Exemple #1
0
def Static_Analysis(
        InputMethod=opem.Functions.Get_Input,
        TestMode=False,
        PrintMode=True,
        ReportMode=True):
    """
    Run Larminie-Dicks static analysis.

    :param InputMethod : input function or input test vector
    :param TestMode : test mode flag
    :type InputMethod : dict or Get_Input function object
    :type TestMode:bool
    :param PrintMode : print mode control flag (True : print outputs)
    :type PrintMode:bool
    :param ReportMode : report mode control flag (True : generate report)
    :type ReportMode: bool
    :return: Result as dict
    """
    OutputFile = None
    CSVFile = None
    Warning1 = False
    Warning2 = False
    I_Warning = 0
    Overall_Params_Max = {}
    Overall_Params_Linear = {}
    Simulation_Title = "Larminie-Dicks"
    try:

        if PrintMode:
            print("###########")
            print(Simulation_Title + "-Model Simulation")
            print("###########")
        OutputParamsKeys = sorted(OutputParams.keys())
        Output_Dict = dict(
            zip(OutputParamsKeys, [None] * len(OutputParamsKeys)))
        if not TestMode:
            Input_Dict = InputMethod(InputParams)
        else:
            Input_Dict = InputMethod
        if PrintMode:
            print("Analyzing . . .")
        Input_Dict = opem.Functions.filter_alpha(Input_Dict)
        Name = Input_Dict["Name"]
        if ReportMode:
            OutputFile = opem.Functions.Output_Init(
                Input_Dict, Simulation_Title, Name)
            CSVFile = opem.Functions.CSV_Init(
                OutputParamsKeys,
                OutputParams,
                Simulation_Title,
                Name)
            HTMLFile = opem.Functions.HTML_Init(Simulation_Title, Name)
        IEnd = Input_Dict["i-stop"]
        IStep = Input_Dict["i-step"]
        Precision = opem.Functions.get_precision(IStep)
        [i, IEnd, IStep] = opem.Functions.filter_range(
            Input_Dict["i-start"], IEnd, IStep)
        I_List = []
        Efficiency_List = []
        Power_List = []
        Vstack_List = []
        Power_Thermal_List = []
        B = B_Calc(Input_Dict["T"])
        while i < IEnd:
            try:
                I_List.append(i)
                Output_Dict["Vcell"] = Vcell_Calc(
                    E0=Input_Dict["E0"],
                    i=i,
                    i_0=Input_Dict["i_0"],
                    i_n=Input_Dict["i_n"],
                    i_L=Input_Dict["i_L"],
                    R_M=Input_Dict["RM"],
                    B=B,
                    A=Input_Dict["A"])
                [Warning1, I_Warning] = opem.Functions.warning_check_1(
                    Output_Dict["Vcell"], I_Warning, i, Warning1)
                Output_Dict["PEM Efficiency"] = Efficiency_Calc(
                    Output_Dict["Vcell"])
                Output_Dict["Power"] = Power_Calc(Output_Dict["Vcell"], i)
                Output_Dict["VStack"] = VStack_Calc(
                    Input_Dict["N"], Output_Dict["Vcell"])
                Output_Dict["Power-Stack"] = PowerStack_Calc(
                    Output_Dict["Power"], Input_Dict["N"])
                Output_Dict["Power-Thermal"] = Power_Thermal_Calc(
                    VStack=Output_Dict["VStack"], N=Input_Dict["N"], i=i)
                Vstack_List.append(Output_Dict["VStack"])
                Efficiency_List.append(Output_Dict["PEM Efficiency"])
                Power_List.append(Output_Dict["Power-Stack"])
                Power_Thermal_List.append(Output_Dict["Power-Thermal"])
                if ReportMode:
                    opem.Functions.Output_Save(
                        OutputParamsKeys,
                        Output_Dict,
                        OutputParams,
                        i,
                        OutputFile,
                        PrintMode)
                    opem.Functions.CSV_Save(
                        OutputParamsKeys, Output_Dict, i, CSVFile)
                i = opem.Functions.rounder(i + IStep, Precision)
            except Exception as e:
                print(e)
                i = opem.Functions.rounder(i + IStep, Precision)
                if ReportMode:
                    opem.Functions.Output_Save(
