fan(FanNum)%OutletAirTemp = Fan(FanNum)%InletAirTemp

! Set the Control Flow variables to 0.0 flow when OFF.

Fan(FanNum)%MassFlowRateMaxAvail = 0.0

Fan(FanNum)%MassFlowRateMinAvail = 0.0

End If

RETURN

END SUBROUTINE SimSimpleFan

SUBROUTINE SimVariableVolumeFan(FanNum)

! SUBROUTINE INFORMATION:

! AUTHOR Unknown

! DATE WRITTEN Unknown

! MODIFIED Phil Haves

! RE-ENGINEERED na

! PURPOSE OF THIS SUBROUTINE:

! This subroutine simulates the simple variable volume fan.

! METHODOLOGY EMPLOYED:

! Converts design pressure rise and efficiency into fan power and temperature rise

! Constant fan pressure rise is assumed.

! Uses curves of fan power fraction vs. fan part load to determine fan power at

! off design conditions.

! REFERENCES:

! ASHRAE HVAC 2 Toolkit, page 2-3 (FANSIM)

! USE STATEMENTS:

! na

IMPLICIT NONE ! Enforce explicit typing of all variables in this routine

! SUBROUTINE ARGUMENT DEFINITIONS:

Integer, Intent(IN) :: FanNum

! SUBROUTINE PARAMETER DEFINITIONS:

! na

! INTERFACE BLOCK SPECIFICATIONS

! na

! DERIVED TYPE DEFINITIONS

! na

! SUBROUTINE LOCAL VARIABLE DECLARATIONS:

Real RhoAir

Real DeltaPress ! [N/M^2 = Pa]

Real FanEff ! Total fan efficiency - combined efficiency of fan, drive train,

! motor and variable speed controller (if any)

Real MassFlow ! [kg/sec]

Real Tin ! [C]

Real Win

Real PartLoadFrac

REAL MaxFlowFrac !Variable Volume Fan Max Flow Fraction [-]

REAL MinFlowFrac !Variable Volume Fan Min Flow Fraction [-]

REAL FlowFrac !Variable Volume Fan Flow Fraction [-]

Real FanShaftPower ! power delivered to fan shaft

Real PowerLossToAir ! fan and motor loss to air stream (watts)

! Simple Variable Volume Fan - default values from DOE-2

! Type of Fan Coeff1 Coeff2 Coeff3 Coeff4 Coeff5

! INLET VANE DAMPERS 0.35071223 0.30850535 -0.54137364 0.87198823 0.000

! DISCHARGE DAMPERS 0.37073425 0.97250253 -0.34240761 0.000 0.000

! VARIABLE SPEED MOTOR 0.0015302446 0.0052080574 1.1086242 -0.11635563 0.000

DeltaPress = Fan(FanNum)%DeltaPress

FanEff = Fan(FanNum)%FanEff

Tin = Fan(FanNum)%InletAirTemp

Win = Fan(FanNum)%InletAirHumRat

RhoAir = Fan(FanNum)%RhoAirStdInit

MassFlow = MIN(Fan(FanNum)%InletAirMassFlowRate,Fan(FanNum)%MaxAirMassFlowRate)

! MassFlow = MAX(MassFlow,Fan(FanNum)%MinAirMassFlowRate)

! Calculate and check limits on fraction of system flow

MaxFlowFrac = 1.0

! MinFlowFrac is calculated from the ration of the volume flows and is non-dimensional

MinFlowFrac = Fan(FanNum)%MinAirFlowRate/Fan(FanNum)%MaxAirFlowRate

! The actual flow fraction is calculated from MassFlow and the MaxVolumeFlow * AirDensity

FlowFrac = MassFlow/(Fan(FanNum)%MaxAirMassFlowRate)

! Calculate the part Load Fraction (PH 7/13/03)

FlowFrac = MAX(MinFlowFrac,MIN(FlowFrac,1.0)) ! limit flow fraction to allowed range

