def build(self):
super().build()
config = self.config # sorter ref to config for less line splitting
# All feedwater heaters have a condensing section
_set_prop_pack(config.condense, config)
self.condense = FWHCondensing0D(default=config.condense)
# Add a mixer to add the drain stream from another feedwater heater
if config.has_drain_mixer:
mix_cfg = {
"dynamic": False,
"inlet_list": ["steam", "drain"],
"property_package": config.property_package,
"momentum_mixing_type": MomentumMixingType.none,
}
self.drain_mix = Mixer(default=mix_cfg)
@self.drain_mix.Constraint(self.drain_mix.flowsheet().config.time)
def mixer_pressure_constraint(b, t):
"""
Constraint to set the drain mixer pressure to the pressure of
the steam extracted from the turbine. The drain inlet should
always be a higher pressure than the steam inlet.
"""
return b.steam_state[t].pressure == b.mixed_state[t].pressure
# Connect the mixer to the condensing section inlet
self.SMX = Arc(source=self.drain_mix.outlet,
destination=self.condense.inlet_1)
# Add a desuperheat section before the condensing section
if config.has_desuperheat:
_set_prop_pack(config.desuperheat, config)
self.desuperheat = HeatExchanger(default=config.desuperheat)
# set default area less than condensing section area, this will
# almost always be overridden by the user fixing an area later
self.desuperheat.area.value = 10
if config.has_drain_mixer:
self.SDS = Arc(source=self.desuperheat.outlet_1,
destination=self.drain_mix.steam)
else:
self.SDS = Arc(source=self.desuperheat.outlet_1,
destination=self.condense.inlet_1)
self.FW2 = Arc(source=self.condense.outlet_2,
destination=self.desuperheat.inlet_2)
# Add a drain cooling section after the condensing section
if config.has_drain_cooling:
_set_prop_pack(config.cooling, config)
self.cooling = HeatExchanger(default=config.cooling)
# set default area less than condensing section area, this will
# almost always be overridden by the user fixing an area later
self.cooling.area.value = 10
self.FW1 = Arc(source=self.cooling.outlet_2,
destination=self.condense.inlet_2)
self.SC = Arc(source=self.condense.outlet_1,
destination=self.cooling.inlet_1)
TransformationFactory("network.expand_arcs").apply_to(self)
def declare_heatx_unit(h):
"""
Declare all units of the heat exchanger network.
Optional keyword arguments:
---------------------------
:param h: the heat exchanger network
:return: return the heat exchanger network
"""
h.fs = FlowsheetBlock(default={"dynamic": False})
h.fs.thermo_params = thermo_props.MethaneParameterBlock()
h.fs.Split2 = Separator(default={
"dynamic": False,
"num_outlets": 3,
"property_package": h.fs.thermo_params
})
h.fs.HX1a = HeatExchanger(
default={
"dynamic": False,
"delta_temperature_callback": delta_temperature_amtd_callback,
"shell": {
"property_package": h.fs.thermo_params
},
"tube": {
"property_package": h.fs.thermo_params
}
})
h.fs.HX2a = HeatExchanger(
default={
"dynamic": False,
"delta_temperature_callback": delta_temperature_amtd_callback,
"shell": {
"property_package": h.fs.thermo_params
},
"tube": {
"property_package": h.fs.thermo_params
}
})
h.fs.HX2b = HeatExchanger(
default={
"dynamic": False,
"delta_temperature_callback": delta_temperature_amtd_callback,
"shell": {
"property_package": h.fs.thermo_params
},
"tube": {
"property_package": h.fs.thermo_params
}
})
h.fs.HX1b = Heater(default={"property_package": h.fs.thermo_params})
return h
def test_flowsheet_serializer_get_unit_model_type():
from idaes.core import MaterialBalanceType
from idaes.generic_models.unit_models.pressure_changer import (
ThermodynamicAssumption, )
