Exemplo n.º 1
0
    def dropEvent(self, event):
        """
        Create an element
        @param event:
        @return:
        """
        if event.mimeData().hasFormat('component/name'):
            obj_type = event.mimeData().data('component/name')
            elm = None
            data = QByteArray()
            stream = QDataStream(data, QIODevice.WriteOnly)
            stream.writeQString('Bus')
            if obj_type == data:
                name = 'Bus ' + str(len(self.scene_.circuit.buses))

                obj = Bus(name=name,
                          area=self.scene_.circuit.areas[0],
                          zone=self.scene_.circuit.zones[0],
                          substation=self.scene_.circuit.substations[0],
                          country=self.scene_.circuit.countries[0])

                elm = BusGraphicItem(diagramScene=self.scene(), name=name, editor=self.editor, bus=obj)
                obj.graphic_obj = elm
                self.scene_.circuit.add_bus(obj)  # weird but it's the only way to have graphical-API communication

            if elm is not None:
                elm.setPos(self.mapToScene(event.pos()))
                self.scene_.addItem(elm)
Exemplo n.º 2
0
def test_demo_5_node(root_path=ROOT_PATH):
    np.core.arrayprint.set_printoptions(precision=4)

    grid = MultiCircuit()

    # Add buses
    bus1 = Bus('Bus 1', vnom=20)
    grid.add_bus(bus1)
    gen1 = Generator('Slack Generator', voltage_module=1.0)
    grid.add_generator(bus1, gen1)

    bus2 = Bus('Bus 2', vnom=20)
    grid.add_bus(bus2)
    grid.add_load(bus2, Load('load 2', P=40, Q=20))

    bus3 = Bus('Bus 3', vnom=20)
    grid.add_bus(bus3)
    grid.add_load(bus3, Load('load 3', P=25, Q=15))

    bus4 = Bus('Bus 4', vnom=20)
    grid.add_bus(bus4)
    grid.add_load(bus4, Load('load 4', P=40, Q=20))

    bus5 = Bus('Bus 5', vnom=20)
    grid.add_bus(bus5)
    grid.add_load(bus5, Load('load 5', P=50, Q=20))

    # add branches (Lines in this case)
    grid.add_line(Line(bus1, bus2, 'line 1-2', r=0.05, x=0.11, b=0.02))
    grid.add_line(Line(bus1, bus3, 'line 1-3', r=0.05, x=0.11, b=0.02))
    grid.add_line(Line(bus1, bus5, 'line 1-5', r=0.03, x=0.08, b=0.02))
    grid.add_line(Line(bus2, bus3, 'line 2-3', r=0.04, x=0.09, b=0.02))
    grid.add_line(Line(bus2, bus5, 'line 2-5', r=0.04, x=0.09, b=0.02))
    grid.add_line(Line(bus3, bus4, 'line 3-4', r=0.06, x=0.13, b=0.03))
    grid.add_line(Line(bus4, bus5, 'line 4-5', r=0.04, x=0.09, b=0.02))
    # grid.plot_graph()
    print('\n\n', grid.name)

    FileSave(grid, 'demo_5_node.json').save()

    options = PowerFlowOptions(SolverType.NR, verbose=False)

    power_flow = PowerFlowDriver(grid, options)
    power_flow.run()

    print_power_flow_results(power_flow=power_flow)
    v = np.array([1., 0.9553, 0.9548, 0.9334, 0.9534])
    all_ok = np.isclose(np.abs(power_flow.results.voltage), v, atol=1e-3)
    return all_ok
Exemplo n.º 3
0
def test_same_temp():
    B_C3 = Bus(name="B_C3", vnom=10)  # kV

    B_MV_M32 = Bus(name="B_MV_M32", vnom=10)  # kV

    cable = Branch(
        bus_from=B_C3,
        bus_to=B_MV_M32,
        name="C_M32",
        r=0.784,
        x=0.174,
        temp_base=20,  # °C
        temp_oper=20,  # °C
        alpha=0.00323)  # Copper

    assert cable.R_corrected == 0.784
Exemplo n.º 4
0
def test_demo_5_node(root_path):
    np.core.arrayprint.set_printoptions(precision=4)

    grid = MultiCircuit()

    # Add buses
    bus1 = Bus('Bus 1', vnom=20)
    # bus1.is_slack = True
    grid.add_bus(bus1)
    gen1 = Generator('Slack Generator', voltage_module=1.0)
    grid.add_generator(bus1, gen1)

    bus2 = Bus('Bus 2', vnom=20)
    grid.add_bus(bus2)
    grid.add_load(bus2, Load('load 2', P=40, Q=20))

    bus3 = Bus('Bus 3', vnom=20)
    grid.add_bus(bus3)
    grid.add_load(bus3, Load('load 3', P=25, Q=15))

    bus4 = Bus('Bus 4', vnom=20)
    grid.add_bus(bus4)
    grid.add_load(bus4, Load('load 4', P=40, Q=20))

    bus5 = Bus('Bus 5', vnom=20)
    grid.add_bus(bus5)
    grid.add_load(bus5, Load('load 5', P=50, Q=20))

    # add branches (Lines in this case)
    grid.add_branch(Branch(bus1, bus2, 'line 1-2', r=0.05, x=0.11, b=0.02))
    grid.add_branch(Branch(bus1, bus3, 'line 1-3', r=0.05, x=0.11, b=0.02))
    grid.add_branch(Branch(bus1, bus5, 'line 1-5', r=0.03, x=0.08, b=0.02))
    grid.add_branch(Branch(bus2, bus3, 'line 2-3', r=0.04, x=0.09, b=0.02))
    grid.add_branch(Branch(bus2, bus5, 'line 2-5', r=0.04, x=0.09, b=0.02))
    grid.add_branch(Branch(bus3, bus4, 'line 3-4', r=0.06, x=0.13, b=0.03))
    grid.add_branch(Branch(bus4, bus5, 'line 4-5', r=0.04, x=0.09, b=0.02))
    # grid.plot_graph()
    print('\n\n', grid.name)

    options = PowerFlowOptions(SolverType.NR, verbose=False)

    power_flow = PowerFlowDriver(grid, options)
    power_flow.run()

    print_power_flow_results(power_flow=power_flow)
Exemplo n.º 5
0
def test_line_losses_1():
    """
    Basic line losses test.
    """
    test_name = "test_line_losses_1"
    grid = MultiCircuit(name=test_name)
    Sbase = 100  # MVA
    grid.Sbase = Sbase
    grid.time_profile = None
    grid.logger = Logger()

    # Create buses
    Bus0 = Bus(name="Bus0", vnom=25, is_slack=True)
    Bus1 = Bus(name="Bus1", vnom=25)

    grid.add_bus(Bus0)
    grid.add_bus(Bus1)

    # Create load
    grid.add_load(Bus1, Load(name="Load0", P=1.0, Q=0.4))

    # Create slack bus
    grid.add_generator(Bus0, Generator(name="Utility"))

    # Create cable (r and x should be in pu)
    grid.add_branch(
        Line(bus_from=Bus0, bus_to=Bus1, name="Cable1", r=0.01, x=0.05))

    # Run non-linear load flow
    options = PowerFlowOptions(verbose=True)

    power_flow = PowerFlowDriver(grid, options)
    power_flow.run()