PartLoadFrac = Fan(FanNum)%FanCoeff(1) + Fan(FanNum)%FanCoeff(2)*FlowFrac + &

Fan(FanNum)%FanCoeff(3)*FlowFrac**2 + Fan(FanNum)%FanCoeff(4)*FlowFrac**3 + &

Fan(FanNum)%FanCoeff(5)*FlowFrac**4

!Determine the Fan Schedule for the Time step

If( ( GetCurrentScheduleValue(Fan(FanNum)%SchedPtr)>0.0 .and. Massflow>0.0 .or. TurnFansOn .and. Massflow>0.0) &

.and. .NOT.TurnFansOff ) Then

!Fan is operating - calculate power loss and enthalpy rise

! Fan(FanNum)%FanPower = PartLoadFrac*FullMassFlow*DeltaPress/(FanEff*RhoAir) ! total fan power

Fan(FanNum)%FanPower = PartLoadFrac*Fan(FanNum)%MaxAirMassFlowRate*DeltaPress/(FanEff*RhoAir) ! total fan power (PH 7/13/03)

FanShaftPower = Fan(FanNum)%MotEff * Fan(FanNum)%FanPower ! power delivered to shaft

PowerLossToAir = FanShaftPower + (Fan(FanNum)%FanPower - FanShaftPower) * Fan(FanNum)%MotInAirFrac

Fan(FanNum)%OutletAirEnthalpy = Fan(FanNum)%InletAirEnthalpy + PowerLossToAir/MassFlow

! This fan does not change the moisture or Mass Flow across the component

Fan(FanNum)%OutletAirHumRat = Fan(FanNum)%InletAirHumRat

Fan(FanNum)%OutletAirMassFlowRate = MassFlow

Fan(FanNum)%OutletAirTemp = PsyTdbFnHW(Fan(FanNum)%OutletAirEnthalpy,Fan(FanNum)%OutletAirHumRat)

Else

!Fan is off and not operating no power consumed and mass flow rate.

Fan(FanNum)%FanPower = 0.0

FanShaftPower = 0.0

PowerLossToAir = 0.0

Fan(FanNum)%OutletAirMassFlowRate = 0.0

Fan(FanNum)%OutletAirHumRat = Fan(FanNum)%InletAirHumRat

Fan(FanNum)%OutletAirEnthalpy = Fan(FanNum)%InletAirEnthalpy

Fan(FanNum)%OutletAirTemp = Fan(FanNum)%InletAirTemp

! Set the Control Flow variables to 0.0 flow when OFF.

Fan(FanNum)%MassFlowRateMaxAvail = 0.0

Fan(FanNum)%MassFlowRateMinAvail = 0.0

End If

RETURN

END SUBROUTINE SimVariableVolumeFan

SUBROUTINE SimOnOffFan(FanNum)

! SUBROUTINE INFORMATION:

! AUTHOR Unknown

! DATE WRITTEN Unknown

! MODIFIED Shirey, May 2001

! RE-ENGINEERED na

! PURPOSE OF THIS SUBROUTINE:

! This subroutine simulates the simple on/off fan.

! METHODOLOGY EMPLOYED:

! Converts design pressure rise and efficiency into fan power and temperature rise

! Constant fan pressure rise is assumed.

! Uses curves of fan power fraction vs. fan part load to determine fan power at

! off design conditions.

! Same as simple (constant volume) fan, except added part-load curve input

! REFERENCES:

! ASHRAE HVAC 2 Toolkit, page 2-3 (FANSIM)

! USE STATEMENTS:

USE CurveManager, ONLY: CurveValue

IMPLICIT NONE ! Enforce explicit typing of all variables in this routine

! SUBROUTINE ARGUMENT DEFINITIONS:

Integer, Intent(IN) :: FanNum

! SUBROUTINE PARAMETER DEFINITIONS:

! na

! INTERFACE BLOCK SPECIFICATIONS

! na

! DERIVED TYPE DEFINITIONS

! na

! SUBROUTINE LOCAL VARIABLE DECLARATIONS:

Real RhoAir

Real DeltaPress ! [N/M^2]

Real FanEff

Real MassFlow ! [kg/sec]

