def test_inner_recycle_loop_with_bifurcated_feed():
    f.set_flowsheet('simple_recycle_loop_with_bifurcated_feed')
    settings.set_thermo(['Water'], cache=True)
    feedstock = Stream('feedstock', Water=1000)
    water = Stream('water', Water=10)
    recycle = Stream('recycle')
    product = Stream('product')
    side_product = Stream('side_product')
    P1 = Pump('P1', feedstock)
    P2 = Pump('P2', water)
    S1 = Splitter('S1', P2 - 0, split=0.5)
    M1 = Mixer('M1', [P1 - 0, S1 - 1, recycle])
    S2 = Splitter('S2', M1 - 0, [side_product, ''], split=0.5)
    M2 = Mixer('M2', [S1 - 0, S2 - 1])
    S3 = Splitter('S3', M2 - 0, [product, recycle], split=0.5)
    recycle_loop_sys = f.create_system('recycle_loop_sys')
    network = recycle_loop_sys.to_network()
    actual_network = Network(
        [P1, P2, S1, Network([M1, S2, M2, S3], recycle=S3 - 1)])
    assert network == actual_network
    recycle_loop_sys.simulate()
    x_nested_solution = recycle.mol.copy()
    recycle_loop_sys.flatten()
    assert recycle_loop_sys.path == (P1, P2, S1, M1, S2, M2, S3)
    recycle_loop_sys.empty_recycles()
    recycle_loop_sys.simulate()
    x_flat_solution = recycle.mol.copy()
    assert_allclose(x_nested_solution, x_flat_solution, rtol=1e-2)
    f.clear()
def test_feed_forward_recycle_loop():
    f.set_flowsheet('feed_forward_recycle_loop')
    settings.set_thermo(['Water'], cache=True)
    feedstock = Stream('feedstock', Water=1000)
    water = Stream('water', Water=10)
    recycle = Stream('recycle')
    inner_recycle = Stream('inner_recycle')
    product = Stream('product')
    P1 = Pump('P1', feedstock)
    P2 = Pump('P2', water)
    M1 = Mixer('M1', [P1 - 0, recycle, inner_recycle])
    S1 = Splitter('S1', M1 - 0, ['', recycle], split=0.5)
    M2 = Mixer('M2', [P2 - 0, S1 - 0])
    S2 = Splitter('S2', M2 - 0, [inner_recycle, product], split=0.5)
    P3 = Pump('P3', product)
    recycle_loop_sys = f.create_system('recycle_loop_sys')
    network = recycle_loop_sys.to_network()
    actual_network = (Network(
        [P1, P2,
         Network([M1, S1, M2, S2], recycle={S2 - 0, S1 - 1}), P3]))
    assert network == actual_network
    recycle_loop_sys.simulate()
    x_nested_solution = np.vstack([recycle.mol, inner_recycle.mol])
    recycle_loop_sys.flatten()
    assert recycle_loop_sys.path == (P1, P2, M1, S1, M2, S2, P3)
    recycle_loop_sys.empty_recycles()
    recycle_loop_sys.simulate()
    x_flat_solution = np.vstack([recycle.mol, inner_recycle.mol])
    assert_allclose(x_nested_solution, x_flat_solution, rtol=1e-2)
    f.clear()
def test_two_recycle_loops_with_complete_overlap():
    f.set_flowsheet('two_recycle_loops_with_complete_overlap')
    settings.set_thermo(['Water'], cache=True)
    feedstock = Stream('feedstock', Water=1000)
    water = Stream('water', Water=10)
    recycle = Stream('recycle')
    inner_recycle = Stream('inner_recycle')
    product = Stream('product')
    inner_water = Stream('inner_water', Water=10)
    P1 = Pump('P1', feedstock)
    P2 = Pump('P2', water)
    P3 = Pump('P3', inner_water)
    M1 = Mixer('M1', [P1 - 0, P2 - 0, recycle])
    M2 = Mixer('M2', [M1 - 0, P3 - 0, inner_recycle])