from idaes.generic_models.unit_models.heat_exchanger import (
delta_temperature_underwood_callback, )
from idaes.generic_models.properties import iapws95
from pyomo.environ import Set
# flowsheet
m = ConcreteModel(name="My Model")
m.fs = FlowsheetBlock(default={"dynamic": False})
m.fs.prop_water = iapws95.Iapws95ParameterBlock(
default={"phase_presentation": iapws95.PhaseType.LG})
# add & test scalar unit model
m.fs.cond_pump = PressureChanger(
default={
"property_package": m.fs.prop_water,
"material_balance_type": MaterialBalanceType.componentTotal,
"thermodynamic_assumption": ThermodynamicAssumption.pump,
})
unit_type = FlowsheetSerializer.get_unit_model_type(m.fs.cond_pump)
assert unit_type == "pressure_changer"
# add & test indexed unit model
m.set_fwh = Set(initialize=[1, 2, 3, 4, 6, 7, 8])
m.fs.fwh = HeatExchanger(m.set_fwh,
default={
"delta_temperature_callback":
delta_temperature_underwood_callback,
"shell": {
"property_package": m.fs.prop_water,
"material_balance_type":
MaterialBalanceType.componentTotal,
"has_pressure_change": True,
},
"tube": {
"property_package": m.fs.prop_water,
"material_balance_type":
MaterialBalanceType.componentTotal,
"has_pressure_change": True,
},
})
unit_type = FlowsheetSerializer.get_unit_model_type(m.fs.fwh)
assert unit_type == "heat_exchanger"
def create_model():
"""Create the flowsheet and add unit models. Fixing model inputs is done
in a separate function to try to keep this fairly clean and easy to follow.
Args:
None
Returns:
(ConcreteModel) Steam cycle model
"""
############################################################################
# Flowsheet and Properties #
############################################################################
m = pyo.ConcreteModel(name="Steam Cycle Model")
m.fs = FlowsheetBlock(default={"dynamic":
False}) # Add steady state flowsheet
# A physical property parameter block for IAPWS-95 with pressure and enthalpy
# (PH) state variables. Usually pressure and enthalpy state variables are
# more robust especially when the phases are unknown.
m.fs.prop_water = iapws95.Iapws95ParameterBlock(
default={"phase_presentation": iapws95.PhaseType.MIX})
# A physical property parameter block with temperature, pressure and vapor
# fraction (TPx) state variables. There are a few instances where the vapor
# fraction is known and the temperature and pressure state variables are
# preferable.
m.fs.prop_water_tpx = iapws95.Iapws95ParameterBlock(
default={
"phase_presentation": iapws95.PhaseType.LG,
"state_vars": iapws95.StateVars.TPX,
})
############################################################################
# Turbine with fill-in reheat constraints #
############################################################################
# The TurbineMultistage class allows creation of the full turbine model by
# providing several configuration options, including: throttle valves;
# high-, intermediate-, and low-pressure sections; steam extractions; and
# pressure driven flow. See the IDAES documentation for details.
m.fs.turb = HelmTurbineMultistage(
default={
"property_package": m.fs.prop_water,
"num_parallel_inlet_stages": 4, # number of admission arcs
"num_hp": 7, # number of high-pressure stages
"num_ip": 10, # number of intermediate-pressure stages
"num_lp": 11, # number of low-pressure stages
"hp_split_locations": [4, 7], # hp steam extraction locations
"ip_split_locations": [5, 10], # ip steam extraction locations
"lp_split_locations": [4, 8, 10, 11
], # lp steam extraction locations
"hp_disconnect": [7], # disconnect hp from ip to insert reheater
"ip_split_num_outlets": {
10: 3
}, # number of split streams (default is 2)
})
