Exemplo n.º 1
0
 def test_outlet(self):
     for T_stag_in in self.T_stag_in_outlet:
         for G_in in self.G_in_outlet:
             for dif in self.dif_outlet:
                 print('T_stag_in = %.1f, G_in = %.3f, dif = %.3f' %
                       (T_stag_in, G_in, dif))
                 p_stag_in = 1.2e5
                 work_fluid = NaturalGasCombustionProducts()
                 G_fuel = 0.1
                 alpha = 1 / (work_fluid.l0 * G_fuel / (G_in - G_fuel))
                 c_p = work_fluid.c_p_real_func(T_stag_in, alpha=alpha)
                 k = work_fluid.k_func(c_p)
                 F_in = 0.25
                 q = G_in * np.sqrt(work_fluid.R * T_stag_in) / (
                     F_in * p_stag_in * gd.m(k))
                 lam = gd.lam(k, q=q)
                 a_cr = gd.a_cr(T_stag_in, k, work_fluid.R)
                 c_in = a_cr * lam
                 outlet = OutletModel(T_stag_in=T_stag_in,
                                      p_stag_in=1.2e5,
                                      G_in=G_in,
                                      G_fuel_in=G_fuel,
                                      c_in=c_in,
                                      F_in=F_in,
                                      F_out=F_in * dif,
                                      sigma=0.99)
                 outlet.compute()
                 G_in = outlet.rho_in * outlet.F_in * outlet.c_in
                 G_out = outlet.rho_out * outlet.F_out * outlet.c_out
                 G_res = abs(G_out - G_in) / G_in
                 self.assertAlmostEqual(G_res, 0, places=3)
Exemplo n.º 2
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 def test_integrate_work_balance_power_turbine_ngas_wcool(self):
     """Соврадение работы, определенной на разности входной и выходной энтальпий, заданной величине."""
     work_fluid = NaturalGasCombustionProducts()
     T_g_stag = self.power_turbine_ngas_wcool.T_g_stag
     T_t_stag = self.power_turbine_ngas_wcool.last.T_st_stag
     work_fluid.T1 = T_g_stag
     work_fluid.T2 = T_t_stag
     work_fluid.alpha = self.power_turbine_ngas_wcool.first.alpha_air_in
     L_t = work_fluid.c_p_av_int * (T_g_stag - T_t_stag)
     L_t_res = abs(L_t - self.power_turbine_ngas_wcool.L_t_cycle) / self.power_turbine_ngas_wcool.L_t_cycle
     self.assertAlmostEqual(L_t_res, 0, places=2)
Exemplo n.º 3
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 def __init__(self,
              T_stag_in,
              p_stag_in,
              G_in,
              G_fuel_in,
              c_in,
              F_in,
              F_out,
              sigma,
              work_fluid: IdealGas = NaturalGasCombustionProducts()):
     ModelSingleWorkFluid.__init__(self)
     ModelStaticPar.__init__(self)
     self.T_stag_in = T_stag_in
     self.p_stag_in = p_stag_in
     self.G_in = G_in
     self.G_fuel_in = G_fuel_in
     self.c_in = c_in
     self.F_in = F_in
     self.F_out = F_out
     self.sigma = sigma
     self.work_fluid = work_fluid
     self.fuel_content = None
     self.alpha = None
     self.c_p = None
     self.k = None
     self.static_out = None
Exemplo n.º 4
0
 def __init__(self,
              T_stag_in,
              p_stag_in,
              G_in,
              G_fuel_in,
              pi_t_stag,
              T_stag_in_nom,
              p_stag_in_nom,
              G_in_nom,
              pi_t_stag_nom,
              eta_t_stag_nom,
              F_out,
              eta_m=0.9,
              work_fluid: IdealGas = NaturalGasCombustionProducts(),
              precision=0.001):
     TurbineModel.__init__(self, T_stag_in, p_stag_in, G_in, G_fuel_in,
                           pi_t_stag, T_stag_in_nom, p_stag_in_nom,
                           G_in_nom, pi_t_stag_nom, eta_t_stag_nom, eta_m,
                           work_fluid, precision)
     self.F_out = F_out
     self.c_p_out = None
     self.k_out = None
     self.q_out = None
     self.lam_out = None
     self.a_cr_out = None
     self.c_out = None
Exemplo n.º 5
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    def __init__(self,
                 T_stag_in,
                 p_stag_in,
                 G_in,
                 G_fuel_in,
                 g_cool,
                 G_c1_in,
                 T_cool,
                 cool_fluid: IdealGas = Air(),
                 work_fluid: IdealGas = NaturalGasCombustionProducts(),
                 precision=0.0001):
        ModelSingleWorkFluid.__init__(self)
        self.T_stag_in = T_stag_in
        self.p_stag_in = p_stag_in
        self.G_in = G_in
        self.G_fuel_in = G_fuel_in
        self.g_cool = g_cool
        self.G_c1_in = G_c1_in
        self.T_cool = T_cool
        self.cool_fluid = cool_fluid
        self.work_fluid = work_fluid
        self.precision = precision