Real Tin ! [C]

Real Win

Real PartLoadRatio !Ratio of actual mass flow rate to max mass flow rate

REAL FlowFrac !Actual Fan Flow Fraction = actual mass flow rate / max air mass flow rate

Real FanShaftPower ! power delivered to fan shaft

Real PowerLossToAir ! fan and motor loss to air stream (watts)

DeltaPress = Fan(FanNum)%DeltaPress

FanEff = Fan(FanNum)%FanEff

Tin = Fan(FanNum)%InletAirTemp

Win = Fan(FanNum)%InletAirHumRat

RhoAir = Fan(FanNum)%RhoAirStdInit

MassFlow = MIN(Fan(FanNum)%InletAirMassFlowRate,Fan(FanNum)%MaxAirMassFlowRate)

MassFlow = MAX(MassFlow,Fan(FanNum)%MinAirMassFlowRate)

Fan(FanNum)%FanRuntimeFraction = 0.0

! The actual flow fraction is calculated from MassFlow and the MaxVolumeFlow * AirDensity

FlowFrac = MassFlow/(Fan(FanNum)%MaxAirMassFlowRate)

! Calculate the part load ratio, can’t be greater than 1

PartLoadRatio = MIN(1.0,FlowFrac)

! Determine the Fan Schedule for the Time step

IF( ( GetCurrentScheduleValue(Fan(FanNum)%SchedPtr)>0.0 .and. Massflow>0.0 .or. TurnFansOn .and. Massflow>0.0) &

.and. .NOT.TurnFansOff ) THEN

! Fan is operating

IF (OnOffFanPartLoadFraction < = 0.0) THEN

CALL ShowWarningError(‘FAN:SIMPLE:ONOFF, OnOffFanPartLoadFraction < = 0.0, Reset to 1.0’)

OnOffFanPartLoadFraction = 1.0 ! avoid divide by zero or negative PLF

END IF

IF (OnOffFanPartLoadFraction < 0.7) THEN

OnOffFanPartLoadFraction = 0.7 ! a warning message is already issued from the DX coils or gas heating coil

END IF

! Keep fan runtime fraction between 0.0 and 1.0

Fan(FanNum)%FanRuntimeFraction = MAX(0.0,MIN(1.0,PartLoadRatio/OnOffFanPartLoadFraction))

! Fan(FanNum)%FanPower = MassFlow*DeltaPress/(FanEff*RhoAir*OnOffFanPartLoadFraction)! total fan power

Fan(FanNum)%FanPower = Fan(FanNum)%MaxAirMassFlowRate*Fan(FanNum)%FanRuntimeFraction*DeltaPress/(FanEff*RhoAir)!total fan power

! OnOffFanPartLoadFraction is passed via DataHVACGlobals from the cooling or heating coil that is

! requesting the fan to operate in cycling fan/cycling coil mode

OnOffFanPartLoadFraction = 1.0 ! reset to 1 in case other on/off fan is called without a part load curve

FanShaftPower = Fan(FanNum)%MotEff * Fan(FanNum)%FanPower ! power delivered to shaft

PowerLossToAir = FanShaftPower + (Fan(FanNum)%FanPower - FanShaftPower) * Fan(FanNum)%MotInAirFrac

Fan(FanNum)%OutletAirEnthalpy = Fan(FanNum)%InletAirEnthalpy + PowerLossToAir/MassFlow

! This fan does not change the moisture or Mass Flow across the component

Fan(FanNum)%OutletAirHumRat = Fan(FanNum)%InletAirHumRat

Fan(FanNum)%OutletAirMassFlowRate = MassFlow

! Fan(FanNum)%OutletAirTemp = Tin + PowerLossToAir/(MassFlow*PsyCpAirFnWTdb(Win,Tin))

Fan(FanNum)%OutletAirTemp = PsyTdbFnHW(Fan(FanNum)%OutletAirEnthalpy,Fan(FanNum)%OutletAirHumRat)

ELSE

! Fan is off and not operating no power consumed and mass flow rate.