                        OutputParamsKeys,
                        Output_Dict,
                        OutputParams,
                        i,
                        OutputFile,
                        PrintMode)
                    opem.Functions.CSV_Save(
                        OutputParamsKeys, Output_Dict, i, CSVFile)
        [Estimated_V, B0, B1] = opem.Functions.linear_plot(
            x=I_List, y=Vstack_List)
        Linear_Approx_Params = Linear_Aprox_Params_Calc(B0, B1)
        Max_Params = Max_Params_Calc(Power_List, Efficiency_List, Vstack_List)
        Power_Total = Power_Total_Calc(Vstack_List, IStep, Input_Dict["N"])
        Overall_Params_Linear["Pmax(L-Approx)"] = Linear_Approx_Params[0]
        Overall_Params_Linear["V0"] = B0
        Overall_Params_Linear["K"] = B1
        Overall_Params_Linear["VFC|Pmax(L-Approx)"] = Linear_Approx_Params[1]

        Overall_Params_Max["Pmax"] = Max_Params["Max_Power"]
        Overall_Params_Max["VFC|Pmax"] = Max_Params["Max_VStack"]
        Overall_Params_Max["Efficiency|Pmax"] = Max_Params["Max_EFF"]
        Overall_Params_Max["Ptotal(Elec)"] = Power_Total[0]
        Overall_Params_Max["Ptotal(Thermal)"] = Power_Total[1]
        if ReportMode:
            OutputFile.close()
            CSVFile.close()
            if PrintMode:
                print(Report_Message)
            opem.Functions.HTML_Desc(
                Simulation_Title, Larminiee_Description, HTMLFile)
            opem.Functions.HTML_Input_Table(
                Input_Dict=Input_Dict,
                Input_Params=InputParams,
                file=HTMLFile)
            opem.Functions.HTML_Overall_Params_Table(
                Overall_Params_Max,
                Overall_Params_Max_Description,
                file=HTMLFile,
                header=True)
            opem.Functions.HTML_Chart(
                x=str(I_List),
                y=str(Power_List),
                color='rgba(255,99,132,1)',
                x_label="I(A)",
                y_label="P(W)",
                chart_name="Power-Stack",
                size="600px",
                file=HTMLFile)
            opem.Functions.HTML_Chart(
                x=str(I_List), y=[
                    str(Vstack_List), str(Estimated_V)], color=[
                    'rgba(99,100,255,1)', 'rgb(238, 210, 141)'], x_label="I(A)", y_label="V(V)", chart_name=[
                    "Voltage-Stack", "Linear-Apx"], size="600px", file=HTMLFile)
            opem.Functions.HTML_Overall_Params_Table(
                Overall_Params_Linear,
                Overall_Params_Linear_Description,
                file=HTMLFile,
                header=False)
            opem.Functions.HTML_Chart(
                x=str(I_List),
                y=str(Efficiency_List),
                color='rgb(255, 0, 255)',
                x_label="I(A)",
                y_label="EFF",
                chart_name="Efficiency",
                size="600px",
                file=HTMLFile)
            opem.Functions.HTML_Chart(x=str(list(map(opem.Functions.rounder,
                                                     Power_List))),
                                      y=str(Efficiency_List),
                                      color='rgb(238, 210, 141)',
                                      x_label="P(W)",
                                      y_label="EFF",
                                      chart_name="Efficiency vs Power",
                                      size="600px",
                                      file=HTMLFile)
            opem.Functions.HTML_Chart(
                x=str(I_List),
                y=str(Power_Thermal_List),
                color='rgb(255, 0, 255)',
                x_label="I(A)",
                y_label="P(W)",
                chart_name="Power(Thermal)",
                size="600px",
                file=HTMLFile)
            opem.Functions.warning_print(
                warning_flag_1=Warning1,
                warning_flag_2=Warning2,
                I_Warning=I_Warning,
                file=HTMLFile,
                PrintMode=PrintMode)
            opem.Functions.HTML_End(HTMLFile)
            HTMLFile.close()
        if PrintMode:
            print("Done!")