    S2 = Splitter('S2', M2 - 0, ['', inner_recycle], split=0.5)
    S1 = Splitter('S1', S2 - 0, [product, recycle], split=0.5)
    recycle_loop_sys = f.create_system('recycle_loop_sys')
    network = recycle_loop_sys.to_network()
    actual_network = Network([
        P1, P2, P3,
        Network([M1, Network([M2, S2], recycle=inner_recycle), S1],
                recycle=recycle)
    ])
    assert network == actual_network
    recycle_loop_sys.simulate()
    x_nested_solution = np.vstack([recycle.mol, inner_recycle.mol])
    recycle_loop_sys.flatten()
    assert recycle_loop_sys.path == (P1, P2, P3, M1, M2, S2, S1)
    recycle_loop_sys.empty_recycles()
    recycle_loop_sys.simulate()
    x_flat_solution = np.vstack([recycle.mol, inner_recycle.mol])
    assert_allclose(x_nested_solution, x_flat_solution, rtol=1e-2)
    f.clear()
def test_unconnected_recycle_loops():
    f.set_flowsheet('unconnected_recycle_loops')
    settings.set_thermo(['Water'], cache=True)
    feedstock_a = Stream('feedstock_a', Water=1000)
    water_a = Stream('water_a', Water=10)
    recycle_a = Stream('recycle_a')
    product_a = Stream('product_a')
    M1_a = Mixer('M1_a', [feedstock_a, water_a, recycle_a])
    S1_a = Splitter('S1_a', M1_a - 0, [product_a, recycle_a], split=0.5)

    feedstock_b = Stream('feedstock_b', Water=800)
    water_b = Stream('water_b', Water=10)
    recycle_b = Stream('recycle_b')
    product_b = Stream('product_b')
    M1_b = Mixer('M1_b', [feedstock_b, water_b, recycle_b])
    S1_b = Splitter('S1_b', M1_b - 0, [product_b, recycle_b], split=0.5)
    recycle_loop_sys = f.create_system('recycle_loop_sys')
    network = recycle_loop_sys.to_network()
    actual_network = Network([
        Network([M1_a, S1_a], recycle=S1_a - 1),
        Network([M1_b, S1_b], recycle=S1_b - 1)
    ])
    assert network == actual_network
    recycle_loop_sys.simulate()
    x_nested_solution = np.vstack([recycle_a.mol, recycle_b.mol])
    recycle_loop_sys.flatten()
    assert recycle_loop_sys.path == (M1_a, S1_a, M1_b, S1_b)
    recycle_loop_sys.empty_recycles()
    recycle_loop_sys.simulate()
    x_flat_solution = np.vstack([recycle_a.mol, recycle_b.mol])
    assert_allclose(x_nested_solution, x_flat_solution, rtol=1e-2)
    f.clear()
def test_unconnected_case():
    f.set_flowsheet('unconnected_case')
    settings.set_thermo(['Water'], cache=True)
    feedstock_a = Stream('feedstock_a', Water=1000)
    water_a = Stream('water_a', Water=10)
    byproduct_a = Stream('byproduct_a')
    product_a = Stream('product_a')
    M1_a = Mixer('M1_a', [feedstock_a, water_a])
    S1_a = Splitter('S1_a', M1_a - 0, [product_a, byproduct_a], split=0.5)

    feedstock_b = Stream('feedstock_b', Water=1000)
    water_b = Stream('water_b', Water=10)
    byproduct_b = Stream('byproduct_b')
    product_b = Stream('product_b')
    M1_b = Mixer('M1_b', [feedstock_b, water_b])
    S1_b = Splitter('S1_b', M1_b - 0, [product_b, byproduct_b], split=0.5)
    parallel_sys = f.create_system('parallel_sys')
    network = parallel_sys.to_network()
    actual_network = Network([M1_a, S1_a, M1_b, S1_b])
    assert network == actual_network
    parallel_sys.simulate()
