Ejemplo n.º 1
0
    def setup(self):
        """Set up network for electrolyzer tests."""
        self.nw = Network(['O2', 'H2', 'H2O'], T_unit='C', p_unit='bar')
        self.instance = WaterElectrolyzer('electrolyzer')

        fw = Source('feed water')
        cw_in = Source('cooling water')
        o2 = Sink('oxygen sink')
        h2 = Sink('hydrogen sink')
        cw_out = Sink('cooling water sink')

        self.instance.set_attr(pr=0.99, eta=1)

        cw_el = Connection(cw_in,
                           'out1',
                           self.instance,
                           'in1',
                           fluid={
                               'H2O': 1,
                               'H2': 0,
                               'O2': 0
                           },
                           T=20,
                           p=1)
        el_cw = Connection(self.instance, 'out1', cw_out, 'in1', T=45)

        self.nw.add_conns(cw_el, el_cw)

        fw_el = Connection(fw, 'out1', self.instance, 'in2', label='h2o')
        el_o2 = Connection(self.instance, 'out2', o2, 'in1')
        el_h2 = Connection(self.instance, 'out3', h2, 'in1', label='h2')

        self.nw.add_conns(fw_el, el_o2, el_h2)
Ejemplo n.º 2
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def test_wrong_Bus_param_func():
    """Test missing/wrong bus parameter specification in equations."""
    # this test does not need setup, since the function is called without
    # network initialisation
    instance = WaterElectrolyzer('electrolyzer')
    some_bus = Bus('some_bus')
    param = 'G'
    some_bus.add_comps({'comp': instance, 'param': param})
    with raises(ValueError):
        instance.bus_func(some_bus.comps.loc[instance])
Ejemplo n.º 3
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def test_wrong_Bus_param_deriv():
    """Test missing/wrong bus parameter specification in derivatives."""
    # this test does not need setup, since the function is called without
    # network initialisation
    instance = WaterElectrolyzer('electrolyzer')
    # required for calling bus_deriv method without network initialisation
    instance.num_vars = 1
    instance.num_nw_fluids = 1
    instance.num_nw_vars = 1
    some_bus = Bus('some_bus')
    param = 'G'
    some_bus.add_comps({'comp': instance, 'param': param})
    with raises(ValueError):
        instance.bus_deriv(some_bus)
Ejemplo n.º 4
0
    def setup_electrolyzer_Network(self):
        """Set up Network for electrolyzer tests."""
        self.instance = WaterElectrolyzer('electrolyzer')

        fw = Source('feed water')
        cw_in = Source('cooling water')
        o2 = Sink('oxygen sink')
        h2 = Sink('hydrogen sink')
        cw_out = Sink('cooling water sink')

        cw_el = Connection(cw_in, 'out1', self.instance, 'in1')
        el_cw = Connection(self.instance, 'out1', cw_out, 'in1')

        self.nw.add_conns(cw_el, el_cw)

        fw_el = Connection(fw, 'out1', self.instance, 'in2')
        el_o2 = Connection(self.instance, 'out2', o2, 'in1')
        el_h2 = Connection(self.instance, 'out3', h2, 'in1')

        self.nw.add_conns(fw_el, el_o2, el_h2)
Ejemplo n.º 5
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class TestReactors:
    def setup(self):
        """Set up network for electrolyzer tests."""
        self.nw = Network(['O2', 'H2', 'H2O'], T_unit='C', p_unit='bar')
        self.instance = WaterElectrolyzer('electrolyzer')

        fw = Source('feed water')
        cw_in = Source('cooling water')
        o2 = Sink('oxygen sink')
        h2 = Sink('hydrogen sink')
        cw_out = Sink('cooling water sink')

        self.instance.set_attr(pr=0.99, eta=1)

        cw_el = Connection(cw_in,
                           'out1',
                           self.instance,
                           'in1',
                           fluid={
                               'H2O': 1,
                               'H2': 0,
                               'O2': 0
                           },
                           T=20,
                           p=1)
        el_cw = Connection(self.instance, 'out1', cw_out, 'in1', T=45)

        self.nw.add_conns(cw_el, el_cw)

        fw_el = Connection(fw, 'out1', self.instance, 'in2', label='h2o')
        el_o2 = Connection(self.instance, 'out2', o2, 'in1')
        el_h2 = Connection(self.instance, 'out3', h2, 'in1', label='h2')

        self.nw.add_conns(fw_el, el_o2, el_h2)

    def test_WaterElectrolyzer(self):
        """Test component properties of water electrolyzer."""
        # check bus function:
        # power output on component and bus must be indentical
        self.nw.get_conn('h2o').set_attr(T=25, p=1)
        self.nw.get_conn('h2').set_attr(T=25)
        power = Bus('power')
        power.add_comps({'comp': self.instance, 'param': 'P', 'base': 'bus'})
        power.set_attr(P=2.5e6)
        self.nw.add_busses(power)

        self.nw.solve('design')
        convergence_check(self.nw.lin_dep)
        msg = ('Value of power must be ' + str(power.P.val) + ', is ' +
               str(self.instance.P.val) + '.')
        assert round(power.P.val, 1) == round(self.instance.P.val), msg

