cBatModel.vb

Public Class cBatModel

    Private sFilePath As String

    Private a0 As Single, a1 As Single, a2 As Single, a3 As Single, a4 As Single, a5 As Single, a6 As Single
    Private b0 As Single, b1 As Single, b2 As Single, b3 As Single, b4 As Single, b5 As Single, b6 As Single
    Private c0 As Single, c1 As Single, c2 As Single, c3 As Single, c4 As Single
    Private d0 As Single, d1 As Single, d2 As Single
    Private NCELLS As Single
    Private RI_20 As Single
    Private T_AMB As Single
    Private T_MAX As Single
    Private CP As Single
    Private MB As Single


    Public SOC_Kap As Single
    Public SOC_MAX As Single
    Public SOC_MIN As Single

    'Aktuelle Daten (d.h. zum aktuellen (zuletzt berechneten) Zeitschritt)

    Public TempBat As Single
    Public Ubat As Single           'Spannung   [V]     (Array)
    Public Ibat As Single           'Strom      [A]     (Array)
    Public SOC As Single
    Public PbatV As Single       'Verluste in Batterie   [kW]    (Array)


    Private LastTempBat As Single
    Private LastSOC As Single
    Private PmaxEntl As Single              'maximal zulässige Leistung zum Assistieren (Batterie entladen) [kW]    Vorzeichen negativ (Renhart Standard)
    Private PmaxLad As Single               'maximal zulässige Leistung zum Generieren (Batterie laden)     [kW]    Vorzeichen positiv (Renhart Standard)

    Private MyEV As cPower


    Public Sub New(ByRef MycPower As cPower)
        MyEV = MycPower
    End Sub

    Public Sub CleanUp()
        MyEV = Nothing
    End Sub

    Public Function PiBat(ByVal PiEM As Single) As Single
        'TODO...

        Return PiEM / 0.9



    End Function

    'Maximal zulässige Leistung zum Antreiben (Batterie entladen) [kW]    Vorzeichen positiv (PHEM Standard)
    Public ReadOnly Property PmaxAntr As Single
        Get
            Return -PmaxEntl
        End Get
    End Property

    'Maximal zulässige Leistung zum Generieren/Rekuperiren (Batterie laden) [kW]    Vorzeichen negativ (PHEM Standard)
    Public ReadOnly Property PmaxLaden As Single
        Get
            Return -PmaxLad
        End Get
    End Property



    '--------------------------------------------------------------------------------------------
    '--------------------------------- ~Batteriemodell Renhart~ ---------------------------------
    '--------------------------------------------------------------------------------------------
    'Methode zur Initialisierung - wird einmal aufgerufen
    Public Function Bat_Init() As Boolean

        Dim BFile As New cFile_V3
        Dim FunkTemp As Single  ' Temp-Funktion für Ri(Temp)
        Dim U0_E As Single      ' Ubatt(SOC(T), Ibatt=0), Entladekurve
        Dim U0_L As Single      ' Ubatt(SOC(T), Ibatt=0), Ladekurve

        'Abbruch wenn's Datei nicht gibt
        If sFilePath = "" Then Return False
        If Not IO.File.Exists(sFilePath) Then Return False


        If Not BFile.OpenRead(sFilePath) Then
            Return False
        End If

        'Einlesen der Parameter:
        a0 = BFile.ReadLine(0)
        a1 = BFile.ReadLine(0)
        a2 = BFile.ReadLine(0)
        a3 = BFile.ReadLine(0)
        a4 = BFile.ReadLine(0)
        a5 = BFile.ReadLine(0)
        a6 = BFile.ReadLine(0)
        b0 = BFile.ReadLine(0)
        b1 = BFile.ReadLine(0)
        b2 = BFile.ReadLine(0)
        b3 = BFile.ReadLine(0)
        b4 = BFile.ReadLine(0)
        b5 = BFile.ReadLine(0)
        b6 = BFile.ReadLine(0)
        c0 = BFile.ReadLine(0)
        c1 = BFile.ReadLine(0)
        c2 = BFile.ReadLine(0)
        c3 = BFile.ReadLine(0)
        c4 = BFile.ReadLine(0)
        d0 = BFile.ReadLine(0)
        d1 = BFile.ReadLine(0)
        d2 = BFile.ReadLine(0)
        SOC_MIN = BFile.ReadLine(0)     '0..1       SOC_MIN = SOCzulu
        SOC_MAX = BFile.ReadLine(0)     '0..1       SOC_MAX = SOCzulo
        SOC_Kap = BFile.ReadLine(0)     '[Ah]
        NCELLS = BFile.ReadLine(0)      'Anzahl der NiMH-Zellen
        RI_20 = BFile.ReadLine(0)       'RI_20 = RiOhm (abzuklären)
        T_AMB = BFile.ReadLine(0)
        T_MAX = BFile.ReadLine(0)
        CP = BFile.ReadLine(0)
        MB = BFile.ReadLine(0)