# This model is only the steam cycle, and the reheater is part of the boiler.
# To fill in the reheater gap, a few constraints for the flow, pressure drop,
# and outlet temperature are added. A detailed boiler model can be coupled later.
#
# hp_split[7] is the splitter directly after the last HP stage. The splitter
# outlet "outlet_1" is always taken to be the main steam flow through the turbine.
# When the turbine model was instantiated the stream from the HP section to the IP
# section was omitted, so the reheater could be inserted.
# The flow constraint sets flow from outlet_1 of the splitter equal to
# flow into the IP turbine.
@m.fs.turb.Constraint(m.fs.time)
def constraint_reheat_flow(b, t):
return b.ip_stages[1].inlet.flow_mol[t] == b.hp_split[
7].outlet_1.flow_mol[t]
# Create a variable for pressure change in the reheater (assuming
# reheat_delta_p should be negative).
m.fs.turb.reheat_delta_p = pyo.Var(m.fs.time,
initialize=0,
units=pyo.units.Pa)
# Add a constraint to calculate the IP section inlet pressure based on the
# pressure drop in the reheater and the outlet pressure of the HP section.
@m.fs.turb.Constraint(m.fs.time)
def constraint_reheat_press(b, t):
return (b.ip_stages[1].inlet.pressure[t] ==
b.hp_split[7].outlet_1.pressure[t] + b.reheat_delta_p[t])
# Create a variable for reheat temperature and fix it to the desired reheater
# outlet temperature
m.fs.turb.reheat_out_T = pyo.Var(m.fs.time,
initialize=866,
units=pyo.units.K)
# Create a constraint for the IP section inlet temperature.
@m.fs.turb.Constraint(m.fs.time)
def constraint_reheat_temp(b, t):
return (b.ip_stages[1].control_volume.properties_in[t].temperature ==
b.reheat_out_T[t])
############################################################################
# Add Condenser/hotwell/condensate pump #
############################################################################
# Add a mixer for all the streams coming into the condenser. In this case the
# main steam, and the boiler feed pump turbine outlet go to the condenser
m.fs.condenser_mix = HelmMixer(
default={
"momentum_mixing_type": MomentumMixingType.none,
"inlet_list": ["main", "bfpt"],
"property_package": m.fs.prop_water,
})
# The pressure in the mixer comes from the connection to the condenser. All
# the streams coming in and going out of the mixer are equal, but we created
# the mixer with no calculation for the unit pressure. Here a constraint that
# specifies that the mixer pressure is equal to the main steam pressure is
# added. There is also a constraint that specifies the that BFP turbine outlet
# pressure is the same as the condenser pressure. Combined with the stream
# connections between units, these constraints effectively specify that the
# mixer inlet and outlet streams all have the same pressure.
@m.fs.condenser_mix.Constraint(m.fs.time)
def mixer_pressure_constraint(b, t):
return b.main_state[t].pressure == b.mixed_state[t].pressure
# The condenser model uses the physical property model with TPx state
# variables, while the rest of the model uses PH state variables. To
# translate between the two property calculations, an extra port is added to
# the mixer which contains temperature, pressure, and vapor fraction
# quantities.
m.fs.condenser_mix.outlet_tpx = Port(
initialize={
"flow_mol":
pyo.Reference(m.fs.condenser_mix.mixed_state[:].flow_mol),
"temperature":
pyo.Reference(m.fs.condenser_mix.mixed_state[:].temperature),
"pressure":
pyo.Reference(m.fs.condenser_mix.mixed_state[:].pressure),
"vapor_frac":
pyo.Reference(m.fs.condenser_mix.mixed_state[:].vapor_frac),
})
# Add the heat exchanger model for the condenser.
m.fs.condenser = HeatExchanger(
default={
"delta_temperature_callback": delta_temperature_underwood_callback,
"shell": {
"property_package": m.fs.prop_water_tpx
},
"tube": {
"property_package": m.fs.prop_water
},
})
m.fs.condenser.delta_temperature_out.fix(5)
# Everything condenses so the saturation pressure determines the condenser
# pressure. Deactivate the constraint that is used in the TPx version vapor
# fraction constraint and fix vapor fraction to 0.
m.fs.condenser.shell.properties_out[:].eq_complementarity.deactivate()
m.fs.condenser.shell.properties_out[:].vapor_frac.fix(0)
