sys.add_connection(z1, z2)
    sys.add_connection(z2, z3)
    sys.add_connection(z3, z0)

    f_42 = 1.4e-7
    f_45 = 7.66e-7
    w_r = f_42 / (f_42 + f_45)

    f_63 = 1.54e-7
    f_67 = 8.08e-7

    w_e = f_63 / (f_63 + f_67)

    sys.set_output_state(z0, [w_r, 1 - w_r])
    sys.set_output_state(z2, [w_e, 1 - w_e])

    sys.switch_time = 180

    fs = sys.build_flow_sheet()
    proc = sys.build_process()

    from CADETProcess.simulation import Cadet
    process_simulator = Cadet(
        cadet_bin_path='/home/jo/software/cadet/cadet4.2.0/bin/',
        temp_dir='/dev/shm')
    process_simulator.evaluate_stationarity = True
    process_simulator.n_cycles = 1
    process_simulator.solver_parameters.NTHREADS = 1

    proc_results = process_simulator.simulate(proc, file_path='new.h5')
Exemple #2
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ssr_binary.add_event('recycle_on', 'flow_sheet.column.output_state', 0)
ssr_binary.add_event('recycle_off', 'flow_sheet.column.output_state', 1)

ssr_binary.add_event_dependency('feed_on', ['inject_off'])
ssr_binary.add_event_dependency('feed_off', ['feed_on', 'feed_duration'],
                                [1, 1])
ssr_binary.add_event_dependency(
    'inject_off', ['inject_on', 'feed_duration', 'recycle_off', 'recycle_on'],
    [1, 1, 1, -1])

# Set process times
ssr_binary.cycle_time = 191.11
ssr_binary.feed_duration.time = 42.956
ssr_binary.recycle_on.time = 354.081
ssr_binary.recycle_off.time = 358.552

if __name__ == '__main__':
    from CADETProcess.simulation import Cadet
    process_simulator = Cadet()
    process_simulator.evaluate_stationarity = True
    process_simulator.n_cycles_min = 4
    ssr_binary_sim_results = process_simulator.simulate(ssr_binary)
    ssr_binary_sim_results.save(case_dir)

    from CADETProcess.fractionation import optimize_fractionation
    ssr_binary_frac = optimize_fractionation(
        ssr_binary_sim_results.chromatograms,
        ssr_binary.process_meta,
        purity_required=0.95)
    ssr_binary_frac.save(case_dir)
Exemple #3
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## Create Events and Durations
Q = 2.88e-8
feed_duration = 7500.0
gradient_start = 9500.0
gradient_slope = Q / (lwe.cycle_time - gradient_start)

lwe.add_event('feed_on', 'flow_sheet.feed.flow_rate', Q)
lwe.add_event('feed_off', 'flow_sheet.feed.flow_rate', 0.0)
lwe.add_duration('feed_duration', time=feed_duration)
lwe.add_event_dependency('feed_off', ['feed_on', 'feed_duration'], [1, 1])

lwe.add_event('eluent_initialization', 'flow_sheet.eluent.flow_rate', 0)
lwe.add_event('eluent_salt_initialization', 'flow_sheet.eluent_salt.flow_rate',
              0)

lwe.add_event('wash', 'flow_sheet.eluent.flow_rate', Q, time=feed_duration)
lwe.add_event_dependency('wash', ['feed_off'])

lwe.add_event('neg_grad_start', 'flow_sheet.eluent.flow_rate',
              [Q, -gradient_slope], gradient_start)
lwe.add_event('pos_grad_start', 'flow_sheet.eluent_salt.flow_rate',
              [0, gradient_slope])
lwe.add_event_dependency('pos_grad_start', ['neg_grad_start'])

if __name__ == '__main__':
    from CADETProcess.simulation import Cadet
    process_simulator = Cadet()

    lwe_sim_results = process_simulator.simulate(lwe)
    lwe_sim_results.solution.outlet.outlet.plot()
Exemple #4
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def simulate_solid_equilibria(binding_model,
                              buffer,
                              unit_model='cstr',
                              flush=None):
    process_name = flow_sheet_name = 'initial_conditions'
    component_system = binding_model.component_system

    # Unit Operations
    buffer_source = Source(component_system, name='buffer')
    buffer_source.c = buffer

    if flush is None:
        flush = buffer
    flush_source = Source(component_system, 'flush')
    flush_source.c = flush

    if unit_model == 'cstr':
        unit = Cstr(component_system, 'cstr')
        unit.porosity = 0.5
        unit.V = 1e-6

        Q = 1e-6
        cycle_time = 1000 * unit.volume / Q
        unit.flow_rate = Q
    elif unit_model == 'column':
        unit = LumpedRateModelWithoutPores(component_system, name='column')
        unit.length = 0.1
        unit.diameter = 0.01
        unit.axial_dispersion = 1e-6
        unit.total_porosity = 0.7

        Q = 60 / (60 * 1e6)
        cycle_time = 10 * unit.volume / Q

    try:
        q = binding_model.n_comp * binding_model.n_states * [0]
        q[0] = binding_model.capacity
        unit.q = q
    except AttributeError:
        pass

    unit.binding_model = binding_model

    outlet = Sink(component_system, name='outlet')

