#################################################################################
# WaterTAP Copyright (c) 2020-2024, The Regents of the University of California,
# through Lawrence Berkeley National Laboratory, Oak Ridge National Laboratory,
# National Renewable Energy Laboratory, and National Energy Technology
# Laboratory (subject to receipt of any required approvals from the U.S. Dept.
# of Energy). All rights reserved.
#
# Please see the files COPYRIGHT.md and LICENSE.md for full copyright and license
# information, respectively. These files are also available online at the URL
# "https://github.com/watertap-org/watertap/"
#################################################################################
# Import Pyomo libraries
from pyomo.environ import Suffix, check_optimal_termination
from pyomo.common.config import ConfigBlock, ConfigValue, In
# Import IDAES cores
from idaes.core import (
ControlVolume0DBlock,
declare_process_block_class,
MaterialBalanceType,
EnergyBalanceType,
MomentumBalanceType,
UnitModelBlockData,
useDefault,
)
from watertap.core.solvers import get_solver
from idaes.core.util.config import is_physical_parameter_block
from idaes.core.util.exceptions import InitializationError
from idaes.core.util.model_statistics import degrees_of_freedom
import idaes.core.util.scaling as iscale
import idaes.logger as idaeslog
from watertap.core import InitializationMixin
_log = idaeslog.getLogger(__name__)
[docs]@declare_process_block_class("Condenser")
class CompressorData(InitializationMixin, UnitModelBlockData):
"""
Condenser model for MVC
"""
# CONFIG are options for the unit model, this simple model only has the mandatory config options
CONFIG = ConfigBlock()
CONFIG.declare(
"dynamic",
ConfigValue(
domain=In([False]),
default=False,
description="Dynamic model flag - must be False",
doc="""Indicates whether this model will be dynamic or not,
**default** = False. The filtration unit does not support dynamic
behavior, thus this must be False.""",
),
)
CONFIG.declare(
"has_holdup",
ConfigValue(
default=False,
domain=In([False]),
description="Holdup construction flag - must be False",
doc="""Indicates whether holdup terms should be constructed or not.
**default** - False. The filtration unit does not have defined volume, thus
this must be False.""",
),
)
CONFIG.declare(
"property_package",
ConfigValue(
default=useDefault,
domain=is_physical_parameter_block,
description="Property package to use for control volume",
doc="""Property parameter object used to define property calculations,
**default** - useDefault.
**Valid values:** {
**useDefault** - use default package from parent model or flowsheet,
**PhysicalParameterObject** - a PhysicalParameterBlock object.}""",
),
)
CONFIG.declare(
"property_package_args",
ConfigBlock(
implicit=True,
description="Arguments to use for constructing property packages",
doc="""A ConfigBlock with arguments to be passed to a property block(s)
and used when constructing these,
**default** - None.
**Valid values:** {
see property package for documentation.}""",
),
)
CONFIG.declare(
"material_balance_type",
ConfigValue(
default=MaterialBalanceType.useDefault,
domain=In(MaterialBalanceType),
description="Material balance construction flag",
doc="""Indicates what type of mass balance should be constructed,
**default** - MaterialBalanceType.useDefault.
**Valid values:** {
**MaterialBalanceType.useDefault - refer to property package for default
balance type
**MaterialBalanceType.none** - exclude material balances,
**MaterialBalanceType.componentPhase** - use phase component balances,
**MaterialBalanceType.componentTotal** - use total component balances,
**MaterialBalanceType.elementTotal** - use total element balances,
**MaterialBalanceType.total** - use total material balance.}""",
),
)
CONFIG.declare(
"energy_balance_type",
ConfigValue(
default=EnergyBalanceType.useDefault,
domain=In(EnergyBalanceType),
description="Energy balance construction flag",
doc="""Indicates what type of energy balance should be constructed,
**default** - EnergyBalanceType.useDefault.
**Valid values:** {
**EnergyBalanceType.useDefault - refer to property package for default
balance type
**EnergyBalanceType.none** - exclude energy balances,
**EnergyBalanceType.enthalpyTotal** - single enthalpy balance for material,
**EnergyBalanceType.enthalpyPhase** - enthalpy balances for each phase,
**EnergyBalanceType.energyTotal** - single energy balance for material,
**EnergyBalanceType.energyPhase** - energy balances for each phase.}""",
),
)