# There is some subcooling in the condenser, so we assume the condenser
# pressure is actually going to be slightly higher than the saturation
# pressure.
m.fs.condenser.pressure_over_sat = pyo.Var(
m.fs.time,
initialize=500,
doc="Pressure added to Psat in the condeser. This is to account for"
"some subcooling. (Pa)",
units=pyo.units.Pa)
# Add a constraint for condenser pressure
@m.fs.condenser.Constraint(m.fs.time)
def eq_pressure(b, t):
return (b.shell.properties_out[t].pressure ==
b.shell.properties_out[t].pressure_sat +
b.pressure_over_sat[t])
# Extra port on condenser to hook back up to pressure-enthalpy properties
m.fs.condenser.outlet_1_ph = Port(
initialize={
"flow_mol":
pyo.Reference(m.fs.condenser.shell.properties_out[:].flow_mol),
"pressure":
pyo.Reference(m.fs.condenser.shell.properties_out[:].pressure),
"enth_mol":
pyo.Reference(m.fs.condenser.shell.properties_out[:].enth_mol),
})
# Add the condenser hotwell. In steady state a mixer will work. This is
# where makeup water is added if needed.
m.fs.hotwell = HelmMixer(
default={
"momentum_mixing_type": MomentumMixingType.none,
"inlet_list": ["condensate", "makeup"],
"property_package": m.fs.prop_water,
})
# The hotwell is assumed to be at the same pressure as the condenser.
@m.fs.hotwell.Constraint(m.fs.time)
def mixer_pressure_constraint(b, t):
return b.condensate_state[t].pressure == b.mixed_state[t].pressure
# Condensate pump (Use compressor model, since it is more robust if vapor form)
m.fs.cond_pump = HelmIsentropicCompressor(
default={"property_package": m.fs.prop_water})
############################################################################
# Add low pressure feedwater heaters #
############################################################################
# All the feedwater heater sections will be set to use the Underwood
# approximation for LMTD, so create the fwh_config dict to make the config
# slightly cleaner
fwh_config = {
"delta_temperature_callback": delta_temperature_underwood_callback
}
# The feedwater heater model allows feedwater heaters with a desuperheat,
# condensing, and subcooling section to be added an a reasonably simple way.
# See the IDAES documentation for more information of configuring feedwater
# heaters
m.fs.fwh1 = FWH0D(
default={
"has_desuperheat": False,
"has_drain_cooling": False,
"has_drain_mixer": True,
"property_package": m.fs.prop_water,
"condense": fwh_config,
})
# pump for fwh1 condensate, to pump it ahead and mix with feedwater
m.fs.fwh1_pump = HelmIsentropicCompressor(
default={"property_package": m.fs.prop_water})
# Mix the FWH1 drain back into the feedwater
m.fs.fwh1_return = HelmMixer(
default={
"momentum_mixing_type": MomentumMixingType.none,
"inlet_list": ["feedwater", "fwh1_drain"],
"property_package": m.fs.prop_water,
})
# Set the mixer pressure to the feedwater pressure
@m.fs.fwh1_return.Constraint(m.fs.time)
def mixer_pressure_constraint(b, t):
return b.feedwater_state[t].pressure == b.mixed_state[t].pressure
# Add the rest of the low pressure feedwater heaters
m.fs.fwh2 = FWH0D(
default={
"has_desuperheat": True,
"has_drain_cooling": True,
"has_drain_mixer": True,
"property_package": m.fs.prop_water,
"desuperheat": fwh_config,
"cooling": fwh_config,
"condense": fwh_config,
})
m.fs.fwh3 = FWH0D(
default={
"has_desuperheat": True,
"has_drain_cooling": True,
"has_drain_mixer": True,
"property_package": m.fs.prop_water,
"desuperheat": fwh_config,
"cooling": fwh_config,
"condense": fwh_config,
})
m.fs.fwh4 = FWH0D(
default={
"has_desuperheat": True,
"has_drain_cooling": True,
"has_drain_mixer": False,
"property_package": m.fs.prop_water,
"desuperheat": fwh_config,
"cooling": fwh_config,
"condense": fwh_config,
})