    # Check solution
    approx_losses = round(1000 * power_flow.results.losses[0], 3)
    solution = complex(0.116, 0.58)  # Expected solution from GridCal
    # Tested on ETAP 16.1.0 and pandapower

    print(
        "\n=================================================================")
    print(f"Test: {test_name}")
    print(
        "=================================================================\n")
    print(f"Results:  {approx_losses}")
    print(f"Solution: {solution}")
    print()

    print("Buses:")
    for i, b in enumerate(grid.buses):
        print(f" - bus[{i}]: {b}")
    print()

    print("Branches:")
    branches = grid.get_branches()
    for b in branches:
        print(f" - {b}:")
        print(f"   R = {round(b.R, 4)} pu")
        print(f"   X = {round(b.X, 4)} pu")
        print(f"   X/R = {round(b.X/b.R, 2)}")
    print()

    print("Voltages:")
    for i in range(len(grid.buses)):
        print(
            f" - {grid.buses[i]}: voltage={round(power_flow.results.voltage[i], 3)} pu"
        )
    print()

    print("Losses:")
    for i in range(len(branches)):
        print(
            f" - {branches[i]}: losses={round(power_flow.results.losses[i], 3)} MVA"
        )
    print()

    print("Loadings (power):")
    for i in range(len(branches)):
        print(
            f" - {branches[i]}: loading={round(power_flow.results.Sf[i], 3)} MVA"
        )
    print()

    print("Loadings (current):")
    for i in range(len(branches)):
        print(
            f" - {branches[i]}: loading={round(power_flow.results.If[i], 3)} pu"
        )
    print()

    assert approx_losses == solution
Exemplo n.º 6
0
def test_basic():
    """
    Basic GridCal test, also useful for a basic tutorial. In this case the
    magnetizing branch of the transformers is neglected by inputting 1e-20
    excitation current and iron core losses.
    The results are identical to ETAP's, which always uses this assumption in
    balanced load flow calculations.
    """
    test_name = "test_basic"
    grid = MultiCircuit(name=test_name)
    S_base = 100  # MVA
    grid.Sbase = S_base
    grid.time_profile = None
    grid.logger = list()

    # Create buses
    POI = Bus(
        name="POI",
        vnom=100,  #kV
        is_slack=True)
    grid.add_bus(POI)

    B_C3 = Bus(name="B_C3", vnom=10)  #kV
    grid.add_bus(B_C3)

    B_MV_M32 = Bus(name="B_MV_M32", vnom=10)  #kV
    grid.add_bus(B_MV_M32)

    B_LV_M32 = Bus(name="B_LV_M32", vnom=0.6)  #kV
    grid.add_bus(B_LV_M32)

    # Create voltage controlled generators (or slack, a.k.a. swing)
    UT = Generator(name="Utility")
    UT.bus = POI
    grid.add_generator(POI, UT)

    # Create static generators (with fixed power factor)
    M32 = StaticGenerator(
        name="M32",
        P=4.2,  # MW
        Q=0.0j)  # MVAR
    M32.bus = B_LV_M32
    grid.add_static_generator(B_LV_M32, M32)

    # Create transformer types
    s = 5  # MVA
    z = 8  # %
    xr = 40
    SS = TransformerType(
        name="SS",
        hv_nominal_voltage=100,  # kV
        lv_nominal_voltage=10,  # kV
        nominal_power=s,
        copper_losses=complex_impedance(z, xr).real * s * 1000 / S_base,
        iron_losses=1e-20,
        no_load_current=1e-20,
        short_circuit_voltage=z)
    grid.add_transformer_type(SS)

    s = 5  # MVA
    z = 6  # %
    xr = 20
    PM = TransformerType(
        name="PM",
        hv_nominal_voltage=10,  # kV
        lv_nominal_voltage=0.6,  # kV
        nominal_power=s,
        copper_losses=complex_impedance(z, xr).real * s * 1000 / S_base,
        iron_losses=1e-20,
        no_load_current=1e-20,
        short_circuit_voltage=z)
    grid.add_transformer_type(PM)

    # Create branches
    X_C3 = Branch(bus_from=POI,
                  bus_to=B_C3,
                  name="X_C3",
                  branch_type=BranchType.Transformer,
                  template=SS)
    grid.add_branch(X_C3)

    C_M32 = Branch(bus_from=B_C3,
                   bus_to=B_MV_M32,
                   name="C_M32",
                   r=0.784,
                   x=0.174)
    grid.add_branch(C_M32)

    X_M32 = Branch(bus_from=B_MV_M32,
                   bus_to=B_LV_M32,
                   name="X_M32",
                   branch_type=BranchType.Transformer,
                   template=PM)
    grid.add_branch(X_M32)

    # Apply templates (device types)
    grid.apply_all_branch_types()

    print("Buses:")
    for i, b in enumerate(grid.buses):
        print(f" - bus[{i}]: {b}")
    print()

    options = PowerFlowOptions(SolverType.LM,
                               verbose=True,
                               initialize_with_existing_solution=True,
                               multi_core=True,
                               control_q=ReactivePowerControlMode.Direct,
                               tolerance=1e-6,
                               max_iter=99)

    power_flow = PowerFlow(grid, options)
    power_flow.run()

    approx_volt = [round(100 * abs(v), 1) for v in power_flow.results.voltage]
    solution = [
        100.0, 99.6, 102.7, 102.9
    ]  # Expected solution from GridCal and ETAP 16.1.0, for reference

    print()
    print(f"Test: {test_name}")
    print(f"Results:  {approx_volt}")
    print(f"Solution: {solution}")
    print()

    print("Generators:")
    for g in grid.get_generators():
        print(f" - Generator {g}: q_min={g.Qmin}pu, q_max={g.Qmax}pu")
    print()

    print("Branches:")
    for b in grid.branches:
        print(f" - {b}:")
        print(f"   R = {round(b.R, 4)} pu")
        print(f"   X = {round(b.X, 4)} pu")
        print(f"   X/R = {round(b.X/b.R, 1)}")
        print(f"   G = {round(b.G, 4)} pu")
        print(f"   B = {round(b.B, 4)} pu")
    print()

    print("Transformer types:")
    for t in grid.transformer_types:
        print(
            f" - {t}: Copper losses={int(t.Pcu)}kW, Iron losses={int(t.Pfe)}kW, SC voltage={t.Vsc}%"
        )
    print()

    print("Losses:")
    for i in range(len(grid.branches)):
        print(
            f" - {grid.branches[i]}: losses={1000*round(power_flow.results.losses[i], 3)} kVA"
        )
    print()

    equal = True
    for i in range(len(approx_volt)):
        if approx_volt[i] != solution[i]:
            equal = False

    assert equal
def main():
    ####################################################################################################################
    # Define the circuit
    #
    # A circuit contains all the grid information regardless of the islands formed or the amount of devices
    ####################################################################################################################

    # create a circuit

    grid = MultiCircuit(name='lynn 5 bus')

    # let's create a master profile

    st = datetime.datetime(2020, 1, 1)
    dates = [st + datetime.timedelta(hours=i) for i in range(24)]
    time_array = pd.to_datetime(dates)
    x = np.linspace(-np.pi, np.pi, len(time_array))
    y = np.abs(np.sin(x))
    df_0 = pd.DataFrame(data=y, index=time_array)  # complex values