CONFIG.declare(
"momentum_balance_type",
ConfigValue(
default=MomentumBalanceType.pressureTotal,
domain=In(MomentumBalanceType),
description="Momentum balance construction flag",
doc="""Indicates what type of momentum balance should be constructed,
**default** - MomentumBalanceType.pressureTotal.
**Valid values:** {
**MomentumBalanceType.none** - exclude momentum balances,
**MomentumBalanceType.pressureTotal** - single pressure balance for material,
**MomentumBalanceType.pressurePhase** - pressure balances for each phase,
**MomentumBalanceType.momentumTotal** - single momentum balance for material,
**MomentumBalanceType.momentumPhase** - momentum balances for each phase.}""",
),
)
[docs] def build(self):
super().build()
# this creates blank scaling factors, which are populated later
self.scaling_factor = Suffix(direction=Suffix.EXPORT)
# Next, get the base units of measurement from the property definition
units_meta = self.config.property_package.get_metadata().get_derived_units
# Add control volume
self.control_volume = ControlVolume0DBlock(
dynamic=False,
has_holdup=False,
property_package=self.config.property_package,
property_package_args=self.config.property_package_args,
)
self.control_volume.add_state_blocks(has_phase_equilibrium=False)
# complete condensation mass balance
@self.control_volume.Constraint(
self.flowsheet().time,
self.config.property_package.component_list,
doc="Mass balance",
)
def mass_balance(b, t, j):
lb = b.properties_out[t].get_material_flow_terms("Vap", j).lb
b.properties_out[t].get_material_flow_terms("Vap", j).fix(lb)
return b.properties_in[t].get_material_flow_terms(
"Vap", j
) + b.properties_in[t].get_material_flow_terms(
"Liq", j
) == b.properties_out[
t
].get_material_flow_terms(
"Liq", j
)
self.control_volume.add_energy_balances(
balance_type=self.config.energy_balance_type, has_heat_transfer=True
)
self.control_volume.add_momentum_balances(
balance_type=self.config.momentum_balance_type
)
# # Add constraints
@self.Constraint(self.flowsheet().time, doc="Saturation pressure constraint")
def eq_condenser_pressure_sat(b, t):
return (
b.control_volume.properties_out[t].pressure
>= b.control_volume.properties_out[t].pressure_sat
)
# Add ports
self.add_port(name="inlet", block=self.control_volume.properties_in)
self.add_port(name="outlet", block=self.control_volume.properties_out)
[docs] def initialize_build(
self,
state_args=None,
outlvl=idaeslog.NOTSET,
solver=None,
optarg=None,
hold_state=False,
heat=None,
):
"""
General wrapper for pressure changer initialization routines
Keyword Arguments:
state_args : a dict of arguments to be passed to the property
package(s) to provide an initial state for
initialization (see documentation of the specific
property package) (default = {}).
outlvl : sets output level of initialization routine
optarg : solver options dictionary object (default=None)
solver : str indicating which solver to use during
initialization (default = None)
hold_state : boolean indicating if the inlet conditions should stay fixed
heat : inital guess for heat transfer out of condenser (negative)
Returns: None
"""
init_log = idaeslog.getInitLogger(self.name, outlvl, tag="unit")
solve_log = idaeslog.getSolveLogger(self.name, outlvl, tag="unit")
# Set solver options
opt = get_solver(solver, optarg)
# ---------------------------------------------------------------------
# Initialize control volume
flags = self.control_volume.initialize(
outlvl=outlvl,
optarg=optarg,
solver=solver,
state_args=state_args,
)
init_log.info_high("Initialization Step 1 Complete.")
# # ---------------------------------------------------------------------
# check if guess is needed for the heat based on degrees of freedom
has_guessed_heat = False
if degrees_of_freedom(self) > 1:
raise RuntimeError(
"The model has {} degrees of freedom rather than 0 or 1 (with a guessed heat) for initialization."
" This error suggests that an outlet condition has not been fixed"
" for initialization.".format(degrees_of_freedom(self))
)
elif degrees_of_freedom(self) == 1:
if heat is not None:
self.control_volume.heat.fix(heat)
has_guessed_heat = True
else:
raise RuntimeError(
"The model has 1 degree of freedom rather than 0 for initialization."
" A common error for this model is not providing a guess for heat in the initialization."
)
# Solve unit
with idaeslog.solver_log(solve_log, idaeslog.DEBUG) as slc:
res = opt.solve(self, tee=slc.tee)
init_log.info_high("Initialization Step 2 {}.".format(idaeslog.condition(res)))
# ---------------------------------------------------------------------
if hold_state:
pass
else:
# Release Inlet state
self.control_volume.release_state(flags, outlvl=outlvl)
init_log.info("Initialization Complete: {}".format(idaeslog.condition(res)))
if has_guessed_heat:
self.control_volume.heat.unfix()
if not check_optimal_termination(res):
raise InitializationError(f"Unit model {self.name} failed to initialize")
return flags
def _get_performance_contents(self, time_point=0):
var_dict = {"Heat duty": self.control_volume.heat[time_point]}
return {"vars": var_dict}
def calculate_scaling_factors(self):
super().calculate_scaling_factors()
for (t, j), c in self.control_volume.mass_balance.items():
sf = iscale.get_scaling_factor(
self.control_volume.properties_in[t].flow_mass_phase_comp["Vap", j]
)
iscale.constraint_scaling_transform(c, sf)