############################################################################
# Add deaerator and boiler feed pump (BFP) #
############################################################################
# The deaerator is basically an open tank with multiple inlets. For steady-
# state, a mixer model is sufficient.
m.fs.fwh5_da = HelmMixer(
default={
"momentum_mixing_type": MomentumMixingType.none,
"inlet_list": ["steam", "drain", "feedwater"],
"property_package": m.fs.prop_water,
})
@m.fs.fwh5_da.Constraint(m.fs.time)
def mixer_pressure_constraint(b, t):
# Not sure about deaerator pressure, so assume same as feedwater inlet
return b.feedwater_state[t].pressure == b.mixed_state[t].pressure
# Add the boiler feed pump and boiler feed pump turbine
m.fs.bfp = HelmIsentropicCompressor(
default={"property_package": m.fs.prop_water})
m.fs.bfpt = HelmTurbineStage(default={"property_package": m.fs.prop_water})
# The boiler feed pump outlet pressure is the same as the condenser
@m.fs.Constraint(m.fs.time)
def constraint_out_pressure(b, t):
return (b.bfpt.control_volume.properties_out[t].pressure ==
b.condenser.shell.properties_out[t].pressure)
# Instead of specifying a fixed efficiency, specify that the steam is just
# starting to condense at the outlet of the boiler feed pump turbine. This
# ensures approximately the right behavior in the turbine. With a fixed
# efficiency, depending on the conditions you can get odd things like steam
# fully condensing in the turbine.
@m.fs.Constraint(m.fs.time)
def constraint_out_enthalpy(b, t):
return (
b.bfpt.control_volume.properties_out[t].enth_mol ==
b.bfpt.control_volume.properties_out[t].enth_mol_sat_phase["Vap"] -
200 * pyo.units.J / pyo.units.mol)
# The boiler feed pump power is the same as the power generated by the
# boiler feed pump turbine. This constraint determines the steam flow to the
# BFP turbine. The turbine work is negative for power out, while pump work
# is positive for power in.
@m.fs.Constraint(m.fs.time)
def constraint_bfp_power(b, t):
return 0 == b.bfp.control_volume.work[t] + b.bfpt.control_volume.work[t]
############################################################################
# Add high pressure feedwater heaters #
############################################################################
m.fs.fwh6 = FWH0D(
default={
"has_desuperheat": True,
"has_drain_cooling": True,
"has_drain_mixer": True,
"property_package": m.fs.prop_water,
"desuperheat": fwh_config,
"cooling": fwh_config,
"condense": fwh_config,
})
m.fs.fwh7 = FWH0D(
default={
"has_desuperheat": True,
"has_drain_cooling": True,
"has_drain_mixer": True,
"property_package": m.fs.prop_water,
"desuperheat": fwh_config,
"cooling": fwh_config,
"condense": fwh_config,
})
m.fs.fwh8 = FWH0D(
default={
"has_desuperheat": True,
"has_drain_cooling": True,
"has_drain_mixer": False,
"property_package": m.fs.prop_water,
"desuperheat": fwh_config,
"cooling": fwh_config,
"condense": fwh_config,
})
############################################################################
# Additional Constraints/Expressions #
############################################################################
# Add a few constraints to allow a for complete plant results despite the
# lack of a detailed boiler model.
# Boiler pressure drop
m.fs.boiler_pressure_drop_fraction = pyo.Var(
m.fs.time,
initialize=0.01,
doc="Fraction of pressure lost from boiler feed pump and turbine inlet",
)
@m.fs.Constraint(m.fs.time)
def boiler_pressure_drop(b, t):
return (m.fs.bfp.control_volume.properties_out[t].pressure *
(1 - b.boiler_pressure_drop_fraction[t]) ==
m.fs.turb.inlet_split.mixed_state[t].pressure)
# Again, since the boiler is missing, set the flow of steam into the turbine
# equal to the flow of feedwater out of the last feedwater heater.
@m.fs.Constraint(m.fs.time)
def close_flow(b, t):
return (m.fs.bfp.control_volume.properties_out[t].flow_mol ==
m.fs.turb.inlet_split.mixed_state[t].flow_mol)
# Calculate the amount of heat that is added in the boiler, including the
# reheater.
@m.fs.Expression(m.fs.time)
def boiler_heat(b, t):
return (b.turb.inlet_split.mixed_state[t].enth_mol *
b.turb.inlet_split.mixed_state[t].flow_mol -
b.fwh8.desuperheat.tube.properties_out[t].enth_mol *
b.fwh8.desuperheat.tube.properties_out[t].flow_mol +
b.turb.ip_stages[1].control_volume.properties_in[t].enth_mol *
b.turb.ip_stages[1].control_volume.properties_in[t].flow_mol -
b.turb.hp_split[7].outlet_1.enth_mol[t] *
b.turb.hp_split[7].outlet_1.flow_mol[t])