        if not TestMode:
            if PrintMode:
                print(
                    "Result In -->" +
                    os.path.join(
                        os.getcwd(),
                        Simulation_Title))
        else:
            return {
                "Status": True,
                "P": Power_List,
                "I": I_List,
                "V": Vstack_List,
                "EFF": Efficiency_List,
                "Ph": Power_Thermal_List,
                "V0": B0,
                "K": B1,
                "VE": Estimated_V}
    except Exception:
        if TestMode:
            return {
                "Status": False,
                "Message": "[Error] " +
                Simulation_Title +
                " Simulation Failed!(Check Your Inputs)"}
        print(
            "[Error] " +
            Simulation_Title +
            " Simulation Failed!(Check Your Inputs)")
Exemple #2
0
def Dynamic_Analysis(InputMethod=Get_Input, TestMode=False,PrintMode=True, ReportMode=True):
    """
    This function run Padulles I analysis  with calling other functions
    :param InputMethod : Input Function Or Input Test Vector
    :param TestMode : Test Mode Flag
    :type InputMethod : dict or Get_Input function object
    :type TestMode:bool
    :param PrintMode : Print Mode Control Flag (True : Print Outputs)
    :type PrintMode:bool
    :param ReportMode : Report Mode Control Flag (True : Generate Report)
    :type ReportMode: bool
    :return: Result as dict
    """
    OutputFile = None
    CSVFile = None
    try:
        Simulation_Title="Padulles-II"
        if PrintMode==True:
            print("###########")
            print(Simulation_Title+"-Model Simulation")
            print("###########")
        OutputParamsKeys = list(OutputParams.keys())
        OutputParamsKeys.sort()
        Output_Dict = dict(zip(OutputParamsKeys, [None] * len(OutputParamsKeys)))
        if not TestMode:
            Input_Dict = InputMethod(InputParams)
        else:
            Input_Dict = InputMethod
        if PrintMode==True:
            print("Analyzing . . .")
        Name = Input_Dict["Name"]
        if ReportMode==True:
            OutputFile = Output_Init(Input_Dict,Simulation_Title,Name)
            CSVFile = CSV_Init(OutputParamsKeys,OutputParams,Simulation_Title,Name)
            HTMLFile = HTML_Init(Simulation_Title, Name)
        IEnd = Input_Dict["i-stop"]
        IStep = Input_Dict["i-step"]
        Precision = get_precision(IStep)
        i = Input_Dict["i-start"]
        I_List = []
        Power_List = []
        Vstack_List = []
        Kr=Kr_Calc(Input_Dict["N0"])
        qO2=qO2_Calc(Input_Dict["qH2"],Input_Dict["rho"])
        qH2O=Input_Dict["qH2"]
        while i < IEnd:
            try:
                I_List.append(i)
                Output_Dict["PO2"]=PO2_Calc(Input_Dict["KO2"],Input_Dict["tO2"],Kr,i,qO2)
                Output_Dict["PH2"]=PH2_Calc(Input_Dict["KH2"],Input_Dict["tH2"],Kr,i,Input_Dict["qH2"])
                Output_Dict["PH2O"]=PH2O_Calc(Input_Dict["KH2O"],Input_Dict["tH2O"],Kr,i,qH2O)
                Output_Dict["E"]=Enernst_Calc(Input_Dict["E0"],Input_Dict["N0"],Input_Dict["T"],Output_Dict["PH2"],Output_Dict["PO2"],Output_Dict["PH2O"])
                Output_Dict["FC Voltage"]=Vcell_Calc(Output_Dict["E"],Input_Dict["B"],Input_Dict["C"],i,Input_Dict["Rint"])
                Vstack_List.append(Output_Dict["FC Voltage"])