    # flow sheet
    fs = FlowSheet(component_system, name=flow_sheet_name)

    fs.add_unit(buffer_source)
    fs.add_unit(flush_source)
    fs.add_unit(unit)
    fs.add_unit(outlet, chromatogram_sink=True)

    fs.add_connection(buffer_source, unit)
    fs.add_connection(flush_source, unit)
    fs.add_connection(unit, outlet)

    # Process
    proc = Process(fs, name=process_name)

    proc.cycle_time = cycle_time

    ## Create Events and Durations
    proc.add_event('buffer_on', 'flow_sheet.buffer.flow_rate', Q)
    proc.add_event('buffer_off', 'flow_sheet.buffer.flow_rate', 0,
                   0.9 * cycle_time)

    proc.add_event('eluent_off', 'flow_sheet.flush.flow_rate', 0.0, 0.0)
    proc.add_event('eluent_on', 'flow_sheet.flush.flow_rate', Q,
                   0.9 * cycle_time)

    # Simulator
    process_simulator = Cadet()
    process_simulator.unit_return_parameters.write_solution_bulk = True
    process_simulator.unit_return_parameters.write_solution_solid = True

    proc_results = process_simulator.simulate(proc)

    if unit_model == 'cstr':
        init_q = proc_results.solution[unit.name].solid.solution[-1, :]
    elif unit_model == 'column':
        init_q = proc_results.solution[unit.name].solid.solution[-1, 0, :]

    return init_q.tolist()
batch_long_ternary.add_event('feed_on', 'flow_sheet.feed.flow_rate', Q)
batch_long_ternary.add_event('feed_off', 'flow_sheet.feed.flow_rate', 0.0)
batch_long_ternary.add_duration('feed_duration', 'feed_on', 'feed_off')

batch_long_ternary.add_event('eluent_on', 'flow_sheet.eluent.flow_rate', Q)
batch_long_ternary.add_event('eluent_off', 'flow_sheet.eluent.flow_rate', 0.0)

batch_long_ternary.add_event_dependency('eluent_on', ['feed_off'])
batch_long_ternary.add_event_dependency('eluent_off', ['feed_on'])
batch_long_ternary.add_event_dependency('feed_off',
                                        ['feed_on', 'feed_duration'], [1, 1])

batch_long_ternary.cycle_time = 135.134
batch_long_ternary.feed_duration.time = 16.268

if __name__ == '__main__':
    from CADETProcess.simulation import Cadet
    process_simulator = Cadet()
    process_simulator.evaluate_stationarity = True

    batch_long_ternary_sim_results = process_simulator.simulate(
        batch_long_ternary)
    batch_long_ternary_sim_results.save(case_dir)

    from CADETProcess.fractionation import optimize_fractionation
    batch_long_ternary_frac = optimize_fractionation(
        batch_long_ternary_sim_results.chromatograms,
        batch_long_ternary.process_meta,
        purity_required=[0, 0.95, 0])
    batch_long_ternary_frac.save(case_dir)
Exemple #6
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                                  [1, 1])

## Set process times
batch_binary.cycle_time = 176.45
batch_binary.feed_duration.time = 51.95

x = [374.4299005082142, 118.65641374452873]
batch_binary.cycle_time = x[0]
batch_binary.feed_duration.time = x[1]

if __name__ == '__main__':
    from CADETProcess.simulation import Cadet
    process_simulator = Cadet()

    process_simulator.evaluate_stationarity = False
    process_simulator.n_cycles = 4

    batch_binary_sim_results = process_simulator.simulate(batch_binary)

    from CADETProcess.fractionation import FractionationOptimizer
    purity_required = [0.95, 0.95]
    frac_opt = FractionationOptimizer(purity_required)

    batch_binary_frac = frac_opt.optimize_fractionation(
        batch_binary_sim_results.chromatograms,
        batch_binary.process_meta,
    )

    batch_binary_frac.plot_fraction_signal()
    performance = batch_binary_frac.performance
    print(performance)
Exemple #7
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serial_ternary.add_event('serial_on', 'flow_sheet.column_1.output_state', 1)
serial_ternary.add_event('serial_off', 'flow_sheet.column_1.output_state', 0)

serial_ternary.add_event('eluent_2_on', 'flow_sheet.eluent_2.flow_rate', Q)
serial_ternary.add_event('eluent_2_off', 'flow_sheet.eluent_2.flow_rate', 0.0)

serial_ternary.add_event_dependency('eluent_2_on', ['serial_off'], [1])
serial_ternary.add_event_dependency('eluent_2_off', ['serial_on'], [1])

# Set process times
serial_ternary.cycle_time = 210.121
serial_ternary.feed_duration.time = 45.859
serial_ternary.serial_on.time = 119.017
serial_ternary.serial_off.time = 47.634

if __name__ == '__main__':
    from CADETProcess.simulation import Cadet
    process_simulator = Cadet()
    process_simulator.evaluate_stationarity = True

    serial_ternary_sim_results = process_simulator.simulate(serial_ternary)
    serial_ternary_sim_results.save(case_dir)

    from CADETProcess.fractionation import optimize_fractionation
    serial_ternary_frac = optimize_fractionation(
        serial_ternary_sim_results.chromatograms,
        serial_ternary.process_meta,
        purity_required=[0.95, 0.95, 0])
    serial_ternary_frac.save(case_dir)