    # set the grid master time profile
    grid.time_profile = df_0.index

    ####################################################################################################################
    # Define the buses
    ####################################################################################################################
    # I will define this bus with all the properties so you see
    bus1 = Bus(name='Bus1',
               vnom=10,   # Nominal voltage in kV
               vmin=0.9,  # Bus minimum voltage in per unit
               vmax=1.1,  # Bus maximum voltage in per unit
               xpos=0,    # Bus x position in pixels
               ypos=0,    # Bus y position in pixels
               height=0,  # Bus height in pixels
               width=0,   # Bus width in pixels
               active=True,   # Is the bus active?
               is_slack=False,  # Is this bus a slack bus?
               area='Defualt',  # Area (for grouping purposes only)
               zone='Default',  # Zone (for grouping purposes only)
               substation='Default'  # Substation (for grouping purposes only)
               )

    # the rest of the buses are defined with the default parameters
    bus2 = Bus(name='Bus2')
    bus3 = Bus(name='Bus3')
    bus4 = Bus(name='Bus4')
    bus5 = Bus(name='Bus5')

    # add the bus objects to the circuit
    grid.add_bus(bus1)
    grid.add_bus(bus2)
    grid.add_bus(bus3)
    grid.add_bus(bus4)
    grid.add_bus(bus5)

    ####################################################################################################################
    # Add the loads
    ####################################################################################################################

    # In GridCal, the loads, generators ect are stored within each bus object:

    # we'll define the first load completely
    l2 = Load(name='Load',
              G=0, B=0,  # admittance of the ZIP model in MVA at the nominal voltage
              Ir=0, Ii=0,  # Current of the ZIP model in MVA at the nominal voltage
              P=40, Q=20,  # Power of the ZIP model in MVA
              active=True,  # Is active?
              mttf=0.0,  # Mean time to failure
              mttr=0.0  # Mean time to recovery
              )
    grid.add_load(bus2, l2)

    # Define the others with the default parameters
    grid.add_load(bus3, Load(P=25, Q=15))
    grid.add_load(bus4, Load(P=40, Q=20))
    grid.add_load(bus5, Load(P=50, Q=20))

    ####################################################################################################################
    # Add the generators
    ####################################################################################################################

    g1 = Generator(name='gen',
                   active_power=0.0,  # Active power in MW, since this generator is used to set the slack , is 0
                   voltage_module=1.0,  # Voltage set point to control
                   Qmin=-9999,  # minimum reactive power in MVAr
                   Qmax=9999,  # Maximum reactive power in MVAr
                   Snom=9999,  # Nominal power in MVA
                   power_prof=None,  # power profile
                   vset_prof=None,  # voltage set point profile
                   active=True  # Is active?
                   )
    grid.add_generator(bus1, g1)

    ####################################################################################################################
    # Add the lines
    ####################################################################################################################

    br1 = Branch(bus_from=bus1,
                 bus_to=bus2,
                 name='Line 1-2',
                 r=0.05,  # resistance of the pi model in per unit
                 x=0.11,  # reactance of the pi model in per unit
                 g=1e-20,  # conductance of the pi model in per unit
                 b=0.02,  # susceptance of the pi model in per unit
                 rate=50,  # Rate in MVA
                 tap=1.0,  # Tap value (value close to 1)
                 shift_angle=0,  # Tap angle in radians
                 active=True,  # is the branch active?
                 mttf=0,  # Mean time to failure
                 mttr=0,  # Mean time to recovery
                 branch_type=BranchType.Line,  # Branch type tag
                 length=1,  # Length in km (to be used with templates)
                 template=BranchTemplate()  # Branch template (The default one is void)
                 )
    grid.add_branch(br1)

    grid.add_branch(Branch(bus1, bus3, name='Line 1-3', r=0.05, x=0.11, b=0.02, rate=50))
    grid.add_branch(Branch(bus1, bus5, name='Line 1-5', r=0.03, x=0.08, b=0.02, rate=80))
    grid.add_branch(Branch(bus2, bus3, name='Line 2-3', r=0.04, x=0.09, b=0.02, rate=3))
    grid.add_branch(Branch(bus2, bus5, name='Line 2-5', r=0.04, x=0.09, b=0.02, rate=10))
    grid.add_branch(Branch(bus3, bus4, name='Line 3-4', r=0.06, x=0.13, b=0.03, rate=30))
    grid.add_branch(Branch(bus4, bus5, name='Line 4-5', r=0.04, x=0.09, b=0.02, rate=30))

    FileSave(grid, 'lynn5node.gridcal').save()

    ####################################################################################################################
    # Overwrite the default profiles with the custom ones
    ####################################################################################################################

    for load in grid.get_loads():
        load.P_prof = load.P * df_0.values[:, 0]
        load.Q_prof = load.Q * df_0.values[:, 0]

    for gen in grid.get_static_generators():
        gen.P_prof = gen.Q * df_0.values[:, 0]
        gen.Q_prof = gen.Q * df_0.values[:, 0]

    for gen in grid.get_generators():
        gen.P_prof = gen.P * df_0.values[:, 0]

    ####################################################################################################################
    # Run a power flow simulation
    ####################################################################################################################

    # We need to specify power flow options
    pf_options = PowerFlowOptions(solver_type=SolverType.NR,  # Base method to use
                                  verbose=False,  # Verbose option where available
                                  tolerance=1e-6,  # power error in p.u.
                                  max_iter=25,  # maximum iteration number
                                  control_q=True  # if to control the reactive power
                                  )

    # Declare and execute the power flow simulation
    pf = PowerFlowDriver(grid, pf_options)
    pf.run()

    writer = pd.ExcelWriter('Results.xlsx')
    # now, let's compose a nice DataFrame with the voltage results
    headers = ['Vm (p.u.)', 'Va (Deg)', 'Vre', 'Vim']
    Vm = np.abs(pf.results.voltage)
    Va = np.angle(pf.results.voltage, deg=True)
    Vre = pf.results.voltage.real
    Vim = pf.results.voltage.imag
    data = np.c_[Vm, Va, Vre, Vim]
    v_df = pd.DataFrame(data=data, columns=headers, index=grid.bus_names)
    # print('\n', v_df)
    v_df.to_excel(writer, sheet_name='V')

    # Let's do the same for the branch results
    headers = ['Loading (%)', 'Current(p.u.)', 'Power (MVA)']
    loading = np.abs(pf.results.loading) * 100
    current = np.abs(pf.results.If)
    power = np.abs(pf.results.Sf)
    data = np.c_[loading, current, power]
    br_df = pd.DataFrame(data=data, columns=headers, index=grid.branch_names)
    br_df.to_excel(writer, sheet_name='Br')

    # Finally the execution metrics
    print('\nError:', pf.results.error)
    print('Elapsed time (s):', pf.results.elapsed, '\n')

    # print(tabulate(v_df, tablefmt="pipe", headers=v_df.columns.values))
    # print()
    # print(tabulate(br_df, tablefmt="pipe", headers=br_df.columns.values))



    ####################################################################################################################
    # Run a time series power flow simulation
    ####################################################################################################################

    ts = TimeSeries(grid=grid,
                    options=pf_options,
                    opf_time_series_results=None,
                    start_=0,
                    end_=None)

    ts.run()

    print()
    print('-' * 200)
    print('Time series')
    print('-' * 200)
    print('Voltage time series')
    df_voltage = pd.DataFrame(data=np.abs(ts.results.voltage), columns=grid.bus_names, index=grid.time_profile)
    df_voltage.to_excel(writer, sheet_name='Vts')
    writer.close()
def test_xfo_static_tap_1():
    """
    Basic test with the main transformer's  HV tap (X_C3) set at +5% (1.05 pu),
    which lowers the LV by the same amount (-5%).
    """
    test_name = "test_xfo_static_tap_1"
    grid = MultiCircuit(name=test_name)
    grid.Sbase = Sbase
    grid.time_profile = None
    grid.logger = Logger()