# Calculate the efficiency of the steam cycle. This doesn't account for
# heat loss in the boiler, so actual plant efficiency would be lower.
@m.fs.Expression(m.fs.time)
def steam_cycle_eff(b, t):
return -100 * b.turb.power[t] / b.boiler_heat[t]
############################################################################
## Create the stream Arcs ##
############################################################################
############################################################################
# Connect turbine and condenser units #
############################################################################
m.fs.EXHST_MAIN = Arc(source=m.fs.turb.outlet_stage.outlet,
destination=m.fs.condenser_mix.main)
m.fs.condenser_mix_to_condenser = Arc(source=m.fs.condenser_mix.outlet_tpx,
destination=m.fs.condenser.inlet_1)
m.fs.COND_01 = Arc(source=m.fs.condenser.outlet_1_ph,
destination=m.fs.hotwell.condensate)
m.fs.COND_02 = Arc(source=m.fs.hotwell.outlet,
destination=m.fs.cond_pump.inlet)
############################################################################
# Low pressure FWHs #
############################################################################
m.fs.EXTR_LP11 = Arc(source=m.fs.turb.lp_split[11].outlet_2,
destination=m.fs.fwh1.drain_mix.steam)
m.fs.COND_03 = Arc(source=m.fs.cond_pump.outlet,
destination=m.fs.fwh1.condense.inlet_2)
m.fs.FWH1_DRN1 = Arc(source=m.fs.fwh1.condense.outlet_1,
destination=m.fs.fwh1_pump.inlet)
m.fs.FWH1_DRN2 = Arc(source=m.fs.fwh1_pump.outlet,
destination=m.fs.fwh1_return.fwh1_drain)
m.fs.FW01A = Arc(source=m.fs.fwh1.condense.outlet_2,
destination=m.fs.fwh1_return.feedwater)
# fwh2
m.fs.FW01B = Arc(source=m.fs.fwh1_return.outlet,
destination=m.fs.fwh2.cooling.inlet_2)
m.fs.FWH2_DRN = Arc(source=m.fs.fwh2.cooling.outlet_1,
destination=m.fs.fwh1.drain_mix.drain)
m.fs.EXTR_LP10 = Arc(
source=m.fs.turb.lp_split[10].outlet_2,
destination=m.fs.fwh2.desuperheat.inlet_1,
)
# fwh3
m.fs.FW02 = Arc(source=m.fs.fwh2.desuperheat.outlet_2,
destination=m.fs.fwh3.cooling.inlet_2)
m.fs.FWH3_DRN = Arc(source=m.fs.fwh3.cooling.outlet_1,
destination=m.fs.fwh2.drain_mix.drain)
m.fs.EXTR_LP8 = Arc(source=m.fs.turb.lp_split[8].outlet_2,
destination=m.fs.fwh3.desuperheat.inlet_1)
# fwh4
m.fs.FW03 = Arc(source=m.fs.fwh3.desuperheat.outlet_2,
destination=m.fs.fwh4.cooling.inlet_2)
m.fs.FWH4_DRN = Arc(source=m.fs.fwh4.cooling.outlet_1,
destination=m.fs.fwh3.drain_mix.drain)
m.fs.EXTR_LP4 = Arc(source=m.fs.turb.lp_split[4].outlet_2,
destination=m.fs.fwh4.desuperheat.inlet_1)
############################################################################
# FWH5 (Deaerator) and boiler feed pump (BFP) #
############################################################################
m.fs.FW04 = Arc(source=m.fs.fwh4.desuperheat.outlet_2,
destination=m.fs.fwh5_da.feedwater)