        self.G_cool = None
        self.fuel_content_in = None
        self.fuel_content_out = None
        self.alpha_in = None
        self.alpha_out = None
Exemplo n.º 6
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 def test_integrate_work_balance_comp_turbine_ngas_cool(self):
     """Соврадение работы, определенной на разности входной и выходной энтальпий, заданной величине."""
     work_fluid = NaturalGasCombustionProducts()
     T_g_stag = self.comp_turbine_ngas_cool.T_g_stag
     T_t_stag = self.comp_turbine_ngas_cool.last.T_st_stag
     g_outlet = self.comp_turbine_ngas_cool.last.G_stage_in / self.comp_turbine_ngas_cool.G_turbine
     i_stag_in = work_fluid.get_specific_enthalpy(T_g_stag, alpha=self.comp_turbine_ngas_cool.first.alpha_air_in)
     i_stag_out = work_fluid.get_specific_enthalpy(
         T_t_stag, alpha=self.comp_turbine_ngas_cool.last.alpha_air_in
     ) * g_outlet
     i_cool = 0
     for n, stage in enumerate(self.comp_turbine_ngas_cool):
         if n != self.comp_turbine_ngas_cool.stage_number - 1:
             i_cool += stage.i_cool
     L_t = i_stag_in - i_stag_out + i_cool
     L_t_res = abs(L_t - self.comp_turbine_ngas_cool.L_t_cycle) / self.comp_turbine_ngas_cool.L_t_cycle
     self.assertAlmostEqual(L_t_res, 0, places=3)
Exemplo n.º 7
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def compute_cycle(eta_stag_p_c=0.88, eta_stag_p_ct=9.9, eta_stag_p_pt=0.9):
    precision = 0.0001
    atm = Atmosphere()
    inlet = Inlet()
    comp = Compressor(pi_c=17, eta_stag_p=eta_stag_p_c, precision=precision)
    sink = Sink(g_cooling=0, g_outflow=0.03)
    comb_chamber = CombustionChamber(T_gas=1523,
                                     precision=precision,
                                     alpha_out_init=2,
                                     fuel=NaturalGas(),
                                     T_fuel=320,
                                     delta_p_fuel=5e5)
    comp_turbine = Turbine(eta_stag_p=eta_stag_p_ct,
                           eta_m=0.99,
                           precision=precision)
    source = Source(g_return=0)
    power_turbine = Turbine(eta_stag_p=eta_stag_p_pt,
                            eta_m=0.99,
                            eta_r=0.99,
                            precision=precision,
                            p_stag_out_init=1e5)
    outlet = Outlet()
    load = Load(power=16e6)
    comp_turb_zero_load = Load(power=0)
    power_turb_zero_load = Load(power=0)

    solver = NetworkSolver(unit_arr=[
        atm, inlet, comp, sink, comb_chamber, comp_turbine, source,
        power_turbine, outlet, load, comp_turb_zero_load, power_turb_zero_load
    ],
                           relax_coef=1,
                           precision=precision,
                           max_iter_number=100,
                           cold_work_fluid=Air(),
                           hot_work_fluid=NaturalGasCombustionProducts())
    solver.create_gas_dynamic_connection(atm, inlet)
    solver.create_gas_dynamic_connection(inlet, comp)
    solver.create_gas_dynamic_connection(comp, sink)
    solver.create_gas_dynamic_connection(sink, comb_chamber)
    solver.create_gas_dynamic_connection(comb_chamber, comp_turbine)
    solver.create_gas_dynamic_connection(comp_turbine, source)
    solver.create_gas_dynamic_connection(source, power_turbine)
    solver.create_gas_dynamic_connection(power_turbine, outlet)
    solver.create_static_gas_dynamic_connection(outlet, atm)
    solver.create_mechanical_connection(comp_turbine, comp,
                                        comp_turb_zero_load)
    solver.create_mechanical_connection(power_turbine, load,
                                        power_turb_zero_load)
    solver.solve()
    G_air = load.power / power_turbine.gen_labour1
    G_comp_turb = G_air * comp_turbine.g_in
    G_power_turb = G_air * power_turbine.g_in
    G_fuel = G_air * comb_chamber.g_fuel_prime * comb_chamber.g_in
    eta_e = power_turbine.gen_labour1 / (comb_chamber.work_fluid_out.Q_n *
                                         comb_chamber.g_fuel_prime *
                                         comb_chamber.g_in)
    return solver, G_air, G_comp_turb, G_power_turb, G_fuel, eta_e
Exemplo n.º 8
0
 def test_setting_data_from_input_file(self):
     turbine_input = TurbineInput(TurbineType.Compressor, 1500, 12e5, 25, 1,
                                  NaturalGasCombustionProducts(), 1200, 0.91)
     self.form.set_data_from_turbine_input(turbine_input)
     self.assertEqual(self.form.turbine_type.currentIndex(), 1)
     self.assertEqual(self.form.fuel.currentIndex(), 1)
     self.assertAlmostEqual(self.form.T_g_stag.value(), turbine_input.T_g_stag, 2)
     self.assertAlmostEqual(self.form.p_g_stag.value(), turbine_input.p_g_stag / 1e6, places=3)
     self.assertAlmostEqual(self.form.G_t.value(), turbine_input.G_turbine, places=2)
     self.assertAlmostEqual(self.form.G_fuel.value(), turbine_input.G_fuel, places=2)
     self.assertAlmostEqual(self.form.T_t_stag_cycle.value(), turbine_input.T_t_stag_cycle, places=0)
     self.assertAlmostEqual(self.form.eta_t_stag_cycle.value(), turbine_input.eta_t_stag_cycle, places=2)
Exemplo n.º 9
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    def test_separate_stages_averaging_comp_turbine_ngas_cool(self):
        """Равенство работы ступеней разности энатльпий на входе и на выходе ступеней."""
        for i in range(len(self.comp_turbine_ngas_cool)):
            logging.info('Stage %s' % (i + 1))
            stage = self.comp_turbine_ngas_cool[i]
            work_fluid_in = NaturalGasCombustionProducts()
            work_fluid_out = NaturalGasCombustionProducts()