                Output_Dict["FC Efficiency"] = Efficiency_Calc(Output_Dict["FC Voltage"],Input_Dict["N0"])
                Output_Dict["FC Power"] = Power_Calc(Output_Dict["FC Voltage"], i)
                Power_List.append(Output_Dict["FC Power"])
                if ReportMode==True:
                    Output_Save(OutputParamsKeys, Output_Dict,OutputParams, i, OutputFile,PrintMode)
                    CSV_Save(OutputParamsKeys, Output_Dict, i, CSVFile)
                i = rounder(i + IStep, Precision)
            except Exception as e:
                print(str(e))
                i = rounder(i + IStep, Precision)
                if ReportMode==True:
                    Output_Save(OutputParamsKeys, Output_Dict, OutputParams, i, OutputFile,PrintMode)
                    CSV_Save(OutputParamsKeys, Output_Dict, i, CSVFile)
        if ReportMode==True:
            HTML_Chart(x=str(I_List), y=str(Power_List), color='rgba(255,99,132,1)', x_label="I(A)", y_label="P(W)",
                    chart_name="FC-Power", size="600px", file=HTMLFile)
            HTML_Chart(x=str(I_List), y=str(Vstack_List), color='rgba(99,100,255,1)', x_label="I(A)", y_label="V(V)",
                    chart_name="FC-Voltage", size="600px", file=HTMLFile)
            HTML_Input_Table(Input_Dict=Input_Dict, Input_Params=InputParams, file=HTMLFile)
            HTML_End(HTMLFile)
            OutputFile.close()
            CSVFile.close()
            HTMLFile.close()
        if PrintMode==True:
            print("Done!")
        if not TestMode:
            if PrintMode==True:
                print("Result In -->" + os.path.join(os.getcwd(),Simulation_Title))
        else:
            return {"P": Power_List, "I": I_List, "V": Vstack_List}
    except Exception:
        print("[Error] Dynamic Simulation Failed!(Check Your Inputs)")
def Dynamic_Analysis(InputMethod=opem.Functions.Get_Input,
                     TestMode=False,
                     PrintMode=True,
                     ReportMode=True):
    """
    Run Padulles-Amphlett analysis.

    :param InputMethod : input function or input test vector
    :param TestMode : test mode flag
    :type InputMethod : dict or Get_Input function object
    :type TestMode:bool
    :param PrintMode : print mode control flag (True : print outputs)
    :type PrintMode:bool
    :param ReportMode : report mode control flag (True : generate report)
    :type ReportMode: bool
    :return: result as dict
    """
    OutputFile = None
    CSVFile = None
    Warning1 = False
    Warning2 = False
    I_Warning = 0
    Overall_Params_Max = {}
    Overall_Params_Linear = {}
    Simulation_Title = "Padulles-Amphlett"
    try:

        if PrintMode:
            print("###########")
            print(Simulation_Title + "-Model Simulation")
            print("###########")
        OutputParamsKeys = sorted(OutputParams.keys())
        Output_Dict = dict(
            zip(OutputParamsKeys, [None] * len(OutputParamsKeys)))
        if not TestMode:
            Input_Dict = InputMethod(InputParams, params_default=Defaults)
        else:
            Input_Dict = InputMethod
            Input_Dict = opem.Functions.filter_default(input_dict=Input_Dict,
                                                       params_default=Defaults)
        Input_Dict = opem.Functions.filter_lambda(Input_Dict)
        if PrintMode:
            print("Analyzing . . .")