    # Create buses
    POI = Bus(
        name="POI",
        vnom=100,  #kV
        is_slack=True)
    grid.add_bus(POI)

    B_C3 = Bus(name="B_C3", vnom=10)  #kV
    grid.add_bus(B_C3)

    B_MV_M32 = Bus(name="B_MV_M32", vnom=10)  #kV
    grid.add_bus(B_MV_M32)

    B_LV_M32 = Bus(name="B_LV_M32", vnom=0.6)  #kV
    grid.add_bus(B_LV_M32)

    # Create voltage controlled generators (or slack, a.k.a. swing)
    UT = Generator(name="Utility")
    UT.bus = POI
    grid.add_generator(POI, UT)

    # Create static generators (with fixed power factor)
    M32 = StaticGenerator(name="M32", P=4.2, Q=0.0)  # MVA (complex)
    M32.bus = B_LV_M32
    grid.add_static_generator(B_LV_M32, M32)

    # Create transformer types
    s = 5  # MVA
    z = 8  # %
    xr = 40
    SS = TransformerType(
        name="SS",
        hv_nominal_voltage=100,  # kV
        lv_nominal_voltage=10,  # kV
        nominal_power=s,
        copper_losses=complex_impedance(z, xr).real * s * 1000 / Sbase,
        iron_losses=6.25,  # kW
        no_load_current=0.5,  # %
        short_circuit_voltage=z)
    grid.add_transformer_type(SS)

    s = 5  # MVA
    z = 6  # %
    xr = 20
    PM = TransformerType(
        name="PM",
        hv_nominal_voltage=10,  # kV
        lv_nominal_voltage=0.6,  # kV
        nominal_power=s,
        copper_losses=complex_impedance(z, xr).real * s * 1000 / Sbase,
        iron_losses=6.25,  # kW
        no_load_current=0.5,  # %
        short_circuit_voltage=z)
    grid.add_transformer_type(PM)

    # Create branches
    X_C3 = Branch(bus_from=POI,
                  bus_to=B_C3,
                  name="X_C3",
                  branch_type=BranchType.Transformer,
                  template=SS,
                  tap=1.05)
    grid.add_branch(X_C3)

    C_M32 = Branch(bus_from=B_C3,
                   bus_to=B_MV_M32,
                   name="C_M32",
                   r=0.784,
                   x=0.174)
    grid.add_branch(C_M32)

    X_M32 = Branch(bus_from=B_MV_M32,
                   bus_to=B_LV_M32,
                   name="X_M32",
                   branch_type=BranchType.Transformer,
                   template=PM)
    grid.add_branch(X_M32)

    # Apply templates (device types)
    grid.apply_all_branch_types()

    print("Buses:")
    for i, b in enumerate(grid.buses):
        print(f" - bus[{i}]: {b}")
    print()

    options = PowerFlowOptions(SolverType.NR,
                               verbose=True,
                               initialize_with_existing_solution=True,
                               multi_core=True,
                               control_q=ReactivePowerControlMode.Direct,
                               tolerance=1e-6,
                               max_iter=99)

    power_flow = PowerFlowDriver(grid, options)
    power_flow.run()

    approx_volt = [round(100 * abs(v), 1) for v in power_flow.results.voltage]
    solution = [100.0, 94.7, 98.0, 98.1]  # Expected solution from GridCal

    print()
    print(f"Test: {test_name}")
    print(f"Results:  {approx_volt}")
    print(f"Solution: {solution}")
    print()

    print("Generators:")
    for g in grid.get_generators():
        print(f" - Generator {g}: q_min={g.Qmin} MVAR, q_max={g.Qmax} MVAR")
    print()

    print("Branches:")
    for b in grid.branches:
        print(f" - {b}:")
        print(f"   R = {round(b.R, 4)} pu")
        print(f"   X = {round(b.X, 4)} pu")
        print(f"   X/R = {round(b.X/b.R, 1)}")
        print(f"   G = {round(b.G, 4)} pu")
        print(f"   B = {round(b.B, 4)} pu")
    print()

    print("Transformer types:")
    for t in grid.transformer_types:
        print(
            f" - {t}: Copper losses={int(t.Pcu)}kW, Iron losses={int(t.Pfe)}kW, SC voltage={t.Vsc}%"
        )
    print()

    print("Losses:")
    for i in range(len(grid.branches)):
        print(
            f" - {grid.branches[i]}: losses={1000*round(power_flow.results.losses[i], 3)} kVA"
        )
    print()

    equal = True
    for i in range(len(approx_volt)):
        if approx_volt[i] != solution[i]:
            equal = False

    assert equal
def test_xfo_static_tap_3():
    """
    Basic test with the main transformer's  HV tap (X_C3) set at -2.5%
    (0.975 pu), which raises the LV by the same amount (+2.5%).
    """
    test_name = "test_xfo_static_tap_3"
    grid = MultiCircuit(name=test_name)
    grid.Sbase = Sbase
    grid.time_profile = None
    grid.logger = Logger()

    # Create buses
    POI = Bus(
        name="POI",
        vnom=100,  # kV
        is_slack=True)
    grid.add_bus(POI)

    B_C3 = Bus(name="B_C3", vnom=10)  # kV
    grid.add_bus(B_C3)

    B_MV_M32 = Bus(name="B_MV_M32", vnom=10)  # kV
    grid.add_bus(B_MV_M32)

    B_LV_M32 = Bus(name="B_LV_M32", vnom=0.6)  # kV
    grid.add_bus(B_LV_M32)

    # Create voltage controlled generators (or slack, a.k.a. swing)
    UT = Generator(name="Utility")
    UT.bus = POI
    grid.add_generator(POI, UT)

    # Create static generators (with fixed power factor)
    M32 = StaticGenerator(name="M32", P=4.2, Q=0.0)  # MVA (complex)
    M32.bus = B_LV_M32
    grid.add_static_generator(B_LV_M32, M32)

    # Create transformer types
    s = 5  # MVA
    z = 8  # %
    xr = 40
    SS = TransformerType(
        name="SS",
        hv_nominal_voltage=100,  # kV
        lv_nominal_voltage=10,  # kV
        nominal_power=s,
        copper_losses=complex_impedance(z, xr).real * s * 1000 / Sbase,
        iron_losses=6.25,  # kW
        no_load_current=0.5,  # %
        short_circuit_voltage=z)
    grid.add_transformer_type(SS)

    s = 5  # MVA
    z = 6  # %
    xr = 20
    PM = TransformerType(
        name="PM",
        hv_nominal_voltage=10,  # kV
        lv_nominal_voltage=0.6,  # kV
        nominal_power=s,
        copper_losses=complex_impedance(z, xr).real * s * 1000 / Sbase,
        iron_losses=6.25,  # kW
        no_load_current=0.5,  # %
        short_circuit_voltage=z)
    grid.add_transformer_type(PM)