m.fs.EXTR_IP10 = Arc(source=m.fs.turb.ip_split[10].outlet_2,
destination=m.fs.fwh5_da.steam)
m.fs.FW05A = Arc(source=m.fs.fwh5_da.outlet, destination=m.fs.bfp.inlet)
m.fs.EXTR_BFPT_A = Arc(source=m.fs.turb.ip_split[10].outlet_3,
destination=m.fs.bfpt.inlet)
m.fs.EXHST_BFPT = Arc(source=m.fs.bfpt.outlet,
destination=m.fs.condenser_mix.bfpt)
############################################################################
# High-pressure feedwater heaters #
############################################################################
# fwh6
m.fs.FW05B = Arc(source=m.fs.bfp.outlet,
destination=m.fs.fwh6.cooling.inlet_2)
m.fs.FWH6_DRN = Arc(source=m.fs.fwh6.cooling.outlet_1,
destination=m.fs.fwh5_da.drain)
m.fs.EXTR_IP5 = Arc(source=m.fs.turb.ip_split[5].outlet_2,
destination=m.fs.fwh6.desuperheat.inlet_1)
# fwh7
m.fs.FW06 = Arc(source=m.fs.fwh6.desuperheat.outlet_2,
destination=m.fs.fwh7.cooling.inlet_2)
m.fs.FWH7_DRN = Arc(source=m.fs.fwh7.cooling.outlet_1,
destination=m.fs.fwh6.drain_mix.drain)
m.fs.EXTR_HP7 = Arc(source=m.fs.turb.hp_split[7].outlet_2,
destination=m.fs.fwh7.desuperheat.inlet_1)
# fwh8
m.fs.FW07 = Arc(source=m.fs.fwh7.desuperheat.outlet_2,
destination=m.fs.fwh8.cooling.inlet_2)
m.fs.FWH8_DRN = Arc(source=m.fs.fwh8.cooling.outlet_1,
destination=m.fs.fwh7.drain_mix.drain)
m.fs.EXTR_HP4 = Arc(source=m.fs.turb.hp_split[4].outlet_2,
destination=m.fs.fwh8.desuperheat.inlet_1)
############################################################################
# Turn the Arcs into constraints and return the model #
############################################################################
pyo.TransformationFactory("network.expand_arcs").apply_to(m.fs)
return m
class FWH0DData(UnitModelBlockData):
CONFIG = UnitModelBlockData.CONFIG()
_define_feedwater_heater_0D_config(CONFIG)
def build(self):
super().build()
config = self.config # sorter ref to config for less line splitting
# All feedwater heaters have a condensing section
_set_prop_pack(config.condense, config)
self.condense = FWHCondensing0D(default=config.condense)
# Add a mixer to add the drain stream from another feedwater heater
if config.has_drain_mixer:
mix_cfg = { # general unit model config
"dynamic": config.dynamic,
"has_holdup": config.has_holdup,
"property_package": config.property_package,
"property_package_args": config.property_package_args,
"momentum_mixing_type": MomentumMixingType.none,
"material_balance_type": MaterialBalanceType.componentTotal,
"inlet_list": ["steam", "drain"],
}
self.drain_mix = Mixer(default=mix_cfg)
@self.drain_mix.Constraint(self.drain_mix.flowsheet().config.time)
def mixer_pressure_constraint(b, t):
"""
Constraint to set the drain mixer pressure to the pressure of
the steam extracted from the turbine. The drain inlet should
always be a higher pressure than the steam inlet.