Fan(FanNum)%FanPower = 0.0

FanShaftPower = 0.0

PowerLossToAir = 0.0

Fan(FanNum)%OutletAirMassFlowRate = 0.0

Fan(FanNum)%OutletAirHumRat = Fan(FanNum)%InletAirHumRat

Fan(FanNum)%OutletAirEnthalpy = Fan(FanNum)%InletAirEnthalpy

Fan(FanNum)%OutletAirTemp = Fan(FanNum)%InletAirTemp

! Set the Control Flow variables to 0.0 flow when OFF.

Fan(FanNum)%MassFlowRateMaxAvail = 0.0

Fan(FanNum)%MassFlowRateMinAvail = 0.0

END IF

RETURN

END SUBROUTINE SimOnOffFan

SUBROUTINE SimZoneExhaustFan(FanNum)

! SUBROUTINE INFORMATION:

! AUTHOR Fred Buhl

! DATE WRITTEN Jan 2000

! MODIFIED na

! RE-ENGINEERED na

! PURPOSE OF THIS SUBROUTINE:

! This subroutine simulates the Zone Exhaust Fan

! METHODOLOGY EMPLOYED:

! Converts design pressure rise and efficiency into fan power and temperature rise

! Constant fan pressure rise is assumed.

! REFERENCES:

! ASHRAE HVAC 2 Toolkit, page 2-3 (FANSIM)

! USE STATEMENTS:

! na

IMPLICIT NONE ! Enforce explicit typing of all variables in this routine

! SUBROUTINE ARGUMENT DEFINITIONS:

Integer, Intent(IN) :: FanNum

! SUBROUTINE PARAMETER DEFINITIONS:

! na

! INTERFACE BLOCK SPECIFICATIONS

! na

! DERIVED TYPE DEFINITIONS

! na

! SUBROUTINE LOCAL VARIABLE DECLARATIONS:

Real RhoAir

Real DeltaPress ! [N/M^2]

Real FanEff

Real MassFlow ! [kg/sec]

Real Tin ! [C]

Real Win

Real PowerLossToAir ! fan and motor loss to air stream (watts)

DeltaPress = Fan(FanNum)%DeltaPress

FanEff = Fan(FanNum)%FanEff

! For a Constant Volume Simple Fan the Max Flow Rate is the Flow Rate for the fan

Tin = Fan(FanNum)%InletAirTemp

Win = Fan(FanNum)%InletAirHumRat

RhoAir = Fan(FanNum)%RhoAirStdInit

MassFlow = Fan(FanNum)%InletAirMassFlowRate

!

!Determine the Fan Schedule for the Time step

If( ( GetCurrentScheduleValue(Fan(FanNum)%SchedPtr)>0.0 .or. TurnFansOn ) &

.and. .NOT.TurnFansOff ) Then

!Fan is operating

Fan(FanNum)%FanPower = MassFlow*DeltaPress/(FanEff*RhoAir) ! total fan power

PowerLossToAir = Fan(FanNum)%FanPower

Fan(FanNum)%OutletAirEnthalpy = Fan(FanNum)%InletAirEnthalpy + PowerLossToAir/MassFlow

! This fan does not change the moisture or Mass Flow across the component

Fan(FanNum)%OutletAirHumRat = Fan(FanNum)%InletAirHumRat

Fan(FanNum)%OutletAirMassFlowRate = MassFlow

Fan(FanNum)%OutletAirTemp = PsyTdbFnHW(Fan(FanNum)%OutletAirEnthalpy,Fan(FanNum)%OutletAirHumRat)

Else

!Fan is off and not operating no power consumed and mass flow rate.

Fan(FanNum)%FanPower = 0.0

PowerLossToAir = 0.0

Fan(FanNum)%OutletAirMassFlowRate = 0.0

Fan(FanNum)%OutletAirHumRat = Fan(FanNum)%InletAirHumRat

Fan(FanNum)%OutletAirEnthalpy = Fan(FanNum)%InletAirEnthalpy

Fan(FanNum)%OutletAirTemp = Fan(FanNum)%InletAirTemp

! Set the Control Flow variables to 0.0 flow when OFF.