            work_fluid_in.T = stage.T0_stag
            work_fluid_in.alpha = stage.alpha_air_in
            work_fluid_out.T = stage.T_st_stag
            work_fluid_out.alpha = stage.alpha_air_in

            enthalpy_in = work_fluid_in.c_p_av * (stage.T0_stag - work_fluid_in.T0)
            enthalpy_out = work_fluid_out.c_p_av * (stage.T_st_stag - work_fluid_out.T0)
            L_st = enthalpy_in - enthalpy_out
            L_res = abs(L_st - stage.L_t) / stage.L_t
            self.assertAlmostEqual(L_res, 0, places=3)
            self.assertEqual(stage.work_fluid.T2, stage.T_st_stag)
Exemplo n.º 10
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    def __init__(
        self,
        T_stag_in,
        p_stag_in,
        G_in,
        G_fuel_in,
        pi_t_stag,
        T_stag_in_nom,
        p_stag_in_nom,
        G_in_nom,
        pi_t_stag_nom,
        eta_t_stag_nom,
        eta_m=0.9,
        work_fluid: IdealGas = NaturalGasCombustionProducts(),
        precision=0.001,
    ):
        ModelSingleWorkFluid.__init__(self)
        self.T_stag_in = T_stag_in
        self.p_stag_in = p_stag_in
        self.G_in = G_in
        self.G_fuel_in = G_fuel_in
        self.pi_t_stag = pi_t_stag
        self.T_stag_in_nom = T_stag_in_nom
        self.p_stag_in_nom = p_stag_in_nom
        self.G_in_nom = G_in_nom
        self.pi_t_stag_nom = pi_t_stag_nom
        self.eta_t_stag_nom = eta_t_stag_nom
        self.eta_m = eta_m
        self.work_fluid = work_fluid
        self.precision = precision

        self.pi_t_stag_rel = None
        self.eta_t_stag_rel = None
        self.eta_t_stag = None
        self.fuel_content = None
        self.alpha = None
        self.ad_proc_res = None
        self.T_stag_out_ad = None
        self.H_stag = None
        self.L = None
        self.G_in_char = None
        self.N = None
Exemplo n.º 11
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    def __init__(self,
                 g_fuel,
                 G_c1_in,
                 T_stag_in,
                 p_stag_in,
                 G_in,
                 G_fuel_in,
                 eta_comb,
                 sigma_comb,
                 T_fuel=300,
                 fuel: Fuel = NaturalGas(),
                 delta_p_fuel=5e5,
                 work_fluid_in: IdealGas = Air(),
                 work_fluid_out: IdealGas = NaturalGasCombustionProducts(),
                 precision=0.0001):
        ModelMultipleWorkFluid.__init__(self)
        self.g_fuel = g_fuel
        self.G_c1_in = G_c1_in
        self.G_fuel_in = G_fuel_in
        self.G_in = G_in
        self.T_stag_in = T_stag_in
        self.p_stag_in = p_stag_in
        self.eta_comb = eta_comb
        self.sigma_comb = sigma_comb
        self.T_fuel = T_fuel
        self.fuel = fuel
        self.delta_p_fuel = delta_p_fuel
        self.work_fluid_in = work_fluid_in
        self.work_fluid_out = work_fluid_out
        self.precision = precision

        self.G_fuel = None
        self.fuel_content_out = None
        self.fuel_content_in = None
        self.alpha_in = None
        self.alpha_out = None
        self.i_stag_in = None
        self.i_stag_out = None
        self.p_fuel = None
        self.i_fuel = None
Exemplo n.º 12
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def compute_cycle_and_nodes(
        pi_c_stag=17,
        stage_num_arr=[int(i) for i in np.linspace(9, 15, 7)],
        H_t_rel1_arr=np.linspace(0.2, 0.35, 10),
        H_t_rel_delta=-0.06,
        c1_a_rel1_arr=np.linspace(0.45, 0.55, 10),
        c1_a_rel_delta=0.1):
    eta_stag_p_c = 0.87
    eta_stag_p_ct = 0.89
    eta_stag_p_pt = 0.89
    res = 1
    iter_num = 1
    while res >= 0.001:
        print('Iter %s' % iter_num)
        iter_num += 1
        solver, G_air, G_comp_turb, G_power_turb, G_fuel, eta_e = compute_cycle(
            eta_stag_p_c, eta_stag_p_ct, eta_stag_p_pt)
        n_ct = 11e3
        n_pt = 7.8e3
        inlet: Inlet = solver.get_sorted_unit_list()[1]
        comp_cycle: Compressor = solver.get_sorted_unit_list()[2]
        comp_turbine_cycle: Turbine = solver.get_sorted_unit_list()[5]
        power_turbine_cycle: Turbine = solver.get_sorted_unit_list()[7]
        sink: Sink = solver.get_sorted_unit_list()[3]
        comb_chamber: CombustionChamber = solver.get_sorted_unit_list()[4]
        outlet: Outlet = solver.get_sorted_unit_list()[8]
        load: Load = solver.get_sorted_unit_list()[9]

        comp = get_optimize_compressor(comp_cycle.p_stag_in,
                                       comp_cycle.T_stag_in, G_air, n_ct,
                                       pi_c_stag, stage_num_arr, H_t_rel1_arr,
                                       H_t_rel_delta, c1_a_rel1_arr,
                                       c1_a_rel_delta)