    parallel_sys.flatten()
    assert parallel_sys.path == (M1_a, S1_a, M1_b, S1_b)
    parallel_sys.empty_recycles()
    parallel_sys.simulate()
    f.clear()
def test_bifurcated_recycle_loops():
    f.set_flowsheet('bifurcated_recycle_loops')
    settings.set_thermo(['Water'], cache=True)
    feed_a = Stream('feed_a', Water=10)
    water_a = Stream('water_a', Water=10)
    recycle_a = Stream('recycle_a')
    P1_a = Pump('P1_a', feed_a)
    P2_a = Pump('P2_a', water_a)
    S1_a = Splitter('S1_a', P2_a - 0, split=0.5)
    M1_a = Mixer('M1_a', [P1_a - 0, S1_a - 1, recycle_a])
    S2_a = Splitter('S2_a', M1_a - 0, split=0.5)
    M2_a = Mixer('M2_a', [S1_a - 0, S2_a - 1])
    S3_a = Splitter('S3_a', M2_a - 0, ['', recycle_a], split=0.5)

    feedstock_b = Stream('feedstock_b', Water=1000)
    recycle_b = Stream('recycle_b')
    product_b = Stream('product_b')
    side_product_b = Stream('side_product_b')
    P1_b = Pump('P1_b', feedstock_b)
    P2_b = Pump('P2_b', S2_a - 0)
    S1_b = Splitter('S1_b', P2_b - 0, split=0.5)
    M1_b = Mixer('M1_b', [P1_b - 0, S1_b - 1, recycle_b])
    S2_b = Splitter('S2_b', M1_b - 0, [side_product_b, ''], split=0.5)
    M2_b = Mixer('M2_b', [S1_b - 0, S2_b - 1, S3_a - 0])
    S3_b = Splitter('S3_b', M2_b - 0, [product_b, recycle_b], split=0.5)
    recycle_loop_sys = f.create_system('recycle_loop_sys')
    network = recycle_loop_sys.to_network()
    actual_network = Network([
        P1_b, P1_a, P2_a, S1_a,
        Network([M1_a, S2_a, M2_a, S3_a], recycle=S3_a - 1), P2_b, S1_b,
        Network([M1_b, S2_b, M2_b, S3_b], recycle=S3_b - 1)
    ])
    assert network == actual_network
    recycle_loop_sys.simulate()
    x_nested_solution = np.vstack([recycle_a.mol, recycle_b.mol])
    recycle_loop_sys.flatten()
    assert recycle_loop_sys.path == (P1_b, P1_a, P2_a, S1_a, M1_a, S2_a, M2_a,
                                     S3_a, P2_b, S1_b, M1_b, S2_b, M2_b, S3_b)
    recycle_loop_sys.empty_recycles()
    recycle_loop_sys.simulate()
    x_flat_solution = np.vstack([recycle_a.mol, recycle_b.mol])
    assert_allclose(x_nested_solution, x_flat_solution, rtol=1e-2)
    f.clear()
Exemplo n.º 7
0
def test_sugarcane_ethanol_biorefinery_network():
    from biorefineries.sugarcane import flowsheet as f
    sugarcane_sys = f.create_system('sugarcane_sys')
    globals().update(f.unit.data)
    network = sugarcane_sys.to_network()
    actual_network = Network([
        U101, U102, U103, T201,
        Network([U201, S201, M201],
                recycle=M201 - 0), T202, H201, T203, P201, T204, T205, P202,
        Network([M202, H202, T206, C201, C202, P203], recycle=P203 - 0), S202,
        S301, F301, P306, M301, H301, T305, R301, T301, C301, D301, M302, P301,
        Network([H302, D302, P302], recycle=P302 - 0),
        Network([M303, D303, H303, U301], recycle=U301 - 0), H304, T302, P304,
        T303, P305, M304, T304, P303, M305, U202
    ])
    assert network == actual_network
    sugarcane_sys.empty_recycles()
    sugarcane_sys.simulate()
    bst.process_tools.default()
def test_separate_recycle_loops():
    f.set_flowsheet('separate_recycle_loops')
    settings.set_thermo(['Water'], cache=True)