        BFile.Close()
        BFile = Nothing

        TempBat = T_AMB
        PbatV = 0.0
        SOC = GEN.SOCstart
        LastSOC = MyEV.SOCstart
        ' ----------------------------------------------------------------------------------------
        ' Berechnung der Batteriespannung bei TempBat und SOC(0), Entladekurve
        ' ----------------------------------------------------------------------------------------
        FunkTemp = Ftemp(TempBat)
        U0_E = Uent(SOC) - (Uent(1) - Uent(0)) * 1.1 * (1 - FunkTemp)
        Ubat = U0_E
        ' ----------------------------------------------------------------------------------------
        ' Berechnung der Batteriespannung bei TempBat und SOC(0), Ladekurve
        ' ----------------------------------------------------------------------------------------
        U0_L = Ulad(SOC) - (Uent(1) - Uent(0)) * 1.1 * (1 - FunkTemp)
        ' ----------------------------------------------------------------------------------------


        Return True

    End Function

    'Methode zur Berechnung der zulässigen Leistung - sekündlicher Aufruf
    Public Sub Bat_Pzul(ByVal t As Integer)
        Dim FunkTemp As Single  ' Temp-Funktion für Ri(Temp)
        Dim U0_E As Single      ' Ubatt(SOC(T), Ibatt=0), Entladekurve
        Dim U0_L As Single      ' Ubatt(SOC(T), Ibatt=0), Ladekurve

        If t < 1 Then
            LastTempBat = T_AMB
            LastSOC = MyEV.SOCstart
        Else
            LastTempBat = MyEV.TempBat(t - 1)
            LastSOC = MyEV.SOC(t - 1)
        End If

        FunkTemp = Ftemp(LastTempBat)
        U0_E = Uent(LastSOC) - (Uent(1) - Uent(0.0)) * 1.1 * (1 - FunkTemp)
        PmaxEntl = -U0_E ^ 2 / (4.0 * RiTemp(LastTempBat) * 1000.0)  ' in kW
        U0_L = Ulad(LastSOC) - (Uent(1) - Uent(0.0)) * 1.1 * (1 - FunkTemp)
        PmaxLad = U0_L ^ 2 / (4.0 * RiTemp(LastTempBat) * 1000.0)  ' in kW

        'PmaxEntl = -SOC_Kap * 3600 * (SOC(jz - 1) - SOC_MIN)
        'PmaxLad = SOC_Kap * 3600 * (SOC_MAX - SOC(jz - 1))


    End Sub

    'Methode zur Berechnung der Batterieveluste und SOC für geg. Leistung - sekündlicher Aufruf
    Public Sub Bat_Calc(ByVal Perf As Single, ByVal t As Integer)
        Dim epsilon As Single = 0.001 ' Abfrageschranke

        If t < 1 Then
            LastTempBat = T_AMB
            LastSOC = MyEV.SOCstart
        Else
            LastTempBat = MyEV.TempBat(t - 1)
            LastSOC = MyEV.SOC(t - 1)
        End If

        Perf *= -1                  'Vozeichenwechsel PHEM-Standard => Renhart-Standard

        Select Case Perf
            Case Is < -epsilon      ' Assistieren (Entladen) der Batterie
                ' MsgBox("negativ" + Str(Perf))
                Bat_Ent(Perf)
            Case Is > epsilon       ' Generieren (Laden) der Batterie
                'MsgBox("positiv" + Str(Perf))
                Bat_Lad(Perf)
            Case Else               ' Leistung ist zu klein, alles bleibt gleich
                'MsgBox(Str(jz) + ": Betrag von " + Str(Perf) + " ist kleiner gleich " + Str(epsilon))
                Bat_Nix()
        End Select