    # Create branches
    X_C3 = Branch(bus_from=POI,
                  bus_to=B_C3,
                  name="X_C3",
                  branch_type=BranchType.Transformer,
                  template=SS,
                  tap=0.975)
    # update to a more precise tap changer
    X_C3.apply_tap_changer(
        TapChanger(taps_up=20, taps_down=20, max_reg=1.1, min_reg=0.9))
    grid.add_branch(X_C3)

    C_M32 = Branch(bus_from=B_C3,
                   bus_to=B_MV_M32,
                   name="C_M32",
                   r=0.784,
                   x=0.174)
    grid.add_branch(C_M32)

    X_M32 = Branch(bus_from=B_MV_M32,
                   bus_to=B_LV_M32,
                   name="X_M32",
                   branch_type=BranchType.Transformer,
                   template=PM)
    grid.add_branch(X_M32)

    # Apply templates (device types)
    grid.apply_all_branch_types()

    print("Buses:")
    for i, b in enumerate(grid.buses):
        print(f" - bus[{i}]: {b}")
    print()

    options = PowerFlowOptions(SolverType.NR,
                               verbose=True,
                               initialize_with_existing_solution=True,
                               multi_core=True,
                               control_q=ReactivePowerControlMode.Direct,
                               tolerance=1e-6,
                               max_iter=15)

    power_flow = PowerFlowDriver(grid, options)
    power_flow.run()

    print()
    print(f"Test: {test_name}")
    print()

    print("Generators:")
    for g in grid.get_generators():
        print(f" - Generator {g}: q_min={g.Qmin} MVAR, q_max={g.Qmax} MVAR")
    print()

    print("Branches:")
    for b in grid.branches:
        print(f" - {b}:")
        print(f"   R = {round(b.R, 4)} pu")
        print(f"   X = {round(b.X, 4)} pu")
        print(f"   X/R = {round(b.X/b.R, 1)}")
        print(f"   G = {round(b.G, 4)} pu")
        print(f"   B = {round(b.B, 4)} pu")
    print()

    print("Transformer types:")
    for t in grid.transformer_types:
        print(f" - {t}: Copper losses={int(t.Pcu)}kW, "
              f"Iron losses={int(t.Pfe)}kW, SC voltage={t.Vsc}%")
    print()

    print("Losses:")
    for i in range(len(grid.branches)):
        print(
            f" - {grid.branches[i]}: losses={1000*round(power_flow.results.losses[i], 3)} kVA"
        )
    print()

    equal = False
    for i, branch in enumerate(grid.branches):
        if branch.name == "X_C3":
            equal = power_flow.results.tap_module[i] == branch.tap_module

    if not equal:
        grid.export_pf(f"{test_name}_results.xlsx", power_flow.results)
        grid.save_excel(f"{test_name}_grid.xlsx")

    assert equal
Exemplo n.º 10
0
def test_corr_line_losses():
    test_name = "test_corr_line_losses"

    grid = MultiCircuit(name=test_name)
    grid.Sbase = Sbase
    grid.time_profile = None
    grid.logger = list()

    # Create buses
    Bus0 = Bus(name="Bus0", vnom=10, is_slack=True)
    bus_1 = Bus(name="bus_1", vnom=10)

    grid.add_bus(Bus0)
    grid.add_bus(bus_1)

    # Create load
    grid.add_load(bus_1, Load(name="Load0", P=1.0, Q=0.4))

    # Create slack bus
    grid.add_generator(Bus0, Generator(name="Utility"))

    # Create cable
    cable = Branch(bus_from=Bus0,
                   bus_to=bus_1,
                   name="Cable0",
                   r=0.784,
                   x=0.174,
                   temp_base=20,  # °C
                   temp_oper=90,  # °C
                   alpha=0.00323)  # Copper

    grid.add_branch(cable)

    options = PowerFlowOptions(verbose=True,
                               apply_temperature_correction=True)

    power_flow = PowerFlow(grid, options)
    power_flow.run()

    # Check solution
    approx_losses = round(power_flow.results.losses[0], 3)
    solution = complex(0.011, 0.002)  # Expected solution from GridCal
                                      # Tested on ETAP 16.1.0

    print("\n=================================================================")
    print(f"Test: {test_name}")
    print("=================================================================\n")
    print(f"Results:  {approx_losses}")
    print(f"Solution: {solution}")
    print()

    print("Buses:")
    for i, b in enumerate(grid.buses):
        print(f" - bus[{i}]: {b}")
    print()

    print("Branches:")
    for b in grid.branches:
        print(f" - {b}:")
        print(f"   R = {round(b.R, 4)} pu")
        print(f"   X = {round(b.X, 4)} pu")
        print(f"   X/R = {round(b.X/b.R, 2)}")
    print()

    print("Voltages:")
    for i in range(len(grid.buses)):
        print(f" - {grid.buses[i]}: voltage={round(power_flow.results.voltage[i], 3)} pu")
    print()

    print("Losses:")
    for i in range(len(grid.branches)):
        print(f" - {grid.branches[i]}: losses={round(power_flow.results.losses[i], 3)} MVA")
    print()

    print("Loadings (power):")
    for i in range(len(grid.branches)):
        print(f" - {grid.branches[i]}: loading={round(power_flow.results.Sbranch[i], 3)} MVA")
    print()

    print("Loadings (current):")
    for i in range(len(grid.branches)):
        print(f" - {grid.branches[i]}: loading={round(power_flow.results.Ibranch[i], 3)} pu")
    print()

    assert approx_losses == solution
Exemplo n.º 11
0
def test_gridcal_regulator():
    """
    GridCal test for the new implementation of transformer voltage regulators.
    """
    test_name = "test_gridcal_regulator"
    grid = MultiCircuit(name=test_name)
    grid.Sbase = 100.0  # MVA
    grid.time_profile = None
    grid.logger = Logger()

    # Create buses
    POI = Bus(
        name="POI",
        vnom=100,  # kV
        is_slack=True)
    grid.add_bus(POI)

    B_C3 = Bus(name="B_C3", vnom=10)  # kV
    grid.add_bus(B_C3)

    B_MV_M32 = Bus(name="B_MV_M32", vnom=10)  # kV
    grid.add_bus(B_MV_M32)

    B_LV_M32 = Bus(name="B_LV_M32", vnom=0.6)  # kV
    grid.add_bus(B_LV_M32)

    # Create voltage controlled generators (or slack, a.k.a. swing)
    UT = Generator(name="Utility")
    UT.bus = POI
    grid.add_generator(POI, UT)

    # Create static generators (with fixed power factor)
    M32 = StaticGenerator(name="M32", P=4.2, Q=0.0)  # MVA (complex)
    M32.bus = B_LV_M32
    grid.add_static_generator(B_LV_M32, M32)

    # Create transformer types
    s = 100  # MVA
    z = 8  # %
    xr = 40
    SS = TransformerType(
        name="SS",
        hv_nominal_voltage=100,  # kV
        lv_nominal_voltage=10,  # kV
        nominal_power=s,  # MVA
        copper_losses=complex_impedance(z, xr).real * s * 1000.0 /
        grid.Sbase,  # kW
        iron_losses=125,  # kW
        no_load_current=0.5,  # %
        short_circuit_voltage=z)  # %
    grid.add_transformer_type(SS)

    s = 5  # MVA
    z = 6  # %
    xr = 20
    PM = TransformerType(
        name="PM",
        hv_nominal_voltage=10,  # kV
        lv_nominal_voltage=0.6,  # kV
        nominal_power=s,  # MVA
        copper_losses=complex_impedance(z, xr).real * s * 1000.0 /
        grid.Sbase,  # kW
        iron_losses=6.25,  # kW
        no_load_current=0.5,  # %
        short_circuit_voltage=z)  # %
    grid.add_transformer_type(PM)