Fan(FanNum)%MassFlowRateMaxAvail = 0.0

Fan(FanNum)%MassFlowRateMinAvail = 0.0

Fan(FanNum)%InletAirMassFlowRate = 0.0

End If

RETURN

END SUBROUTINE SimZoneExhaustFan

! End Algorithm Section of the Module

! *****************************************************************************

! Beginning of Update subroutines for the Fan Module

! *****************************************************************************

SUBROUTINE UpdateFan(FanNum)

! SUBROUTINE INFORMATION:

! AUTHOR Richard Liesen

! DATE WRITTEN April 1998

! MODIFIED na

! RE-ENGINEERED na

! PURPOSE OF THIS SUBROUTINE:

! This subroutine updates the fan outlet nodes.

! METHODOLOGY EMPLOYED:

! Data is moved from the fan data structure to the fan outlet nodes.

! REFERENCES:

! na

! USE STATEMENTS:

! na

IMPLICIT NONE ! Enforce explicit typing of all variables in this routine

! SUBROUTINE ARGUMENT DEFINITIONS:

Integer, Intent(IN) :: FanNum

! SUBROUTINE PARAMETER DEFINITIONS:

! na

! INTERFACE BLOCK SPECIFICATIONS

! na

! DERIVED TYPE DEFINITIONS

! na

! SUBROUTINE LOCAL VARIABLE DECLARATIONS:

Integer :: OutletNode

Integer :: InletNode

OutletNode = Fan(FanNum)%OutletNodeNum

InletNode = Fan(FanNum)%InletNodeNum

! Set the outlet air nodes of the fan

Node(OutletNode)%MassFlowRate = Fan(FanNum)%OutletAirMassFlowRate

Node(OutletNode)%Temp = Fan(FanNum)%OutletAirTemp

Node(OutletNode)%HumRat = Fan(FanNum)%OutletAirHumRat

Node(OutletNode)%Enthalpy = Fan(FanNum)%OutletAirEnthalpy

! Set the outlet nodes for properties that just pass through & not used

Node(OutletNode)%Quality = Node(InletNode)%Quality

Node(OutletNode)%Press = Node(InletNode)%Press

! Set the Node Flow Control Variables from the Fan Control Variables

Node(OutletNode)%MassFlowRateMaxAvail = Fan(FanNum)%MassFlowRateMaxAvail

Node(OutletNode)%MassFlowRateMinAvail = Fan(FanNum)%MassFlowRateMinAvail

IF (Fan(FanNum)%FanType .EQ. ‘ZONE EXHAUST FAN’) THEN

Node(InletNode)%MassFlowRate = Fan(FanNum)%InletAirMassFlowRate

END IF

RETURN

END Subroutine UpdateFan

! End of Update subroutines for the Fan Module

! *****************************************************************************

! Beginning of Reporting subroutines for the Fan Module

! *****************************************************************************

SUBROUTINE ReportFan(FanNum)

! SUBROUTINE INFORMATION:

! AUTHOR Richard Liesen

! DATE WRITTEN April 1998

! MODIFIED na

! RE-ENGINEERED na

! PURPOSE OF THIS SUBROUTINE:

! This subroutine updates the report variables for the fans.

! METHODOLOGY EMPLOYED:

! na

! REFERENCES:

! na

! USE STATEMENTS:

Use DataHVACGlobals, ONLY: TimeStepSys, FanElecPower

IMPLICIT NONE ! Enforce explicit typing of all variables in this routine

! SUBROUTINE ARGUMENT DEFINITIONS:

Integer, Intent(IN) :: FanNum

! SUBROUTINE PARAMETER DEFINITIONS:

! na

! INTERFACE BLOCK SPECIFICATIONS

! na

! DERIVED TYPE DEFINITIONS

! na

! SUBROUTINE LOCAL VARIABLE DECLARATIONS:

! na

Fan(FanNum)%FanEnergy = Fan(FanNum)%FanPower*TimeStepSys*3600

Fan(FanNum)%DeltaTemp = Fan(FanNum)%OutletAirTemp - Fan(FanNum)%InletAirTemp

FanElecPower = Fan(FanNum)%FanPower

RETURN

END Subroutine ReportFan

! End of Reporting subroutines for the Fan Module

! *****************************************************************************

! Beginning of Utility subroutines for the Fan Module

! *****************************************************************************

FUNCTION GetFanDesignVolumeFlowRate(FanType,FanName,ErrorsFound) RESULT(DesignVolumeFlowRate)

! FUNCTION INFORMATION:

! AUTHOR Linda Lawrie

! DATE WRITTEN February 2006

! MODIFIED na

! RE-ENGINEERED na

! PURPOSE OF THIS FUNCTION:

! This function looks up the design volume flow rate for the given fan and returns it. If

! incorrect fan type or name is given, errorsfound is returned as true and value is returned

! as negative.

! METHODOLOGY EMPLOYED:

! na

! REFERENCES:

! na

! USE STATEMENTS:

USE InputProcessor, ONLY: FindItemInList

IMPLICIT NONE ! Enforce explicit typing of all variables in this routine

! FUNCTION ARGUMENT DEFINITIONS:

CHARACTER(len = *), INTENT(IN) :: FanType ! must match fan types in this module

CHARACTER(len = *), INTENT(IN) :: FanName ! must match fan names for the fan type

LOGICAL, INTENT(INOUT) :: ErrorsFound ! set to true if problem

REAL :: DesignVolumeFlowRate ! returned flow rate of matched fan

! FUNCTION PARAMETER DEFINITIONS:

! na

! INTERFACE BLOCK SPECIFICATIONS:

! na

! DERIVED TYPE DEFINITIONS:

! na

! FUNCTION LOCAL VARIABLE DECLARATIONS:

INTEGER :: WhichFan

! Obtains and Allocates fan related parameters from input file

IF (GetFanInputFlag) THEN !First time subroutine has been entered

CALL GetFanInput

GetFanInputFlag = .false.

End If

WhichFan = FindItemInList(FanName,Fan%FanName,NumFans)

IF (WhichFan / = 0) THEN

DesignVolumeFlowRate = Fan(WhichFan)%MaxAirFlowRate

ENDIF

IF (WhichFan = = 0) THEN

CALL ShowSevereError(‘Could not find FanType = “’//TRIM(FanType)//”’ with Name = “’//TRIM(FanName)//”’’)

ErrorsFound = .true.

DesignVolumeFlowRate = -1000.

ENDIF

RETURN

END FUNCTION GetFanDesignVolumeFlowRate

FUNCTION GetFanInletNode(FanType,FanName,ErrorsFound) RESULT(NodeNumber)

! FUNCTION INFORMATION:

! AUTHOR Linda Lawrie

! DATE WRITTEN February 2006

! MODIFIED na

! RE-ENGINEERED na

! PURPOSE OF THIS FUNCTION:

! This function looks up the given fan and returns the inlet node. If

! incorrect fan type or name is given, errorsfound is returned as true and value is returned

! as zero.

! METHODOLOGY EMPLOYED:

! na

! REFERENCES:

! na

! USE STATEMENTS:

USE InputProcessor, ONLY: FindItemInList

IMPLICIT NONE ! Enforce explicit typing of all variables in this routine

! FUNCTION ARGUMENT DEFINITIONS:

CHARACTER(len = *), INTENT(IN) :: FanType ! must match fan types in this module

CHARACTER(len = *), INTENT(IN) :: FanName ! must match fan names for the fan type

LOGICAL, INTENT(INOUT) :: ErrorsFound ! set to true if problem

INTEGER :: NodeNumber ! returned outlet node of matched fan

! FUNCTION PARAMETER DEFINITIONS:

! na

! INTERFACE BLOCK SPECIFICATIONS:

! na

! DERIVED TYPE DEFINITIONS:

! na

! FUNCTION LOCAL VARIABLE DECLARATIONS:

INTEGER :: WhichFan

! Obtains and Allocates fan related parameters from input file

IF (GetFanInputFlag) THEN !First time subroutine has been entered

CALL GetFanInput

GetFanInputFlag = .false.