        comp_turbine = TurbAvLine(turbine_type=TurbineType.WORK,
                                  stage_number=2,
                                  T_g_stag=comp_turbine_cycle.T_stag_in,
                                  p_g_stag=comp_turbine_cycle.p_stag_in,
                                  G_turbine=G_comp_turb,
                                  G_fuel=G_fuel,
                                  work_fluid=NaturalGasCombustionProducts(),
                                  l1_D1_ratio=0.15,
                                  n=n_ct,
                                  T_t_stag_cycle=comp_turbine_cycle.T_stag_out,
                                  eta_t_stag_cycle=comp_turbine_cycle.eta_stag,
                                  alpha11=np.radians(14),
                                  precision=0.0001,
                                  eta_m=comp_turbine_cycle.eta_m,
                                  gamma_in=np.radians(0),
                                  gamma_out=np.radians(10),
                                  H01_init=200e3,
                                  c21_init=250)
        comp_turbine.compute_geometry()
        comp_turbine.compute_stages_gas_dynamics()
        comp_turbine.compute_integrate_turbine_parameters()

        power_turbine = TurbAvLine(
            turbine_type=TurbineType.WORK,
            stage_number=2,
            T_g_stag=power_turbine_cycle.T_stag_in,
            p_g_stag=power_turbine_cycle.p_stag_in,
            G_turbine=G_power_turb,
            G_fuel=G_fuel,
            work_fluid=NaturalGasCombustionProducts(),
            l1_D1_ratio=0.15,
            n=n_pt,
            eta_m=power_turbine_cycle.eta_m,
            T_t_stag_cycle=power_turbine_cycle.T_stag_out,
            eta_t_stag_cycle=power_turbine_cycle.eta_stag,
            alpha11=np.radians(14),
            precision=0.0001,
            gamma_in=np.radians(0),
            gamma_out=np.radians(15),
            H01_init=200e3,
            c21_init=250)
        power_turbine.compute_geometry()
        power_turbine.compute_stages_gas_dynamics()
        power_turbine.compute_integrate_turbine_parameters()

        eta_stag_p_c_res = abs(comp.eta_c_stag_p - eta_stag_p_c) / eta_stag_p_c
        eta_stag_p_ct_res = abs(comp_turbine.eta_t_stag_p -
                                eta_stag_p_ct) / eta_stag_p_ct
        eta_stag_p_pt_res = abs(power_turbine.eta_t_stag_p -
                                eta_stag_p_pt) / eta_stag_p_pt

        eta_stag_p_c = comp.eta_c_stag_p
        eta_stag_p_ct = comp_turbine.eta_t_stag_p
        eta_stag_p_pt = power_turbine.eta_t_stag_p

        res = max(eta_stag_p_c_res, eta_stag_p_pt_res, eta_stag_p_ct_res)

    return solver, inlet, comp, sink, comb_chamber, comp_turbine, power_turbine, outlet, load, comp_cycle
Exemplo n.º 13
0
    def test_setting_input_data_from_turbine(self):
        turbine = Turbine(turbine_type=TurbineType.Compressor,
                          stage_number=2,
                          T_g_stag=1450,
                          p_g_stag=400e3,
                          G_turbine=25,
                          G_fuel=1,
                          work_fluid=NaturalGasCombustionProducts(),
                          alpha_air=2.6,
                          l1_D1_ratio=0.20,
                          n=15e3,
                          T_t_stag_cycle=1050,
                          eta_t_stag_cycle=0.91,
                          alpha11=np.radians([17])[0],
                          auto_set_rho=False,
                          rho_list=[0.35, 0.45],
                          auto_compute_heat_drop=True,
                          H01_init=220e3,
                          c21_init=250,
                          gamma_in=np.radians([7])[0],
                          gamma_out=np.radians([8])[0],
                          precise_heat_drop=False)

        turbine.geom[0].l1_b_sa_ratio = 2.1
        turbine.geom[0].l2_b_rk_ratio = 2.5
        turbine.geom[0].delta_a_b_sa_ratio = 0.4
        turbine.geom[0].delta_a_b_rk_ratio = 0.35
        turbine.geom[0].p_r_out_l1_ratio = 0.045
        turbine.geom[0].p_r_in_l1_ratio = 0.055
        turbine.geom[0].p_a_out_rel = 0.35
        turbine.geom[0].p_a_in_rel = 0.25
        turbine.geom[0].delta_r_rk_l2_ratio = 0.02
        turbine.geom[0].phi = 0.95
        turbine.geom[0].psi = 0.95
        turbine.geom[0].g_lb = 0.01
        turbine.geom[0].g_ld = 0.02
        turbine.geom[0].g_lk = 0.015
        turbine.geom[0].g_cool = 0.07

        self.form.set_input_from_turbine(turbine)

        self.assertEqual(turbine.stage_number, self.form.stage_number.value())
        self.assertEqual(self.form.turbine_type.currentIndex(), 1)
        self.assertEqual(self.form.fuel.currentIndex(), 1)
        self.assertTrue(self.form.gamma_in_out.isChecked())
        self.assertAlmostEqual(self.form.gamma1.value(), np.degrees(turbine.gamma_out), places=1)
        self.assertAlmostEqual(self.form.gamma2.value(), np.degrees(turbine.gamma_in), places=1)
        self.assertFalse(self.form.checkBox_rho_auto.isChecked())
        self.assertTrue(self.form.checkBox_h0_auto.isChecked())
        self.assertFalse(self.form.checkBox_precise_h0.isChecked())
        self.assertAlmostEqual(self.form.H01_init.value(), turbine.H01_init / 1e3, places=1)
        self.assertAlmostEqual(self.form.c21.value(), turbine.c21_init, places=1)