        # effieciency was set to 100 % with inlet and outlet states of the
        # reaction educts and products beeing identical to reference state
        # therefore Q must be equal to 0
        msg = ('Value of heat output must be 0.0, is ' +
               str(self.instance.Q.val) + '.')
        assert round(self.instance.Q.val, 4) == 0.0, msg

        # reset power, change efficiency value and specify heat bus value
        power.set_attr(P=np.nan)
        self.nw.get_conn('h2o').set_attr(T=25, p=1)
        self.nw.get_conn('h2').set_attr(T=50)
        self.instance.set_attr(eta=0.8)
        # check bus function:
        # heat output on component and bus must be indentical
        heat = Bus('heat')
        heat.add_comps({'comp': self.instance, 'param': 'Q'})
        heat.set_attr(P=-8e5)
        self.nw.add_busses(heat)

        self.nw.solve('design')
        convergence_check(self.nw.lin_dep)
        msg = ('Value of heat flow must be ' + str(heat.P.val) + ', is ' +
               str(self.instance.Q.val) + '.')
        assert round(heat.P.val, 1) == round(self.instance.Q.val), msg
        self.nw.save('tmp')

        # check bus function:
        # heat output on component and bus must identical (offdesign test)
        Q = heat.P.val * 0.9
        heat.set_attr(P=Q)
        self.nw.solve('offdesign', design_path='tmp')
        convergence_check(self.nw.lin_dep)
        msg = ('Value of heat flow must be ' + str(Q) + ', is ' +
               str(self.instance.Q.val) + '.')
        assert round(Q, 1) == round(self.instance.Q.val), msg

        # delete both busses again
        self.nw.del_busses(heat, power)

        # test efficiency vs. specific energy consumption
        self.nw.get_conn('h2').set_attr(m=0.1)
        self.instance.set_attr(eta=0.9, e='var')
        self.nw.solve('design')
        convergence_check(self.nw.lin_dep)
        msg = ('Value of efficiency must be ' + str(self.instance.eta.val) +
               ', is ' + str(self.instance.e0 / self.instance.e.val) + '.')
        eta = round(self.instance.eta.val, 2)
        eta_calc = round(self.instance.e0 / self.instance.e.val, 2)
        assert eta == eta_calc, msg

        # test efficiency value > 1, Q must be larger than 0
        e = 130e6
        self.instance.set_attr(e=np.nan, eta=np.nan)
        self.instance.set_attr(e=e)
        self.nw.solve('design')
        convergence_check(self.nw.lin_dep)
        # test efficiency
        msg = ('Value of efficiency must be ' + str(self.instance.e0 / e) +
               ', is ' + str(self.instance.eta.val) + '.')
        eta = round(self.instance.e0 / e, 2)
        eta_calc = round(self.instance.eta.val, 2)
        assert eta == eta_calc, msg
        # test Q
        msg = ('Value of heat must be larger than zero, is ' +
               str(self.instance.Q.val) + '.')
        assert self.instance.Q.val > 0, msg

        # test specific energy consumption
        e = 150e6
        self.instance.set_attr(e=np.nan, eta=np.nan)
        self.instance.set_attr(e=e)
        self.nw.solve('design')
        convergence_check(self.nw.lin_dep)
        msg = ('Value of specific energy consumption e must be ' + str(e) +
               ', is ' + str(self.instance.e.val) + '.')
        assert round(e, 1) == round(self.instance.e.val, 1), msg

        # test cooling loop pressure ratio, zeta as variable value
        pr = 0.95
        self.instance.set_attr(pr=pr,
                               e=None,
                               eta=None,
                               zeta='var',
                               P=2e7,
                               design=['pr'])
        self.nw.solve('design')
        shutil.rmtree('./tmp', ignore_errors=True)
        self.nw.save('tmp')
        convergence_check(self.nw.lin_dep)
        msg = ('Value of pressure ratio must be ' + str(pr) + ', is ' +
               str(self.instance.pr.val) + '.')
        assert round(pr, 2) == round(self.instance.pr.val, 2), msg

        # use zeta as offdesign parameter, at design point pressure
        # ratio must not change
        self.instance.set_attr(zeta=np.nan, offdesign=['zeta'])
        self.nw.solve('offdesign', design_path='tmp')
        convergence_check(self.nw.lin_dep)
        msg = ('Value of pressure ratio must be ' + str(pr) + ', is ' +
               str(self.instance.pr.val) + '.')
        assert round(pr, 2) == round(self.instance.pr.val, 2), msg

        # test heat output specification in offdesign mode
        Q = self.instance.Q.val * 0.9
        self.instance.set_attr(Q=Q, P=np.nan)
        self.nw.solve('offdesign', design_path='tmp')
        convergence_check(self.nw.lin_dep)
        msg = ('Value of heat must be ' + str(Q) + ', is ' +
               str(self.instance.Q.val) + '.')
        assert round(Q, 0) == round(self.instance.Q.val, 0), msg
        shutil.rmtree('./tmp', ignore_errors=True)