    # Create branches
    X_C3 = Branch(bus_from=POI,
                  bus_to=B_C3,
                  name="X_C3",
                  branch_type=BranchType.Transformer,
                  template=SS,
                  bus_to_regulated=True,
                  vset=1.05)
    X_C3.tap_changer = TapChanger(taps_up=16,
                                  taps_down=16,
                                  max_reg=1.1,
                                  min_reg=0.9)
    X_C3.tap_changer.set_tap(X_C3.tap_module)
    grid.add_branch(X_C3)

    C_M32 = Branch(bus_from=B_C3,
                   bus_to=B_MV_M32,
                   name="C_M32",
                   r=7.84,
                   x=1.74)
    grid.add_branch(C_M32)

    X_M32 = Branch(bus_from=B_MV_M32,
                   bus_to=B_LV_M32,
                   name="X_M32",
                   branch_type=BranchType.Transformer,
                   template=PM)
    grid.add_branch(X_M32)

    # Apply templates (device types)
    grid.apply_all_branch_types()

    print("Buses:")
    for i, b in enumerate(grid.buses):
        print(f" - bus[{i}]: {b}")
    print()

    options = PowerFlowOptions(SolverType.NR,
                               verbose=True,
                               initialize_with_existing_solution=True,
                               multi_core=True,
                               control_q=ReactivePowerControlMode.Direct,
                               control_taps=TapsControlMode.Direct,
                               tolerance=1e-6,
                               max_iter=99)

    power_flow = PowerFlowDriver(grid, options)
    power_flow.run()

    approx_volt = [round(100 * abs(v), 1) for v in power_flow.results.voltage]
    solution = [100.0, 105.2, 130.0, 130.1]  # Expected solution from GridCal

    print()
    print(f"Test: {test_name}")
    print(f"Results:  {approx_volt}")
    print(f"Solution: {solution}")
    print()

    print("Generators:")
    for g in grid.get_generators():
        print(f" - Generator {g}: q_min={g.Qmin}pu, q_max={g.Qmax}pu")
    print()

    print("Branches:")
    branches = grid.get_branches()
    for b in grid.transformers2w:
        print(
            f" - {b}: R={round(b.R, 4)}pu, X={round(b.X, 4)}pu, X/R={round(b.X/b.R, 1)}, vset={b.vset}"
        )
    print()

    print("Transformer types:")
    for t in grid.transformer_types:
        print(
            f" - {t}: Copper losses={int(t.Pcu)}kW, Iron losses={int(t.Pfe)}kW, SC voltage={t.Vsc}%"
        )
    print()

    print("Losses:")
    for i in range(len(branches)):
        print(
            f" - {branches[i]}: losses={round(power_flow.results.losses[i], 3)} MVA"
        )
    print()

    tr_vset = [tr.vset for tr in grid.transformers2w]
    print(f"Voltage settings: {tr_vset}")

    equal = np.isclose(approx_volt, solution, atol=1e-3).all()

    assert equal
def test_pv_3():
    """
    Voltage controlled generator test, also useful for a basic tutorial. In this
    case the generator M32 regulates the voltage at a setpoint of 1.025 pu, and
    the slack bus (POI) regulates it at 1.0 pu.

    The transformers' magnetizing branch losses are considered, as well as the
    main power transformer's voltage regulator (X_C3) which regulates bus
    B_MV_M32 at 1.005 pu.

    In addition, the iterative PV control method is used instead of the usual
    (faster) method.
    """
    test_name = "test_pv_3"
    grid = MultiCircuit(name=test_name)
    Sbase = 100  # MVA
    grid.Sbase = Sbase
    grid.time_profile = None
    grid.logger = Logger()

    # Create buses
    POI = Bus(
        name="POI",
        vnom=100,  # kV
        is_slack=True)
    grid.add_bus(POI)

    B_MV_M32 = Bus(name="B_MV_M32", vnom=10)  # kV
    grid.add_bus(B_MV_M32)

    B_LV_M32 = Bus(name="B_LV_M32", vnom=0.6)  # kV
    grid.add_bus(B_LV_M32)

    # Create voltage controlled generators (or slack, a.k.a. swing)
    UT = Generator(name="Utility")
    UT.bus = POI
    grid.add_generator(POI, UT)

    M32 = Generator(name="M32",
                    active_power=4.2,
                    voltage_module=1.025,
                    Qmin=-2.5,
                    Qmax=2.5)
    M32.bus = B_LV_M32
    grid.add_generator(B_LV_M32, M32)

    # Create transformer types
    s = 100  # MVA
    z = 8  # %
    xr = 40
    SS = TransformerType(
        name="SS",
        hv_nominal_voltage=100,  # kV
        lv_nominal_voltage=10,  # kV
        nominal_power=s,
        copper_losses=complex_impedance(z, xr).real * s * 1000 / Sbase,
        iron_losses=125,  # kW
        no_load_current=0.5,  # %
        short_circuit_voltage=z)
    grid.add_transformer_type(SS)

    s = 5  # MVA
    z = 6  # %
    xr = 20
    PM = TransformerType(
        name="PM",
        hv_nominal_voltage=10,  # kV
        lv_nominal_voltage=0.6,  # kV
        nominal_power=s,
        copper_losses=complex_impedance(z, xr).real * s * 1000 / Sbase,
        iron_losses=6.25,  # kW
        no_load_current=0.5,  # %
        short_circuit_voltage=z)
    grid.add_transformer_type(PM)

    # Create branches
    X_C3 = Branch(bus_from=POI,
                  bus_to=B_MV_M32,
                  name="X_C3",
                  branch_type=BranchType.Transformer,
                  template=SS,
                  bus_to_regulated=True,
                  vset=1.005)
    X_C3.tap_changer = TapChanger(taps_up=16,
                                  taps_down=16,
                                  max_reg=1.1,
                                  min_reg=0.9)
    X_C3.tap_changer.set_tap(X_C3.tap_module)
    grid.add_branch(X_C3)

    X_M32 = Branch(bus_from=B_MV_M32,
                   bus_to=B_LV_M32,
                   name="X_M32",
                   branch_type=BranchType.Transformer,
                   template=PM)
    grid.add_branch(X_M32)