        self.assertAlmostEqual(self.form.T_g_stag.value(), turbine.T_g_stag, 2)
        self.assertAlmostEqual(self.form.p_g_stag.value(), turbine.p_g_stag / 1e6, places=3)
        self.assertAlmostEqual(self.form.G_t.value(), turbine.G_turbine, places=2)
        self.assertAlmostEqual(self.form.G_fuel.value(), turbine.G_fuel, places=2)
        self.assertAlmostEqual(self.form.alpha11.value(), np.degrees(turbine.alpha11), places=1)
        self.assertAlmostEqual(self.form.l1_D1_ratio.value(), turbine.l1_D1_ratio, places=2)
        self.assertAlmostEqual(self.form.n.value(), turbine.n, places=0)
        self.assertAlmostEqual(self.form.T_t_stag_cycle.value(), turbine.T_t_stag_cycle, places=0)
        self.assertAlmostEqual(self.form.eta_t_stag_cycle.value(), turbine.eta_t_stag_cycle, places=2)

        for i in range(turbine.stage_number):
            stage_data: StageDataWidget = self.form.stackedWidget.widget(i)
            geom = turbine.geom[i]
            self.assertAlmostEqual(stage_data.l1_b_sa_ratio.value(), geom.l1_b_sa_ratio, places=2)
            self.assertAlmostEqual(stage_data.l2_b_rk_ratio.value(), geom.l2_b_rk_ratio, places=2)
            self.assertAlmostEqual(stage_data.delta_a_b_sa_ratio.value(), geom.delta_a_b_sa_ratio, places=2)
            self.assertAlmostEqual(stage_data.delta_a_b_rk_ratio.value(), geom.delta_a_b_rk_ratio, places=2)
            self.assertAlmostEqual(stage_data.p_r_out_l1_ratio.value(), geom.p_r_out_l1_ratio, places=2)
            self.assertAlmostEqual(stage_data.p_r_in_l1_ratio.value(), geom.p_r_in_l1_ratio, places=2)
            self.assertAlmostEqual(stage_data.p_a_out_rel.value(), geom.p_a_out_rel, places=2)
            self.assertAlmostEqual(stage_data.p_a_in_rel.value(), geom.p_a_in_rel, places=2)
            self.assertAlmostEqual(stage_data.delta_r_rel.value(), geom.delta_r_rk_l2_ratio, places=2)
            self.assertAlmostEqual(stage_data.phi.value(), geom.phi, places=2)
            self.assertAlmostEqual(stage_data.psi.value(), geom.psi, places=2)
            self.assertAlmostEqual(stage_data.g_lb.value(), geom.g_lb, places=2)
            self.assertAlmostEqual(stage_data.g_ld.value(), geom.g_ld, places=2)
            self.assertAlmostEqual(stage_data.g_lk.value(), geom.g_lk, places=2)
            self.assertAlmostEqual(stage_data.g_cool.value(), geom.g_cool, places=2)
            self.assertAlmostEqual(stage_data.T_cool.value(), geom.T_cool, places=1)
Exemplo n.º 14
0
 def setUp(self):
     self.comb_chamber = CombustionChamberModel(
         g_fuel=0.02,
         G_c1_in=30,
         T_stag_in=800,
         p_stag_in=13e5,
         G_in=29,
         G_fuel_in=0,
         eta_comb=0.99,
         sigma_comb=0.99,
     )
     self.turbine = Turbine(turbine_type=TurbineType.WORK,
                            stage_number=2,
                            T_g_stag=1400,
                            p_g_stag=15e5,
                            G_turbine=34,
                            G_fuel=0.9,
                            work_fluid=NaturalGasCombustionProducts(),
                            l1_D1_ratio=0.15,
                            n=10e3,
                            T_t_stag_cycle=1150,
                            eta_t_stag_cycle=0.9,
                            alpha11=np.radians(14),
                            precision=0.0001,
                            gamma_in=np.radians(0),
                            gamma_out=np.radians(10),
                            H01_init=200e3,
                            c21_init=250)
     self.turbine.compute_geometry()
     self.turbine.compute_stages_gas_dynamics()
     self.turbine.compute_integrate_turbine_parameters()
     self.turb_model = OutletTurbineModel(
         T_stag_in=self.turbine.T_g_stag,
         p_stag_in=self.turbine.p_g_stag,
         G_in=self.turbine.G_turbine,
         G_fuel_in=self.turbine.G_fuel,
         pi_t_stag=self.turbine.pi_t_stag,
         T_stag_in_nom=self.turbine.T_g_stag,
         p_stag_in_nom=self.turbine.p_g_stag,
         G_in_nom=self.turbine.G_turbine,
         pi_t_stag_nom=self.turbine.pi_t_stag,
         eta_t_stag_nom=self.turbine.eta_t_stag,
         F_out=self.turbine.geom.last.A2,
         eta_m=self.turbine.eta_m,
         precision=self.turbine.precision)
     comp_stage_num = 10
     H_t_rel_dist = QuadraticBezier(0.3,
                                    0.25,
                                    stage_num=comp_stage_num,
                                    angle1=np.radians(10),
                                    angle2=np.radians(10))
     eta_rel_dist = QuadraticBezier(0.84,
                                    0.84,
                                    stage_num=comp_stage_num,
                                    angle1=np.radians(3),
                                    angle2=np.radians(3))
     c1_a_rel_dist = QuadraticBezier(0.4,
                                     0.4,
                                     stage_num=comp_stage_num,
                                     angle1=np.radians(10),
                                     angle2=np.radians(10))
     self.comp = Compressor(
         work_fluid=Air(),
         stage_num=comp_stage_num,
         const_diam_par_arr=[0.5 for _ in range(comp_stage_num)],
         p0_stag=1e5,
         T0_stag=288,
         G=28,
         n=9e3,
         H_t_rel_arr=H_t_rel_dist.get_array(),
         eta_ad_stag_arr=eta_rel_dist.get_array(),
         R_av_arr=[0.5 for _ in range(comp_stage_num)],
         k_h_arr=[1.0 for _ in range(comp_stage_num)],
         c1_a_rel_arr=c1_a_rel_dist.get_array(),
         h_rk_rel_arr=[3.5 for _ in range(comp_stage_num)],
         h_na_rel_arr=[3.5 for _ in range(comp_stage_num)],
         delta_a_rk_rel_arr=[0.4 for _ in range(comp_stage_num)],
         delta_a_na_rel_arr=[0.4 for _ in range(comp_stage_num)],
         d1_in_rel1=0.5,
         zeta_inlet=0.04,
         zeta_outlet=0.03,
         c11_init=200,
         precision=0.0001)
     self.comp.compute()
     self.comp_model = CompressorModel(characteristics=From16To18Pi(),
                                       T_stag_in=self.comp.T0_stag,
                                       p_stag_in=self.comp.p0_stag,
                                       pi_c_stag_rel=1,
                                       n_norm_rel=1,
                                       T_stag_in_nom=self.comp.T0_stag,
                                       p_stag_in_nom=self.comp.p0_stag,
                                       G_in_nom=self.comp.G,
                                       eta_c_stag_nom=self.comp.eta_c_stag,
                                       n_nom=self.comp.n,
                                       pi_c_stag_nom=self.comp.pi_c_stag,
                                       precision=0.0001)
     self.T_stag_in_outlet = np.linspace(300, 1000, 5)
     self.G_in_outlet = np.linspace(2, 40, 5)
     self.dif_outlet = np.linspace(1.1, 10.5, 5)
Exemplo n.º 15
0
    def setUp(self):
        self.precision = 0.00001
        self.comp_turbine_ker_wcool = Turbine(
            TurbineType.WORK,
            T_g_stag=1523,
            p_g_stag=16e5,
            G_turbine=40,
            G_fuel=0.8,
            work_fluid=KeroseneCombustionProducts(),
            l1_D1_ratio=0.25,
            n=13e3,
            T_t_stag_cycle=1000,
            stage_number=3,
            eta_t_stag_cycle=0.90,
            k_n=6.8,
            eta_m=0.99,
            auto_compute_heat_drop=False,
            auto_set_rho=True,
            precise_heat_drop=True,
            precision=self.precision,
            H0_list=[290e3, 290e3, 290e3],
            alpha11=np.radians([17])[0],
            gamma_av=np.radians([4])[0],
            gamma_sum=np.radians([10])[0]
        )
        self.comp_turbine_ker_wcool.compute_geometry()
        self.comp_turbine_ker_wcool.compute_stages_gas_dynamics()
        self.comp_turbine_ker_wcool.compute_integrate_turbine_parameters()