        'Input:
        '   Perf ...geforderte Leistung. Bedingung: PgMAX < Perf < PaMAX [kW]
        '   alle Paramer die in Bat_Init bestimmt/eingelesen wurden
        '   jz ...Aktueller Zeitschritt
        '   Alle Arrays von Zeitschritt 1 bis jz-1

        'Output:
        '   SOC(jz)
        '   Ubat(jz)
        '   Ibat(jz)
        '   PbatV(jz)

        '-------------TEST-------------
        'PbatV(jz) = 0.2 * Math.Abs(Perf)
        'SOC(jz) = SOC(jz - 1) + Perf / 5000
        'Ubat(jz) = (SOC(jz) - SOC_MIN) / (SOC_MAX - SOC_MIN) * 80 + 120
        'Ibat(jz) = Perf / Ubat(jz)
        '-------------TEST-------------




    End Sub

    'Übergibt PeBat für geg. PiBat (Vorzeichen nach PHEM)
    Public Function fPeBat(ByVal PiBat As Single) As Single
        If PiBat < 0 Then
            Return -fPbatLad(-PiBat)
        Else
            Return -fPbatEnt(-PiBat)
        End If
    End Function


    Public Property FilePath() As String
        Get
            Return sFilePath
        End Get
        Set(ByVal value As String)
            sFilePath = value
        End Set
    End Property



    '--------------------------------------------------------------------------------------------
    '----------------------------------------- PRIVATE ------------------------------------------
    '--------------------------------------------------------------------------------------------

    'Batterie entladen
    Private Sub Bat_Ent(ByVal Perf As Single)
        Dim FunkTemp As Single  ' Temp-Funktion für Ri(Temp)
        Dim U0_E As Single      ' Ubatt(SOC(T), Ibatt=0), Entladekurve
        Dim Ri_T As Single      ' Ri bei Temperatur T, lokal

        'Temperaturfunktion
        FunkTemp = Ftemp(LastTempBat)

        'Ri bestimmen abhängig von Temperatur
        Ri_T = RiTemp(LastTempBat)

        'Spannung bestimmen aus SOC und Spannungskurve
        U0_E = Uent(LastSOC) - (Uent(1) - Uent(0)) * 1.1 * (1 - FunkTemp)

        'Strom berechnen
        Ibat = -U0_E / 2 / Ri_T + Math.Sqrt((U0_E / 2 / Ri_T) ^ 2 + Perf * 1000 / Ri_T)

        'Batterieverluste
        PbatV = Ibat ^ 2 * Ri_T / 1000.0

        'Batterietemperatur
        TempBat = LastTempBat + PbatV * 1000.0 * 1.0 / CP / MB
        If TempBat >= T_MAX Then
            TempBat = T_MAX
        End If

        'SOC berechnen
        SOC = LastSOC + Ibat * 1.0 / (SOC_Kap * 3600)

        'Korrektur für den aktuellen Zeitschritt
        FunkTemp = Ftemp(TempBat)
        U0_E = Uent(SOC) - (Uent(1) - Uent(0)) * 1.1 * (1 - FunkTemp)
        Ri_T = RiTemp(TempBat)
        Ubat = U0_E + Ibat * Ri_T
    End Sub

    'Batterie laden
    Private Sub Bat_Lad(ByVal Perf As Single)
        Dim FunkTemp As Single  ' Temp-Funktion für Ri(Temp)
        Dim U0_L As Single      ' Ubatt(SOC(T), Ibatt=0), Entladekurve
        Dim Ri_T As Single      ' Ri bei Temperatur T, lokal


        'Temperaturfunktion
        FunkTemp = Ftemp(LastTempBat)

        'Ri bestimmen abhängig von Temperatur
        Ri_T = RiTemp(LastTempBat)

        'Spannung bestimmen aus SOC und Spannungskurve
        U0_L = Ulad(LastSOC) - (Ulad(1) - Ulad(0)) * 1.1 * (1 - FunkTemp)

        'Strom berechnen
        Ibat = +U0_L / 2 / Ri_T - Math.Sqrt((U0_L / 2 / Ri_T) ^ 2 - Perf * 1000 / Ri_T)