    # Apply templates (device types)
    grid.apply_all_branch_types()

    print("Buses:")
    for i, b in enumerate(grid.buses):
        print(f" - bus[{i}]: {b}")
    print()

    options = PowerFlowOptions(SolverType.LM,
                               verbose=True,
                               initialize_with_existing_solution=True,
                               multi_core=True,
                               control_q=ReactivePowerControlMode.Iterative,
                               control_taps=TapsControlMode.Direct,
                               tolerance=1e-6,
                               max_iter=99)

    power_flow = PowerFlowDriver(grid, options)
    power_flow.run()

    approx_volt = [round(100 * abs(v), 1) for v in power_flow.results.voltage]
    solution = [100.0, 100.7, 102.5]  # Expected solution from GridCal

    print()
    print(f"Test: {test_name}")
    print(f"Results:  {approx_volt}")
    print(f"Solution: {solution}")
    print()

    print("Generators:")
    for g in grid.get_generators():
        print(f" - Generator {g}: q_min={g.Qmin} MVAR, q_max={g.Qmax} MVAR")
    print()

    print("Branches:")
    for b in grid.branches:
        print(f" - {b}:")
        print(f"   R = {round(b.R, 4)} pu")
        print(f"   X = {round(b.X, 4)} pu")
        print(f"   X/R = {round(b.X / b.R, 1)}")
        print(f"   G = {round(b.G, 4)} pu")
        print(f"   B = {round(b.B, 4)} pu")
    print()

    print("Transformer types:")
    for t in grid.transformer_types:
        print(
            f" - {t}: Copper losses={int(t.Pcu)}kW, Iron losses={int(t.Pfe)}kW, SC voltage={t.Vsc}%"
        )
    print()

    print("Losses:")
    for i in range(len(grid.branches)):
        print(
            f" - {grid.branches[i]}: losses={1000 * round(power_flow.results.losses[i], 3)} kVA"
        )
    print()

    equal = True
    for i in range(len(approx_volt)):
        if approx_volt[i] != solution[i]:
            equal = False

    assert equal
Exemplo n.º 13
0
def main():
    ####################################################################################################################
    # Define the circuit
    #
    # A circuit contains all the grid information regardless of the islands formed or the amount of devices
    ####################################################################################################################


    grid = MultiCircuit(name='lynn 5 bus')

    ####################################################################################################################
    # Define the buses
    ####################################################################################################################
    # I will define this bus with all the properties so you see
    bus1 = Bus(name='Bus1',
               vnom=10,   # Nominal voltage in kV
               vmin=0.9,  # Bus minimum voltage in per unit
               vmax=1.1,  # Bus maximum voltage in per unit
               xpos=0,    # Bus x position in pixels
               ypos=0,    # Bus y position in pixels
               height=0,  # Bus height in pixels
               width=0,   # Bus width in pixels
               active=True,   # Is the bus active?
               is_slack=False,  # Is this bus a slack bus?
               area='Defualt',  # Area (for grouping purposes only)
               zone='Default',  # Zone (for grouping purposes only)
               substation='Default'  # Substation (for grouping purposes only)
               )

    # the rest of the buses are defined with the default parameters
    bus2 = Bus(name='Bus2')
    bus3 = Bus(name='Bus3')
    bus4 = Bus(name='Bus4')
    bus5 = Bus(name='Bus5')

    # add the bus objects to the circuit
    grid.add_bus(bus1)
    grid.add_bus(bus2)
    grid.add_bus(bus3)
    grid.add_bus(bus4)
    grid.add_bus(bus5)

    ####################################################################################################################
    # Add the loads
    ####################################################################################################################
    # In GridCal, the loads, generators ect are stored within each bus object:

    # we'll define the first load completely
    l2 = Load(name='Load',
              G=0,  # Impedance of the ZIP model in MVA at the nominal voltage
              B=0,
              Ir=0,
              Ii=0,  # Current of the ZIP model in MVA at the nominal voltage
              P=40,
              Q=20,  # Power of the ZIP model in MVA
              P_prof=None,  # Impedance profile
              Q_prof=None,  # Current profile
              Ir_prof=None,  # Power profile
              Ii_prof=None,
              G_prof=None,
              B_prof=None,
              active=True,  # Is active?
              mttf=0.0,  # Mean time to failure
              mttr=0.0  # Mean time to recovery
              )
    grid.add_load(bus2, l2)

    # Define the others with the default parameters
    grid.add_load(bus3, Load(P=25, Q=15))
    grid.add_load(bus4, Load(P=40, Q=20))
    grid.add_load(bus5, Load(P=50, Q=20))

    ####################################################################################################################
    # Add the generators
    ####################################################################################################################

    g1 = Generator(name='gen',
                   active_power=0.0,  # Active power in MW, since this generator is used to set the slack , is 0
                   voltage_module=1.0,  # Voltage set point to control
                   Qmin=-9999,  # minimum reactive power in MVAr
                   Qmax=9999,  # Maximum reactive power in MVAr
                   Snom=9999,  # Nominal power in MVA
                   power_prof=None,  # power profile
                   vset_prof=None,  # voltage set point profile
                   active=True  # Is active?
                   )
    grid.add_generator(bus1, g1)

    ####################################################################################################################
    # Add the lines
    ####################################################################################################################

    br1 = Branch(bus_from=bus1,
                 bus_to=bus2,
                 name='Line 1-2',
                 r=0.05,  # resistance of the pi model in per unit
                 x=0.11,  # reactance of the pi model in per unit
                 g=1e-20,  # conductance of the pi model in per unit
                 b=0.02,  # susceptance of the pi model in per unit
                 rate=50,  # Rate in MVA
                 tap=1.0,  # Tap value (value close to 1)
                 shift_angle=0,  # Tap angle in radians
                 active=True,  # is the branch active?
                 mttf=0,  # Mean time to failure
                 mttr=0,  # Mean time to recovery
                 branch_type=BranchType.Line,  # Branch type tag
                 length=1,  # Length in km (to be used with templates)
                 template=BranchTemplate()  # Branch template (The default one is void)
                 )
    grid.add_branch(br1)

    grid.add_branch(Branch(bus1, bus3, name='Line 1-3', r=0.05, x=0.11, b=0.02, rate=50))
    grid.add_branch(Branch(bus1, bus5, name='Line 1-5', r=0.03, x=0.08, b=0.02, rate=80))
    grid.add_branch(Branch(bus2, bus3, name='Line 2-3', r=0.04, x=0.09, b=0.02, rate=3))
    grid.add_branch(Branch(bus2, bus5, name='Line 2-5', r=0.04, x=0.09, b=0.02, rate=10))
    grid.add_branch(Branch(bus3, bus4, name='Line 3-4', r=0.06, x=0.13, b=0.03, rate=30))
    grid.add_branch(Branch(bus4, bus5, name='Line 4-5', r=0.04, x=0.09, b=0.02, rate=30))

    ####################################################################################################################
    # Run a power flow simulation
    ####################################################################################################################

    # We need to specify power flow options
    pf_options = PowerFlowOptions(solver_type=SolverType.NR,  # Base method to use
                                  verbose=False,  # Verbose option where available
                                  tolerance=1e-6,  # power error in p.u.
                                  max_iter=25,  # maximum iteration number
                                  control_q=True  # if to control the reactive power
                                  )

    # Declare and execute the power flow simulation
    pf = PowerFlowDriver(grid, pf_options)
    pf.run()

    # now, let's compose a nice DataFrame with the voltage results
    headers = ['Vm (p.u.)', 'Va (Deg)', 'Vre', 'Vim']
    Vm = np.abs(pf.results.voltage)
    Va = np.angle(pf.results.voltage, deg=True)
    Vre = pf.results.voltage.real
    Vim = pf.results.voltage.imag
    data = np.c_[Vm, Va, Vre, Vim]
    v_df = pd.DataFrame(data=data, columns=headers, index=grid.bus_names)
    print('\n', v_df)


    # Let's do the same for the branch results
    headers = ['Loading (%)', 'Current(p.u.)', 'Power (MVA)']
    loading = np.abs(pf.results.loading) * 100
    current = np.abs(pf.results.Ibranch)
    power = np.abs(pf.results.Sbranch)
    data = np.c_[loading, current, power]
    br_df = pd.DataFrame(data=data, columns=headers, index=grid.branch_names)
    print('\n', br_df)