        self.comp_turbine_ngas_wcool = Turbine(
            TurbineType.WORK,
            T_g_stag=1523,
            p_g_stag=16e5,
            G_turbine=40,
            G_fuel=0.8,
            work_fluid=NaturalGasCombustionProducts(),
            l1_D1_ratio=0.25,
            n=13e3,
            T_t_stag_cycle=1000,
            stage_number=3,
            eta_t_stag_cycle=0.90,
            k_n=6.8,
            eta_m=0.99,
            auto_compute_heat_drop=False,
            auto_set_rho=True,
            precise_heat_drop=True,
            precision=self.precision,
            H0_list=[290e3, 290e3, 290e3],
            alpha11=np.radians([17])[0],
            gamma_av=np.radians([4])[0],
            gamma_sum=np.radians([10])[0]
        )
        self.comp_turbine_ngas_wcool.compute_geometry()
        self.comp_turbine_ngas_wcool.compute_stages_gas_dynamics()
        self.comp_turbine_ngas_wcool.compute_integrate_turbine_parameters()

        self.power_turbine_ngas_wcool = Turbine(
            TurbineType.PRESSURE,
            T_g_stag=1523,
            p_g_stag=16e5,
            G_turbine=40,
            G_fuel=0.8,
            work_fluid=NaturalGasCombustionProducts(),
            l1_D1_ratio=0.25,
            n=13e3,
            T_t_stag_cycle=1000,
            stage_number=3,
            eta_t_stag_cycle=0.90,
            k_n=6.8,
            eta_m=0.99,
            auto_compute_heat_drop=False,
            auto_set_rho=True,
            precise_heat_drop=True,
            precision=self.precision,
            H0_list=[290e3, 290e3, 290e3],
            alpha11=np.radians([17])[0],
            gamma_av=np.radians([4])[0],
            gamma_sum=np.radians([10])[0]
        )
        eta_t_res = 1
        eta_t_stag_new = self.power_turbine_ngas_wcool.eta_t_stag_cycle
        self.precision_eta_t = 0.0001
        while eta_t_res >= self.precision_eta_t:
            self.power_turbine_ngas_wcool.eta_t_stag_cycle = eta_t_stag_new
            self.power_turbine_ngas_wcool.compute_geometry()
            self.power_turbine_ngas_wcool.compute_stages_gas_dynamics()
            self.power_turbine_ngas_wcool.compute_integrate_turbine_parameters()
            eta_t_stag_new = self.power_turbine_ngas_wcool.eta_t_stag
            eta_t_stag_old = self.power_turbine_ngas_wcool.eta_t_stag_cycle
            eta_t_res = abs(eta_t_stag_old - eta_t_stag_new) / eta_t_stag_old