"""
return b.steam_state[t].pressure == b.mixed_state[t].pressure
# Connect the mixer to the condensing section inlet
self.mix_out_arc = Arc(source=self.drain_mix.outlet,
destination=self.condense.inlet_1)
# Add a desuperheat section before the condensing section
if config.has_desuperheat:
_set_prop_pack(config.desuperheat, config)
self.desuperheat = HeatExchanger(default=config.desuperheat)
# set default area less than condensing section area, this will
# almost always be overridden by the user fixing an area later
self.desuperheat.area.value = 10
if config.has_drain_mixer:
self.desuperheat_drain_arc = Arc(
source=self.desuperheat.outlet_1,
destination=self.drain_mix.steam)
else:
self.desuperheat_drain_arc = Arc(
source=self.desuperheat.outlet_1,
destination=self.condense.inlet_1)
self.condense_out2_arc = Arc(source=self.condense.outlet_2,
destination=self.desuperheat.inlet_2)
# Add a drain cooling section after the condensing section
if config.has_drain_cooling:
_set_prop_pack(config.cooling, config)
self.cooling = HeatExchanger(default=config.cooling)
# set default area less than condensing section area, this will
# almost always be overridden by the user fixing an area later
self.cooling.area.value = 10
self.cooling_out2_arc = Arc(source=self.cooling.outlet_2,
destination=self.condense.inlet_2)
self.condense_out1_arc = Arc(source=self.condense.outlet_1,
destination=self.cooling.inlet_1)
TransformationFactory("network.expand_arcs").apply_to(self)
def initialize(self, *args, **kwargs):
outlvl = kwargs.get("outlvl", idaeslog.NOTSET)
init_log = idaeslog.getInitLogger(self.name, outlvl, tag="unit")
solve_log = idaeslog.getSolveLogger(self.name, outlvl, tag="unit")
config = self.config # shorter ref to config for less line splitting
sp = StoreSpec.value_isfixed_isactive(only_fixed=True)
istate = to_json(self, return_dict=True, wts=sp)
# the initialization here isn't straight forward since the heat exchanger
# may have 3 stages and they are countercurrent. For simplicity each
# stage in initialized with the same cooling water inlet conditions then
# the whole feedwater heater is solved together. There are more robust
# approaches which can be implimented if the need arises.
# initialize desuperheat if include
if config.has_desuperheat:
if config.has_drain_cooling:
_set_port(self.desuperheat.inlet_2, self.cooling.inlet_2)
else:
_set_port(self.desuperheat.inlet_2, self.condense.inlet_2)
self.desuperheat.initialize(*args, **kwargs)
self.desuperheat.inlet_1.flow_mol.unfix()
if config.has_drain_mixer:
_set_port(self.drain_mix.steam, self.desuperheat.outlet_1)
else:
_set_port(self.condense.inlet_1, self.desuperheat.outlet_1)
# fix the steam and fwh inlet for init
self.desuperheat.inlet_1.fix()
self.desuperheat.inlet_1.flow_mol.unfix() # unfix for extract calc
# initialize mixer if included
if config.has_drain_mixer:
self.drain_mix.steam.fix()
self.drain_mix.drain.fix()
self.drain_mix.outlet.unfix()
self.drain_mix.initialize(*args, **kwargs)
_set_port(self.condense.inlet_1, self.drain_mix.outlet)
if config.has_desuperheat:
self.drain_mix.steam.unfix()
else:
self.drain_mix.steam.flow_mol.unfix()
# Initialize condense section
if config.has_drain_cooling:
_set_port(self.condense.inlet_2, self.cooling.inlet_2)
self.cooling.inlet_2.fix()
else:
self.condense.inlet_2.fix()
if not config.has_drain_mixer and not config.has_desuperheat:
self.condense.inlet_1.fix()
self.condense.inlet_1.flow_mol.unfix()
tempsat = value(self.condense.shell.properties_in[0].temperature_sat)
temp = value(self.condense.tube.properties_in[0].temperature)
if tempsat - temp < 30:
init_log.warning(
"The steam sat. temperature ({}) is near the feedwater"
" inlet temperature ({})".format(tempsat, temp))
self.condense.initialize(*args, **kwargs)
# Initialize drain cooling if included
if config.has_drain_cooling:
_set_port(self.cooling.inlet_1, self.condense.outlet_1)
self.cooling.initialize(*args, **kwargs)
# Solve all together
opt = SolverFactory(kwargs.get("solver", "ipopt"))
opt.options = kwargs.get("oparg", {})
assert degrees_of_freedom(self) == 0
with idaeslog.solver_log(solve_log, idaeslog.DEBUG) as slc:
res = opt.solve(self, tee=slc.tee)
init_log.info("Condensing shell inlet delta T = {}".format(
value(self.condense.delta_temperature_in[0])))
init_log.info("Condensing Shell outlet delta T = {}".format(
value(self.condense.delta_temperature_out[0])))
init_log.info("Steam Flow = {}".format(
value(self.condense.inlet_1.flow_mol[0])))
init_log.info("Initialization Complete: {}".format(
idaeslog.condition(res)))
from_json(self, sd=istate, wts=sp)