        Name = Input_Dict["Name"]
        if ReportMode:
            OutputFile = opem.Functions.Output_Init(Input_Dict,
                                                    Simulation_Title, Name)
            CSVFile = opem.Functions.CSV_Init(OutputParamsKeys, OutputParams,
                                              Simulation_Title, Name)
            HTMLFile = opem.Functions.HTML_Init(Simulation_Title, Name)
        IEndMax = Input_Dict["JMax"] * Input_Dict["A"]
        IEnd = min(IEndMax, Input_Dict["i-stop"])
        IEnd = Input_Dict["i-stop"]
        IStep = Input_Dict["i-step"]
        Precision = opem.Functions.get_precision(IStep)
        [i, IEnd, IStep] = opem.Functions.filter_range(Input_Dict["i-start"],
                                                       IEnd, IStep)
        I_List = []
        Power_List = []
        Vstack_List = []
        Efficiency_List = []
        PH2_List = []
        PO2_List = []
        PH2O_List = []
        Eta_Ohmic_List = []
        Eta_Conc_List = []
        Eta_Active_List = []
        Power_Thermal_List = []
        Kr = Kr_Calc(Input_Dict["N0"])
        qH2 = qH2_Calc(Input_Dict["qMethanol"], Input_Dict["CV"],
                       Input_Dict["t1"], Input_Dict["t2"])
        qO2 = qO2_Calc(qH2, Input_Dict["rho"])
        while i < IEnd:
            try:
                I_List.append(i)
                Output_Dict["PO2"] = PO2_Calc(Input_Dict["KO2"],
                                              Input_Dict["tO2"], Kr, i, qO2)
                Output_Dict["PH2"] = PH2_Calc(Input_Dict["KH2"],
                                              Input_Dict["tH2"], Kr, i, qH2)
                PH2_List.append(Output_Dict["PH2"])
                PO2_List.append(Output_Dict["PO2"])
                Output_Dict["Eta Activation"] = Eta_Act_Calc(
                    Input_Dict["T"], Output_Dict["PO2"], Output_Dict["PH2"], i,
                    Input_Dict["A"])
                Eta_Active_List.append(Output_Dict["Eta Activation"])
                Output_Dict["Eta Ohmic"] = Eta_Ohmic_Calc(
                    i,
                    Input_Dict["l"],
                    Input_Dict["A"],
                    Input_Dict["T"],
                    Input_Dict["lambda"],
                    R_elec=Input_Dict["R"])
                Eta_Ohmic_List.append(Output_Dict["Eta Ohmic"])
                Output_Dict["Eta Concentration"] = Eta_Conc_Calc(
                    i, Input_Dict["A"], Input_Dict["B"], Input_Dict["JMax"])
                Eta_Conc_List.append(Output_Dict["Eta Concentration"])
                Output_Dict["Loss"] = Loss_Calc(
                    Output_Dict["Eta Activation"], Output_Dict["Eta Ohmic"],
                    Output_Dict["Eta Concentration"])
                Output_Dict["PH2O"] = PH2O_Calc(Input_Dict["KH2O"],
                                                Input_Dict["tH2O"], Kr, i, qH2)
                PH2O_List.append(Output_Dict["PH2O"])
                Output_Dict["E"] = Enernst_Calc(Input_Dict["E0"],
                                                Input_Dict["N0"],
                                                Input_Dict["T"],
                                                Output_Dict["PH2"],
                                                Output_Dict["PO2"],
                                                Output_Dict["PH2O"])
                Output_Dict["FC Voltage"] = Vcell_Calc(Output_Dict["E"],
                                                       Output_Dict["Loss"],
                                                       Input_Dict["N0"])
                [Warning1, I_Warning
                 ] = opem.Functions.warning_check_1(Output_Dict["FC Voltage"],
                                                    I_Warning, i, Warning1)
                Warning2 = opem.Functions.warning_check_2(
                    Vcell=Output_Dict["FC Voltage"], warning_flag=Warning2)
                Vstack_List.append(Output_Dict["FC Voltage"])
                Output_Dict["FC Efficiency"] = Efficiency_Calc(
                    Output_Dict["FC Voltage"], Input_Dict["N0"])
                Efficiency_List.append(Output_Dict["FC Efficiency"])
                Output_Dict["FC Power"] = Power_Calc(Output_Dict["FC Voltage"],
                                                     i)
                Output_Dict["Power-Thermal"] = Power_Thermal_Calc(
                    VStack=Output_Dict["FC Voltage"], N=Input_Dict["N0"], i=i)
                Power_List.append(Output_Dict["FC Power"])
                Power_Thermal_List.append(Output_Dict["Power-Thermal"])
                if ReportMode:
                    opem.Functions.Output_Save(OutputParamsKeys, Output_Dict,
                                               OutputParams, i, OutputFile,