        self.comp_turbine_ngas_cool = Turbine(
            TurbineType.WORK,
            T_g_stag=1523,
            p_g_stag=16e5,
            G_turbine=40,
            G_fuel=0.8,
            work_fluid=NaturalGasCombustionProducts(),
            l1_D1_ratio=0.25,
            n=13e3,
            T_t_stag_cycle=1000,
            stage_number=3,
            eta_t_stag_cycle=0.90,
            k_n=6.8,
            eta_m=0.99,
            auto_compute_heat_drop=False,
            auto_set_rho=True,
            precise_heat_drop=True,
            precision=self.precision,
            H0_list=[290e3, 290e3, 290e3],
            alpha11=np.radians([17])[0],
            gamma_av=np.radians([4])[0],
            gamma_sum=np.radians([10])[0]
        )
        self.comp_turbine_ngas_cool.geom[0].g_cool = 0.05
        self.comp_turbine_ngas_cool.geom[1].g_cool = 0.05
        self.comp_turbine_ngas_cool.geom[2].g_cool = 0.01
        self.comp_turbine_ngas_cool.compute_geometry()
        self.comp_turbine_ngas_cool.compute_stages_gas_dynamics()
        self.comp_turbine_ngas_cool.compute_integrate_turbine_parameters()
Exemplo n.º 16
0
    def setUp(self):
        self.atmosphere = Atmosphere()
        self.inlet = Inlet()
        self.compressor = Compressor(17, precision=0.001)
        self.sink = Sink(g_cooling=0.05, g_outflow=0.01)
        self.comb_chamber = CombustionChamber(1450,
                                              alpha_out_init=2.7,
                                              precision=0.001)
        self.comb_chamber_inter_up = CombustionChamber(1300,
                                                       alpha_out_init=2.7,
                                                       precision=0.001)
        self.comb_chamber_inter_down = CombustionChamber(1300,
                                                         alpha_out_init=2.7,
                                                         precision=0.001,
                                                         p_stag_out_init=4e5)
        self.source = Source(g_return=0.05)
        self.turbine_low_pres_power = Turbine(p_stag_out_init=1e5)
        self.turbine_comp_up = Turbine()
        self.outlet = Outlet()
        self.N_gen = 10e6
        self.eta_gen = 0.97
        self.load = Load(self.N_gen / self.eta_gen)
        self.zero_load1 = Load(0)
        self.zero_load2 = Load(0)
        self.solver = NetworkSolver(
            [
                self.atmosphere, self.outlet, self.turbine_comp_up, self.sink,
                self.turbine_low_pres_power, self.source, self.inlet,
                self.comb_chamber, self.compressor, self.load, self.zero_load1,
                self.zero_load2
            ],
            cold_work_fluid=Air(),
            hot_work_fluid=NaturalGasCombustionProducts())
        self.solver.create_gas_dynamic_connection(self.atmosphere, self.inlet)
        self.solver.create_gas_dynamic_connection(self.inlet, self.compressor)
        self.solver.create_gas_dynamic_connection(self.compressor, self.sink)
        self.solver.create_gas_dynamic_connection(self.sink, self.comb_chamber)
        self.solver.create_gas_dynamic_connection(self.comb_chamber,
                                                  self.turbine_comp_up)
        self.solver.create_gas_dynamic_connection(self.turbine_comp_up,
                                                  self.source)
        self.solver.create_gas_dynamic_connection(self.source,
                                                  self.turbine_low_pres_power)
        self.solver.create_gas_dynamic_connection(self.turbine_low_pres_power,
                                                  self.outlet)
        self.solver.create_static_gas_dynamic_connection(
            self.outlet, self.atmosphere)
        self.solver.create_mechanical_connection(self.turbine_low_pres_power,
                                                 self.load, self.zero_load1)
        self.solver.create_mechanical_connection(self.turbine_comp_up,
                                                 self.compressor,
                                                 self.zero_load2)
        self.solver.solve()