        'Batterieverluste
        PbatV = Ibat ^ 2 * Ri_T / 1000.0

        'Batterietemperatur
        TempBat = LastTempBat + PbatV * 1000.0 * 1.0 / CP / MB
        If TempBat >= T_MAX Then
            TempBat = T_MAX
        End If

        'SOC berechnen
        SOC = LastSOC + Ibat * 1.0 / (SOC_Kap * 3600)

        'Korrektur für den aktuellen Zeitschritt
        FunkTemp = Ftemp(TempBat)
        U0_L = Ulad(SOC) - (Ulad(1) - Ulad(0)) * 1.1 * (1 - FunkTemp)
        Ri_T = RiTemp(TempBat)
        Ubat = U0_L + Ibat * Ri_T
    End Sub

    'Batterie nix tun
    Private Sub Bat_Nix()
        'Dim SocProz As Single   ' lokal, SOC in Prozent
        'Dim FunkTemp As Single  ' Temp-Funktion für Ri(Temp)
        'Dim U0_L As Single      ' Ubatt(SOC(T), Ibatt=0), Entladekurve
        'Dim Ri_T As Single      ' Ri bei Temperatur T, lokal

        Ibat = 0.0
        PbatV = 0.0
        TempBat = LastTempBat
        SOC = LastSOC
        ' ALT: Ubat(jz) = Ubat(jz - 1)
    End Sub


    'Übergibt PeBat beim Laden mit PEmot (Vorzeichen nach Renhart)
    Private Function fPbatLad(ByVal PEmot As Single) As Single
        Dim FunkTemp As Single
        Dim U0_L As Single
        Dim Ri_T As Single
        Dim Ibat0 As Single
        Dim PbatV0 As Single

        Ri_T = RiTemp(LastTempBat)
        FunkTemp = Ftemp(LastTempBat)
        U0_L = Ulad(LastSOC) - (Ulad(1) - Ulad(0)) * 1.1 * (1 - FunkTemp)

        If (PEmot * 1000 / Ri_T) > (U0_L / 2 / Ri_T) ^ 2 Then
            Return 0
        Else
            Ibat0 = U0_L / 2 / Ri_T - Math.Sqrt((U0_L / 2 / Ri_T) ^ 2 - PEmot * 1000 / Ri_T)
            PbatV0 = Ibat0 ^ 2 * Ri_T / 1000.0
            Return PEmot + PbatV0
        End If

    End Function

    'Übergibt PeBat beim Entladen mit PEmot (Vorzeichen nach Renhart)
    Private Function fPbatEnt(ByVal PEmot As Single) As Single
        Dim FunkTemp As Single
        Dim U0_E As Single
        Dim Ri_T As Single
        Dim Ibat0 As Single
        Dim PbatV0 As Single

        Ri_T = RiTemp(LastTempBat)
        FunkTemp = Ftemp(LastTempBat)
        U0_E = Uent(LastSOC) - (Uent(1) - Uent(0)) * 1.1 * (1 - FunkTemp)

        Ibat0 = -U0_E / 2 / Ri_T + Math.Sqrt((U0_E / 2 / Ri_T) ^ 2 + PEmot * 1000 / Ri_T)
        PbatV0 = Ibat0 ^ 2 * Ri_T / 1000.0

        Return PEmot - PbatV0

    End Function

    Private Function Uent(ByVal Socf As Single) As Single
        Uent = (a0 + a1 * Socf + a2 * Socf ^ 2 + a3 * Socf ^ 3 + a4 * Socf ^ 4 + a5 * Socf ^ 5 + a6 * Socf ^ 6) * NCELLS
    End Function
    Private Function Ulad(ByVal Socf As Single) As Single
        Ulad = (b0 + b1 * Socf + b2 * Socf ^ 2 + b3 * Socf ^ 3 + b4 * Socf ^ 4 + b5 * Socf ^ 5 + b6 * Socf ^ 6) * NCELLS
    End Function
    Private Function Ftemp(ByVal Tempf As Single) As Single
        Ftemp = c0 + c1 * Tempf + c2 * Tempf ^ 2 + c3 * Tempf ^ 3 + c4 * Tempf ^ 4
    End Function
    Private Function RiTemp(ByVal Ri_T As Single) As Single
        RiTemp = RI_20 * (2.0 - (d0 + d1 * Ri_T + d2 * Ri_T ^ 2))
    End Function







End Class