                                               PrintMode)
                    opem.Functions.CSV_Save(OutputParamsKeys, Output_Dict, i,
                                            CSVFile)
                i = opem.Functions.rounder(i + IStep, Precision)
            except Exception as e:
                print(str(e))
                i = opem.Functions.rounder(i + IStep, Precision)
                if ReportMode:
                    opem.Functions.Output_Save(OutputParamsKeys, Output_Dict,
                                               OutputParams, i, OutputFile,
                                               PrintMode)
                    opem.Functions.CSV_Save(OutputParamsKeys, Output_Dict, i,
                                            CSVFile)
        [Estimated_V, B0, B1] = opem.Functions.linear_plot(x=I_List,
                                                           y=Vstack_List)
        Linear_Approx_Params = Linear_Aprox_Params_Calc(B0, B1)
        Max_Params = Max_Params_Calc(Power_List, Efficiency_List, Vstack_List)
        Power_Total = Power_Total_Calc(Vstack_List, IStep, Input_Dict["N0"])
        Overall_Params_Linear["Pmax(L-Approx)"] = Linear_Approx_Params[0]
        Overall_Params_Linear["V0"] = B0
        Overall_Params_Linear["K"] = B1
        Overall_Params_Linear["VFC|Pmax(L-Approx)"] = Linear_Approx_Params[1]

        Overall_Params_Max["Pmax"] = Max_Params["Max_Power"]
        Overall_Params_Max["VFC|Pmax"] = Max_Params["Max_VStack"]
        Overall_Params_Max["Efficiency|Pmax"] = Max_Params["Max_EFF"]
        Overall_Params_Max["Ptotal(Elec)"] = Power_Total[0]
        Overall_Params_Max["Ptotal(Thermal)"] = Power_Total[1]
        if ReportMode:
            OutputFile.close()
            CSVFile.close()
            if PrintMode:
                print(Report_Message)
            opem.Functions.HTML_Desc(Simulation_Title,
                                     Padulles_Amphlett_Description, HTMLFile)
            opem.Functions.HTML_Input_Table(Input_Dict=Input_Dict,
                                            Input_Params=InputParams,
                                            file=HTMLFile)
            opem.Functions.HTML_Overall_Params_Table(
                Overall_Params_Max,
                Overall_Params_Max_Description,
                file=HTMLFile,
                header=True)
            opem.Functions.HTML_Chart(x=str(I_List),
                                      y=str(Power_List),
                                      color='rgba(255,99,132,1)',
                                      x_label="I(A)",
                                      y_label="P(W)",
                                      chart_name="FC-Power",
                                      size="600px",
                                      file=HTMLFile)
            opem.Functions.HTML_Chart(
                x=str(I_List),
                y=[str(Vstack_List), str(Estimated_V)],
                color=['rgba(99,100,255,1)', 'rgb(238, 210, 141)'],
                x_label="I(A)",
                y_label="V(V)",
                chart_name=["FC-Voltage", "Linear-Apx"],
                size="600px",
                file=HTMLFile)
            opem.Functions.HTML_Overall_Params_Table(
                Overall_Params_Linear,
                Overall_Params_Linear_Description,
                file=HTMLFile,
                header=False)
            opem.Functions.HTML_Chart(
                x=str(I_List),
                y=[
                    str(Eta_Active_List),
                    str(Eta_Conc_List),
                    str(Eta_Ohmic_List)
                ],
                color=[
                    'rgba(255,99,132,1)', 'rgba(99,100,255,1)',
                    'rgb(238, 210, 141)'
                ],
                x_label="I(A)",
                y_label="V(V)",
                chart_name=["Eta Active", "Eta Conc", "Eta Ohmic"],
                size="600px",
                file=HTMLFile)
            opem.Functions.HTML_Chart(x=str(I_List),
                                      y=str(Efficiency_List),
                                      color='rgb(255, 0, 255)',
                                      x_label="I(A)",
                                      y_label="EFF",
                                      chart_name="Efficiency",
                                      size="600px",
                                      file=HTMLFile)
            opem.Functions.HTML_Chart(x=str(I_List),
                                      y=str(PO2_List),
                                      color='	rgb(0, 255, 128)',
                                      x_label="I(A)",
                                      y_label="PO2(atm)",
                                      chart_name="PO2",