        self.N_e_specific = self.load.consumable_labour
        self.G_air = self.load.power / self.N_e_specific
        self.G_fuel = self.comb_chamber.g_fuel_prime * self.comb_chamber.g_in * self.G_air
        self.c_p_nat_gas_av = 2.3e3
        self.k_nat_gas_av = 1.31
        self.press_in_gas_comp = 1.3e6
        self.T_in_gas_comp = 288
        self.eta_ad_gas_comp = 0.82
        self.eta_el_eng = 0.95
        self.mass_rate_gas_comp = self.G_fuel
        self.press_out_gas_comp = self.compressor.p_stag_out + 0.5e6
        self.pi_gas_comp = self.press_out_gas_comp / self.press_in_gas_comp
        self.rho_gas_comp = 6.9867 + (10.587 - 6.9867) / (1.5e6 - 1e6) * (
            self.press_in_gas_comp - 1e6)
        self.vol_rate_gas_comp = self.mass_rate_gas_comp / self.rho_gas_comp * 60
        self.T_out_gas_comp = self.T_in_gas_comp * (1 + (self.pi_gas_comp**(
            (self.k_nat_gas_av - 1) / self.k_nat_gas_av) - 1) /
                                                    self.eta_ad_gas_comp)
        self.L_e_gas_comp = self.c_p_nat_gas_av * (self.T_out_gas_comp -
                                                   self.T_in_gas_comp)
        self.N_gas_comp = self.L_e_gas_comp / (self.mass_rate_gas_comp *
                                               self.eta_el_eng)
Exemplo n.º 17
0
    def setUp(self):
        self.precision = 0.0005
        self.comp_turb_h0_auto = Turbine(TurbineType.WORK,
                                         T_g_stag=1523,
                                         p_g_stag=16e5,
                                         G_turbine=40,
                                         G_fuel=0.8,
                                         work_fluid=KeroseneCombustionProducts(),
                                         l1_D1_ratio=0.25,
                                         n=13e3,
                                         T_t_stag_cycle=1100,
                                         stage_number=2,
                                         eta_t_stag_cycle=0.91,
                                         k_n=6.8,
                                         eta_m=0.99,
                                         auto_compute_heat_drop=True,
                                         auto_set_rho=True,
                                         precise_heat_drop=False,
                                         precision=self.precision,
                                         H01_init=150e3,
                                         c21_init=250,
                                         alpha11=np.radians([17])[0],
                                         gamma_av=np.radians([4])[0],
                                         gamma_sum=np.radians([10])[0])
        self.comp_turb_h0_auto.geom[0].g_cool = 0.03
        self.comp_turb_h0_auto.geom[0].g_lb = 0.00
        self.comp_turb_h0_auto.geom[0].g_lk = 0.00
        self.comp_turb_h0_auto.geom[0].g_ld = 0.00
        self.comp_turb_h0_auto.geom[0].T_cool = 750
        self.comp_turb_h0_auto.geom[1].g_cool = 0.03
        self.comp_turb_h0_auto.compute_geometry()
        self.comp_turb_h0_auto.compute_stages_gas_dynamics()
        self.comp_turb_h0_auto.compute_integrate_turbine_parameters()

        self.comp_turb_h0_hand = Turbine(TurbineType.WORK,
                                         T_g_stag=1523,
                                         p_g_stag=16e5,
                                         G_turbine=40,
                                         G_fuel=0.8,
                                         work_fluid=NaturalGasCombustionProducts(),
                                         l1_D1_ratio=0.12,
                                         n=13e3,
                                         T_t_stag_cycle=1100,
                                         stage_number=2,
                                         eta_t_stag_cycle=0.91,
                                         k_n=6.8,
                                         eta_m=0.99,
                                         auto_compute_heat_drop=False,
                                         auto_set_rho=True,
                                         precise_heat_drop=False,
                                         H0_list=[160e3, 140e3],
                                         alpha11=np.radians([17])[0],
                                         gamma_av=np.radians([4])[0],
                                         gamma_sum=np.radians([10])[0])
        self.comp_turb_h0_hand.compute_geometry()
        self.comp_turb_h0_hand.compute_stages_gas_dynamics()
        self.comp_turb_h0_hand.compute_integrate_turbine_parameters()

        self.comp_turb_rho_hand = Turbine(TurbineType.WORK,
                                          T_g_stag=1400,
                                          p_g_stag=5.5e5,
                                          G_turbine=25,
                                          G_fuel=1,
                                          work_fluid=KeroseneCombustionProducts(),
                                          l1_D1_ratio=0.25,
                                          n=15e3,
                                          T_t_stag_cycle=1200,
                                          stage_number=2,
                                          eta_t_stag_cycle=0.91,
                                          k_n=6.8,
                                          eta_m=0.99,
                                          auto_compute_heat_drop=True,
                                          auto_set_rho=False,
                                          precise_heat_drop=False,
                                          rho_list=[0.45, 0.4],
                                          H01_init=150e3,
                                          c21_init=250,
                                          alpha11=np.radians([17])[0],
                                          gamma_av=np.radians([4])[0],
                                          gamma_sum=np.radians([10])[0])
        self.comp_turb_rho_hand.compute_geometry()
        self.comp_turb_rho_hand.compute_stages_gas_dynamics()
        self.comp_turb_rho_hand.compute_integrate_turbine_parameters()

        self.power_turb_h0_auto = Turbine(TurbineType.PRESSURE,
                                          T_g_stag=1400,
                                          p_g_stag=5.5e5,
                                          G_turbine=25,
                                          G_fuel=1,
                                          work_fluid=NaturalGasCombustionProducts(),
                                          l1_D1_ratio=0.25,
                                          n=15e3,
                                          T_t_stag_cycle=1200,
                                          stage_number=3,
                                          eta_t_stag_cycle=0.91,
                                          k_n=6.8,
                                          eta_m=0.99,
                                          auto_compute_heat_drop=True,
                                          auto_set_rho=True,
                                          precise_heat_drop=False,
                                          H01_init=150e3,
                                          c21_init=250,
                                          alpha11=np.radians([17])[0],
                                          gamma_in=np.radians([0])[0],
                                          gamma_out=np.radians([10])[0])
        self.power_turb_h0_auto.compute_geometry()
        self.power_turb_h0_auto.compute_stages_gas_dynamics()
        self.power_turb_h0_auto.compute_integrate_turbine_parameters()