End If

WhichFan = FindItemInList(FanName,Fan%FanName,NumFans)

IF (WhichFan / = 0) THEN

NodeNumber = Fan(WhichFan)%InletNodeNum

ENDIF

IF (WhichFan = = 0) THEN

CALL ShowSevereError(‘Could not find FanType = “’//TRIM(FanType)//”’ with Name = “’//TRIM(FanName)//”’’)

ErrorsFound = .true.

NodeNumber = 0

ENDIF

RETURN

END FUNCTION GetFanInletNode

FUNCTION GetFanOutletNode(FanType,FanName,ErrorsFound) RESULT(NodeNumber)

! FUNCTION INFORMATION:

! AUTHOR Linda Lawrie

! DATE WRITTEN February 2006

! MODIFIED na

! RE-ENGINEERED na

! PURPOSE OF THIS FUNCTION:

! This function looks up the given fan and returns the outlet node. If

! incorrect fan type or name is given, errorsfound is returned as true and value is returned

! as zero.

! METHODOLOGY EMPLOYED:

! na

! REFERENCES:

! na

! USE STATEMENTS:

USE InputProcessor, ONLY: FindItemInList

IMPLICIT NONE ! Enforce explicit typing of all variables in this routine

! FUNCTION ARGUMENT DEFINITIONS:

CHARACTER(len = *), INTENT(IN) :: FanType ! must match fan types in this module

CHARACTER(len = *), INTENT(IN) :: FanName ! must match fan names for the fan type

LOGICAL, INTENT(INOUT) :: ErrorsFound ! set to true if problem

INTEGER :: NodeNumber ! returned outlet node of matched fan

! FUNCTION PARAMETER DEFINITIONS:

! na

! INTERFACE BLOCK SPECIFICATIONS:

! na

! DERIVED TYPE DEFINITIONS:

! na

! FUNCTION LOCAL VARIABLE DECLARATIONS:

INTEGER :: WhichFan

! Obtains and Allocates fan related parameters from input file

IF (GetFanInputFlag) THEN !First time subroutine has been entered

CALL GetFanInput

GetFanInputFlag = .false.

End If

WhichFan = FindItemInList(FanName,Fan%FanName,NumFans)

IF (WhichFan / = 0) THEN

NodeNumber = Fan(WhichFan)%OutletNodeNum

ENDIF

IF (WhichFan = = 0) THEN

CALL ShowSevereError(‘Could not find FanType = “’//TRIM(FanType)//”’ with Name = “’//TRIM(FanName)//”’’)

ErrorsFound = .true.

NodeNumber = 0

ENDIF

RETURN

END FUNCTION GetFanOutletNode

! End of Utility subroutines for the Fan Module

! *****************************************************************************

! NOTICE

!

! Copyright © 1996-xxxx The Board of Trustees of the University of Illinois

! and The Regents of the University of California through Ernest Orlando Lawrence

! Berkeley National Laboratory. All rights reserved.

!

! Portions of the EnergyPlus software package have been developed and copyrighted

! by other individuals, companies and institutions. These portions have been

! incorporated into the EnergyPlus software package under license. For a complete

! list of contributors, see “Notice” located in EnergyPlus.f90.

!

! NOTICE: The U.S. Government is granted for itself and others acting on its

! behalf a paid-up, nonexclusive, irrevocable, worldwide license in this data to

! reproduce, prepare derivative works, and perform publicly and display publicly.

! Beginning five (5) years after permission to assert copyright is granted,

! subject to two possible five year renewals, the U.S. Government is granted for

! itself and others acting on its behalf a paid-up, non-exclusive, irrevocable

! worldwide license in this data to reproduce, prepare derivative works,

! distribute copies to the public, perform publicly and display publicly, and to

! permit others to do so.

!

! TRADEMARKS: EnergyPlus is a trademark of the US Department of Energy.

!

End Module Fans