                                      size="600px",
                                      file=HTMLFile)
            opem.Functions.HTML_Chart(x=str(I_List),
                                      y=str(PH2_List),
                                      color='	rgb(128, 0, 255)',
                                      x_label="I(A)",
                                      y_label="PH2(atm)",
                                      chart_name="PH2",
                                      size="600px",
                                      file=HTMLFile)
            opem.Functions.HTML_Chart(x=str(I_List),
                                      y=str(PH2O_List),
                                      color='	rgb(165, 185, 112)',
                                      x_label="I(A)",
                                      y_label="PH2O(atm)",
                                      chart_name="PH2O",
                                      size="600px",
                                      file=HTMLFile)
            opem.Functions.HTML_Chart(x=str(
                list(map(opem.Functions.rounder, Power_List))),
                                      y=str(Efficiency_List),
                                      color='rgb(238, 210, 141)',
                                      x_label="P(W)",
                                      y_label="EFF",
                                      chart_name="Efficiency vs Power",
                                      size="600px",
                                      file=HTMLFile)
            opem.Functions.HTML_Chart(x=str(I_List),
                                      y=str(Power_Thermal_List),
                                      color='rgb(255, 0, 255)',
                                      x_label="I(A)",
                                      y_label="P(W)",
                                      chart_name="Power(Thermal)",
                                      size="600px",
                                      file=HTMLFile)
            opem.Functions.warning_print(warning_flag_1=Warning1,
                                         warning_flag_2=Warning2,
                                         I_Warning=I_Warning,
                                         file=HTMLFile,
                                         PrintMode=PrintMode)
            opem.Functions.HTML_End(HTMLFile)
            HTMLFile.close()
        if PrintMode:
            print("Done!")
        if not TestMode:
            if PrintMode:
                print("Result In -->" +
                      os.path.join(os.getcwd(), Simulation_Title))
        else:
            return {
                "Status": True,
                "P": Power_List,
                "I": I_List,
                "V": Vstack_List,
                "EFF": Efficiency_List,
                "PO2": PO2_List,
                "PH2": PH2_List,
                "PH2O": PH2O_List,
                "Ph": Power_Thermal_List,
                "V0": B0,
                "K": B1,
                "Eta_Active": Eta_Active_List,
                "Eta_Conc": Eta_Conc_List,
                "Eta_Ohmic": Eta_Ohmic_List,
                "VE": Estimated_V
            }
    except Exception:
        if TestMode:
            return {
                "Status":
                False,
                "Message":
                "[Error] " + Simulation_Title +
                " Simulation Failed!(Check Your Inputs)"
            }
        print("[Error] " + Simulation_Title +
              " Simulation Failed!(Check Your Inputs)")
Exemple #4
0
def Static_Analysis(InputMethod=Get_Input, TestMode=False, PrintMode=True, ReportMode=True):
    """
    This function run Larminie-Dicks static analysis with calling other functions
    :param InputMethod : Input Function Or Input Test Vector
    :param TestMode : Test Mode Flag
    :type InputMethod : dict or Get_Input function object
    :type TestMode:bool
    :param PrintMode : Print Mode Control Flag (True : Print Outputs)
    :type PrintMode:bool
    :param ReportMode : Report Mode Control Flag (True : Generate Report)
    :type ReportMode: bool
    :return: Result as dict
    """
    OutputFile = None
    CSVFile = None
    try:
        Simulation_Title="Larminie-Dicks"
        if PrintMode==True:
            print("###########")
            print(Simulation_Title+"-Model Simulation")
            print("###########")
        OutputParamsKeys = list(OutputParams.keys())
        OutputParamsKeys.sort()
        Output_Dict = dict(zip(OutputParamsKeys, [None] * len(OutputParamsKeys)))
        if not TestMode:
            Input_Dict = InputMethod(InputParams)
        else:
            Input_Dict = InputMethod
        if PrintMode==True:
            print("Analyzing . . .")