    feedstock_a = Stream('feedstock_a', Water=1000)
    water_a = Stream('water_a', Water=10)
    recycle_a = Stream('recycle_a')
    product_a = Stream('product_a')
    P1_a = Pump('P1_a', feedstock_a)
    P2_a = Pump('P2_a', water_a)
    M1_a = Mixer('M1_a', [P1_a - 0, P2_a - 0, recycle_a])
    S1_a = Splitter('S1_a', M1_a - 0, [product_a, recycle_a], split=0.5)
    feedstock_b = Stream('feedstock_b', Water=1000)
    water_b = Stream('water_b', Water=10)
    recycle_b = Stream('recycle_b')
    product_b = Stream('product_b')
    P1_b = Pump('P1_b', feedstock_b)
    P2_b = Pump('P2_b', water_b)
    M1_b = Mixer('M1_b', [P1_b - 0, P2_b - 0, recycle_b])
    S1_b = Splitter('S1_b', M1_b - 0, [product_b, recycle_b], split=0.5)
    recycles = [recycle_a, recycle_b]
    recycle_loop_sys = f.create_system('recycle_loop_sys')
    recycle_loop_sys.simulate()
    network = recycle_loop_sys.to_network()
    actual_network = Network([
        P1_a, P2_a,
        Network([M1_a, S1_a], recycle=S1_a - 1), P1_b, P2_b,
        Network([M1_b, S1_b], recycle=S1_b - 1)
    ])
    assert network == actual_network
    x_nested_solution = np.vstack([i.mol for i in recycles])
    recycle_loop_sys.flatten()
    recycle_loop_sys.empty_recycles()
    recycle_loop_sys.simulate()
    x_flat_solution = np.vstack([i.mol for i in recycles])
    assert_allclose(x_nested_solution, x_flat_solution, rtol=1e-2)
    assert recycle_loop_sys.path == (P1_a, P2_a, M1_a, S1_a, P1_b, P2_b, M1_b,
                                     S1_b)
    f.clear()
Exemplo n.º 9
0
def test_inner_recycle_loop():
    f.set_flowsheet('simple_recycle_loop')
    settings.set_thermo(['Water'], cache=True)
    feedstock = Stream('feedstock', Water=1000)
    water = Stream('water', Water=10)
    recycle = Stream('recycle')
    product = Stream('product')
    P1 = Pump('P1', feedstock)
    P2 = Pump('P2', water)
    M1 = Mixer('M1', [P1 - 0, P2 - 0, recycle])
    S1 = Splitter('S1', M1 - 0, [product, recycle], split=0.5)
    recycle_loop_sys = f.create_system('recycle_loop_sys')
    network = recycle_loop_sys.to_network()
    actual_network = Network([P1, P2, Network([M1, S1], recycle=recycle)])
    assert network == actual_network
    recycle_loop_sys.simulate()
    x_nested_solution = recycle.mol.copy()
    recycle_loop_sys.flatten()
    assert recycle_loop_sys.path == (P1, P2, M1, S1)
    recycle_loop_sys.empty_recycles()
    recycle_loop_sys.simulate()
    x_flat_solution = recycle.mol.copy()
    assert_allclose(x_nested_solution, x_flat_solution, rtol=1e-2)
def test_trivial_case():
    f.set_flowsheet('trivial_case')
    settings.set_thermo(['Water'], cache=True)
    trivial_sys_a = f.create_system('trivial_sys_a')
    network_a = trivial_sys_a.to_network()
    Stream('feedstock', Water=1000)
    Stream('water', Water=10)
    trivial_sys_b = f.create_system('trivial_sys_b')
    network_b = trivial_sys_b.to_network()
    actual_network = Network([])
    assert network_a == network_b == actual_network
    trivial_sys_b.simulate()
    trivial_sys_b.flatten()
    assert trivial_sys_b.path == ()
    trivial_sys_b.empty_recycles()
    trivial_sys_b.simulate()
    f.clear()