    # Finally the execution metrics
    print('\nError:', pf.results.error)
    print('Elapsed time (s):', pf.results.elapsed, '\n')

    print(v_df)
    print()
    print(br_df)
Exemplo n.º 14
0
def get_grid_lynn_5_bus_wiki():
    grid = MultiCircuit(name='lynn 5 bus')

    bus_1 = Bus(
        name='bus_1',
        vnom=10,  # Nominal voltage in kV
        vmin=0.9,  # Bus minimum voltage in per unit
        vmax=1.1,  # Bus maximum voltage in per unit
        xpos=0,  # Bus x position in pixels
        ypos=0,  # Bus y position in pixels
        height=0,  # Bus height in pixels
        width=0,  # Bus width in pixels
        active=True,  # Is the bus active?
        is_slack=False,  # Is this bus a slack bus?
        area='Default',  # Area (for grouping purposes only)
        zone='Default',  # Zone (for grouping purposes only)
        substation='Default'  # Substation (for grouping purposes only)
    )
    bus_2 = Bus(name='bus_2')
    bus_3 = Bus(name='bus_3')
    bus_4 = Bus(name='bus_4')
    bus_5 = Bus(name='bus_5')
    grid.add_bus(bus_1)
    grid.add_bus(bus_2)
    grid.add_bus(bus_3)
    grid.add_bus(bus_4)
    grid.add_bus(bus_5)
    load_2 = Load(
        name='Load',
        # impedance=complex(0, 0),
        # Impedance of the ZIP model in MVA at the nominal voltage
        # current=complex(0, 0),
        # Current of the ZIP model in MVA at the nominal voltage
        # power=complex(40, 20),  # Power of the ZIP model in MVA
        # impedance_prof=None,  # Impedance profile
        # current_prof=None,  # Current profile
        # power_prof=None,  # Power profile
        active=True,  # Is active?
        mttf=0.0,  # Mean time to failure
        mttr=0.0  # Mean time to recovery
    )
    grid.add_load(bus_2, load_2)
    grid.add_load(
        bus_3,
        Load(
            # power=complex(25, 15)
        ))
    grid.add_load(
        bus_4,
        Load(
            # power=complex(40, 20)
        ))
    grid.add_load(
        bus_5,
        Load(
            # power=complex(50, 20)
        ))
    generator_1 = Generator(
        name='gen',
        active_power=0.0,
        # Active power in MW, since this generator is used to set the slack , is 0
        voltage_module=1.0,  # Voltage set point to control
        Qmin=-9999,  # minimum reactive power in MVAr
        Qmax=9999,  # Maximum reactive power in MVAr
        Snom=9999,  # Nominal power in MVA
        power_prof=None,  # power profile
        vset_prof=None,  # voltage set point profile
        active=True  # Is active?
    )
    grid.add_generator(bus_1, generator_1)
    branch_1 = Branch(
        bus_from=bus_1,
        bus_to=bus_2,
        name='Line 1-2',
        r=0.05,  # resistance of the pi model in per unit
        x=0.11,  # reactance of the pi model in per unit
        g=1e-20,  # conductance of the pi model in per unit
        b=0.02,  # susceptance of the pi model in per unit
        rate=50,  # Rate in MVA
        tap=1.0,  # Tap value (value close to 1)
        shift_angle=0,  # Tap angle in radians
        active=True,  # is the branch active?
        mttf=0,  # Mean time to failure
        mttr=0,  # Mean time to recovery
        branch_type=BranchType.Line,  # Branch type tag
        length=1,  # Length in km (to be used with templates)
        # type_obj=BranchTemplate()
        # Branch template (The default one is void)
    )
    grid.add_branch(branch_1)
    grid.add_branch(
        Branch(bus_1, bus_3, name='Line 1-3', r=0.05, x=0.11, b=0.02, rate=50))
    grid.add_branch(
        Branch(bus_1, bus_5, name='Line 1-5', r=0.03, x=0.08, b=0.02, rate=80))
    grid.add_branch(
        Branch(bus_2, bus_3, name='Line 2-3', r=0.04, x=0.09, b=0.02, rate=3))
    grid.add_branch(
        Branch(bus_2, bus_5, name='Line 2-5', r=0.04, x=0.09, b=0.02, rate=10))
    grid.add_branch(
        Branch(bus_3, bus_4, name='Line 3-4', r=0.06, x=0.13, b=0.03, rate=30))
    grid.add_branch(
        Branch(bus_4, bus_5, name='Line 4-5', r=0.04, x=0.09, b=0.02, rate=30))

    grid.compile()

    return grid
Exemplo n.º 15
0
def test_tolerance_lf_higher():
    test_name = "test_tolerance_lf_higher"
    grid = MultiCircuit(name=test_name)
    grid.Sbase = Sbase
    grid.time_profile = None
    grid.logger = list()

    # Create buses
    Bus0 = Bus(name="Bus0", vnom=25, is_slack=True)
    bus_1 = Bus(name="bus_1", vnom=25)

    grid.add_bus(Bus0)
    grid.add_bus(bus_1)

    # Create load
    grid.add_load(bus_1, Load(name="Load0", P=1.0, Q=0.4))

    # Create slack bus
    grid.add_generator(Bus0, Generator(name="Utility"))

    # Create cable (r and x should be in pu)
    grid.add_branch(
        Branch(bus_from=Bus0,
               bus_to=bus_1,
               name="Cable1",
               r=0.01,
               x=0.05,
               tolerance=10))

    # Run non-linear power flow
    options = PowerFlowOptions(
        verbose=True,
        branch_impedance_tolerance_mode=BranchImpedanceMode.Upper)

    power_flow = PowerFlow(grid, options)
    power_flow.run()

    # Check solution
    approx_losses = round(1000 * power_flow.results.losses[0], 3)
    solution = complex(0.128, 0.58)  # Expected solution from GridCal
    # Tested on ETAP 16.1.0 and pandapower

    print(
        "\n=================================================================")
    print(f"Test: {test_name}")
    print(
        "=================================================================\n")
    print(f"Results:  {approx_losses}")
    print(f"Solution: {solution}")
    print()

    print("Buses:")
    for i, b in enumerate(grid.buses):
        print(f" - bus[{i}]: {b}")
    print()

    print("Branches:")
    for b in grid.branches:
        print(f" - {b}:")
        print(f"   R = {round(b.R, 4)} pu")
        print(f"   X = {round(b.X, 4)} pu")
        print(f"   X/R = {round(b.X/b.R, 2)}")
    print()

    print("Voltages:")
    for i in range(len(grid.buses)):
        print(
            f" - {grid.buses[i]}: voltage={round(power_flow.results.voltage[i], 3)} pu"
        )
    print()

    print("Losses:")
    for i in range(len(grid.branches)):
        print(
            f" - {grid.branches[i]}: losses={round(power_flow.results.losses[i], 3)} MVA"
        )
    print()

    print("Loadings (power):")
    for i in range(len(grid.branches)):
        print(
            f" - {grid.branches[i]}: loading={round(power_flow.results.Sbranch[i], 3)} MVA"
        )
    print()

    print("Loadings (current):")
    for i in range(len(grid.branches)):
        print(
            f" - {grid.branches[i]}: loading={round(power_flow.results.Ibranch[i], 3)} pu"
        )
    print()

    assert approx_losses == solution