        Input_Dict=filter_alpha(Input_Dict)
        Name=Input_Dict["Name"]
        if ReportMode==True:
            OutputFile = Output_Init(Input_Dict,Simulation_Title,Name)
            CSVFile = CSV_Init(OutputParamsKeys,OutputParams,Simulation_Title,Name)
            HTMLFile = HTML_Init(Simulation_Title, Name)
        IEnd = Input_Dict["i-stop"]
        IStep = Input_Dict["i-step"]
        Precision = get_precision(IStep)
        i = Input_Dict["i-start"]
        I_List = []
        Power_List = []
        Vstack_List = []
        while i < IEnd:
            try:
                I_List.append(i)
                Output_Dict["Vcell"] = Vcell_Calc(E0=Input_Dict["E0"],i=i,i_0=Input_Dict["i_0"],i_n=Input_Dict["i_n"],
                                                  i_L=Input_Dict["i_L"],R_M=Input_Dict["RM"],B=Input_Dict["B"],A=Input_Dict["A"])
                Output_Dict["PEM Efficiency"] = Efficiency_Calc(Output_Dict["Vcell"])
                Output_Dict["Power"] = Power_Calc(Output_Dict["Vcell"], i)
                Output_Dict["VStack"] = VStack_Calc(Input_Dict["N"], Output_Dict["Vcell"])
                Output_Dict["Power-Stack"] = PowerStack_Calc(Output_Dict["Power"], Input_Dict["N"])
                Vstack_List.append(Output_Dict["VStack"])
                Power_List.append(Output_Dict["Power-Stack"])
                if ReportMode==True:
                    Output_Save(OutputParamsKeys, Output_Dict,OutputParams, i, OutputFile,PrintMode)
                    CSV_Save(OutputParamsKeys, Output_Dict, i, CSVFile)
                i = rounder(i + IStep, Precision)
            except Exception as e:
                print(e)
                i = rounder(i + IStep, Precision)
                if ReportMode==True:
                    Output_Save(OutputParamsKeys, Output_Dict, OutputParams, i, OutputFile,PrintMode)
                    CSV_Save(OutputParamsKeys, Output_Dict, i, CSVFile)
        if ReportMode==True:
            HTML_Chart(x=str(I_List), y=str(Power_List), color='rgba(255,99,132,1)', x_label="I(A)", y_label="P(W)",
                    chart_name="Power-Stack", size="600px", file=HTMLFile)
            HTML_Chart(x=str(I_List), y=str(Vstack_List), color='rgba(99,100,255,1)', x_label="I(A)", y_label="V(V)",
                    chart_name="Voltage-Stack", size="600px", file=HTMLFile)
            HTML_Input_Table(Input_Dict=Input_Dict, Input_Params=InputParams, file=HTMLFile)
            HTML_End(HTMLFile)
            OutputFile.close()
            CSVFile.close()
            HTMLFile.close()
        if PrintMode==True:
            print("Done!")
        if not TestMode:
            if PrintMode==True:
                print("Result In -->" + os.path.join(os.getcwd(), Simulation_Title))
        else:
            return {"P": Power_List, "I": I_List, "V": Vstack_List}
    except Exception:
        print("[Error] Larminiee Simulation Failed!(Check Your Inputs)")