def test_linear_case():
    f.set_flowsheet('linear_case')
    settings.set_thermo(['Water'], cache=True)
    feedstock = Stream('feedstock', Water=1000)
    water = Stream('water', Water=10)
    byproduct = Stream('byproduct')
    product = Stream('product')
    M1 = Mixer('M1', [feedstock, water])
    S1 = Splitter('S1', M1 - 0, [product, byproduct], split=0.5)
    linear_sys = f.create_system('linear_sys')
    network = linear_sys.to_network()
    actual_network = Network([M1, S1])
    assert network == actual_network
    linear_sys.simulate()
    linear_sys.flatten()
    assert linear_sys.path == (M1, S1)
    linear_sys.empty_recycles()
    linear_sys.simulate()
    f.clear()
def test_nested_recycle_loops():
    f.set_flowsheet('nested_recycle_loops')
    settings.set_thermo(['Water'], cache=True)
    feedstock = Stream('feedstock', Water=1000)
    recycle_1, recycle_2, recycle_3, recycle_4, recycle_5 = recycles = [
        Stream('recycle_1'),
        Stream('recycle_2'),
        Stream('recycle_3'),
        Stream('recycle_4'),
        Stream('recycle_5'),
    ]
    feed_1 = Stream('feed_1', Water=10)
    feed_2 = Stream('feed_2', Water=10)
    feed_3 = Stream('feed_3', Water=10)
    feed_4 = Stream('feed_4', Water=10)
    inner_recycle = Stream('inner_recycle')
    product = Stream('product')
    P1 = Pump('P1', feedstock)
    M1 = Mixer('M1', [P1 - 0, recycle_1])
    P2 = Pump('P2', M1 - 0)
    H1 = HXprocess('H1', [P2 - 0, recycle_2])
    P3 = Pump('P3', feed_1)
    M3 = Mixer('M3', [H1 - 0, P3 - 0], recycle_2)
    P4 = Pump('P4', H1 - 1)
    M4 = Mixer('M4', [P4 - 0, recycle_3])
    P5 = Pump('P5', feed_2)
    P6 = Pump('P6', feed_3)
    M5 = Mixer('M5', [M4 - 0, P5 - 0, P6 - 0])
    H2 = HXprocess('H2', [M5 - 0, recycle_4])
    P7 = Pump('P7', feed_4)
    M6 = Mixer('M6', [H2 - 0, P7 - 0])
    S1 = Splitter('S1', M6 - 0, [recycle_4, ''], split=0.5)
    S2 = Splitter('S2', H2 - 1, split=0.5)
    P8 = Pump('P8', S2 - 1)
    S3 = Splitter('S3', P8 - 0, split=0.5)
    H3 = HXprocess('H3', [S2 - 0, recycle_5], ['', recycle_3])
    M7 = Mixer('M7', [H3 - 0, S3 - 0])
    S4 = Splitter('S4', M7 - 0, ['', recycle_5], split=0.5)
    S5 = Splitter('S5', S4 - 0, ['', recycle_1], split=0.5)
    M8 = Mixer('M8', [S3 - 1, S1 - 1, S5 - 0], product)
    recycle_loop_sys = f.create_system('recycle_loop_sys')
    recycle_loop_sys.simulate()
    network = recycle_loop_sys.to_network()
    actual_network = Network([
        P1, P3, P5, P6, P7,
        Network([
            M1, P2,
            Network([H1, M3], recycle=M3 - 0), P4,
            Network([
                M4, M5,
                Network([H2, M6, S1], recycle=S1 - 0), S2,
                Network([M7, S4, H3], recycle=H3 - 0), P8, S3
            ],
                    recycle=H3 - 1), S5
        ],
                recycle=S5 - 1), M8
    ])
    assert network == actual_network
    x_nested_solution = np.vstack([i.mol for i in recycles])
    recycle_loop_sys.flatten()
    recycle_loop_sys.empty_recycles()
    recycle_loop_sys.simulate()
    x_flat_solution = np.vstack([i.mol for i in recycles])
    assert_allclose(x_nested_solution, x_flat_solution, rtol=5e-2)
    f.clear()