Source code for armi.reactor.reactorParameters

# Copyright 2019 TerraPower, LLC
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# Licensed under the Apache License, Version 2.0 (the "License");
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#     http://www.apache.org/licenses/LICENSE-2.0
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"""
Reactor parameter definitions
"""
import numpy

from armi.utils import units
from armi.reactor import parameters
from armi.reactor.parameters import ParamLocation
from armi.reactor import geometry


[docs]def defineReactorParameters(): pDefs = parameters.ParameterDefinitionCollection() pDefs.add( parameters.Parameter( "rdIterNum", units="int", description="Number of region-density equilibrium iterations", location=ParamLocation.AVERAGE, saveToDB=True, default=parameters.NoDefault, setter=parameters.NoDefault, categories=set(), ) ) with pDefs.createBuilder(location=ParamLocation.AVERAGE, default=0.0) as pb: pb.defParam( "cycle", units="int", description="current cycle of the simulation", default=0, ) pb.defParam( "cycleLength", units="EFP days", description="The cycle length of the reactor while power is being produced", ) pb.defParam( "availabilityFactor", units="fraction", description="Availability factor of the plant. This is the fraction of the time that " "the plant is operating.", default=1.0, ) pb.defParam( "capacityFactor", units="fraction", description="The fraction of power produced by the plant this cycle over the " "full-power, 100% uptime potential of the plant.", default=1.0, ) pb.defParam("lcoe", units="$/kWh", description="Levelised cost of electricity") pb.defParam( "time", units="yr", description="time of reactor life from BOL to current time node", categories=["depletion"], ) pb.defParam("timeNode", units="", description="timeNode", default=0) with pDefs.createBuilder( location=ParamLocation.AVERAGE, default=0.0, categories=["economics"] ) as pb: pb.defParam( "eFeedMT", units="MT", description="Total feed material required in reactor economics", ) pb.defParam( "eFissile", units="MT", description="Fissile mass required in reactor economics", ) pb.defParam( "eFuelCycleCost", units="$/MT", description="Cost of fuel cycle in an equilibrium-mode in reactor economics", ) pb.defParam( "eFuelCycleCostRate", units="$/year", description="Rate of fuel cycle cost in an equilibrium mode in reactor economics", ) pb.defParam( "eProduct", units="MT", description="Total mass of manufactured fuel in reactor economics", ) pb.defParam( "eSWU", units="kgSWU", description="Separative work units in reactor economics", ) pb.defParam( "eTailsMT", units="MT", description="Depleted Uranium in reactor economics" ) return pDefs
[docs]def defineCoreParameters(): pDefs = parameters.ParameterDefinitionCollection() with pDefs.createBuilder() as pb: def detailedNucKeys(self, value): if value is None or isinstance(value, numpy.ndarray): self._p_detailedNucKeys = value else: self._p_detailedNucKeys = numpy.array(value) pb.defParam( "detailedNucKeys", setter=detailedNucKeys, units="ZZZAAA (ZZZ atomic number, AAA mass number, + 100 * m for metastable states", description="Nuclide vector keys, used to map densities in b.p.detailedNDens and a.p.detailedNDens", saveToDB=True, default=None, ) with pDefs.createBuilder(location=ParamLocation.CENTROID) as pb: pb.defParam( "orientation", units="degrees", description=( "Triple representing rotations counterclockwise around each spatial axis. For example, " "a hex assembly rotated by 1/6th has orientation (0,0,60.0)" ), default=None, ) with pDefs.createBuilder(location=ParamLocation.AVERAGE, default=0.0) as pb: pb.defParam("currentPercentExpanded", units="", description="") pb.defParam( "maxAssemNum", units=None, description="maximum assembly number", default=0 ) pb.defParam("numMoves", units="", description="numMoves", default=0) with pDefs.createBuilder(default=0.0, location="N/A") as pb: pb.defParam( "breedingRatio2", units="N/A", description="Ratio of fissile Burned and discharged to fissile discharged", saveToDB=False, ) pb.defParam( "crWorthRequiredPrimary", units="$", description="The total worth in $ required for primary control rods to shutdown reactor accounting for uncertainties and margins", ) pb.defParam( "crWorthRequiredSecondary", units="$", description="The total worth in $ required for secondary control rods to shutdown reactor accounting for uncertainties and margins", ) pb.defParam( "critSearchSlope", units=None, description="Critical keff search slope" ) pb.defParam( "directPertKeff", units=None, description="K-eff is computed for the perturbed case with a direct calculation", ) pb.defParam( "distortionReactivity", units="pcm", description="The reactivity effect of the current distortions", default=None, ) pb.defParam( "doublingTime", units="EFPY", description="The time it takes to produce enough spent fuel to fuel a daughter reactor", ) pb.defParam("fissileMass", units="g", description="Fissile mass of the reactor") pb.defParam( "heavyMetalMass", units="g", description="Heavy Metal mass of the reactor" ) pb.defParam( "innerMatrixIndex", units=None, description="The item index of the inner matrix in an optimization case", ) pb.defParam("keffUnc", units=None, description="Uncontrolled keff") pb.defParam( "lastKeff", units=None, description="Previously calculated Keff for potential keff convergence", ) pb.defParam( "loadPadDpaAvg", units="dpa", description="The highest average dpa in any load pad", ) pb.defParam( "loadPadDpaPeak", units="dpa", description="The peak dpa in any load pad" ) pb.defParam("maxcladFCCI", units="", description="", default=0.0) pb.defParam( "maxCladulof", units=units.DEGC, description="Max Clading Temperature in Unprotected Loss of Flow (ULOF) transient", ) pb.defParam( "maxCladulohs", units=units.DEGC, description="Max Clading Temperature in Unprotected Loss of Heat Sink (ULOHS) transient", ) pb.defParam( "maxCladutop", units=units.DEGC, description="Max Clading Temperature in Unprotected Transient Overpower (UTOP) transient", ) pb.defParam( "maxCladptop", units=units.DEGC, description="Max Clading Temperature in protected Transient Overpower (PTOP) transient", ) pb.defParam( "maxCladlockrotor", units=units.DEGC, description="Max Clading Temperature in lock rotor transient", ) pb.defParam( "maxCladplohs", units=units.DEGC, description="Max Clading Temperature in protected loss of heat sink (PLOHS) transient", ) pb.defParam( "maxCladplof", units=units.DEGC, description="Max Clading Temperature in protected loss of flow (PLOF) transient", ) pb.defParam( "maxCladplof2pump", units=units.DEGC, description="Max Clading Temperature in protected loss of 2 primary pumps (PLOF2pump) transient", ) pb.defParam( "maxCladoscillation", units=units.DEGC, description="Max Clading Temperature in oscillation-driven transient", ) pb.defParam( "maxFueloscillation", units=units.DEGC, description="Max Fuel Temperature in oscillation-driven transient", ) pb.defParam( "maxCladpowerdefect", units=units.DEGC, description="Max Clading Temperature in powerdefect transient", ) pb.defParam( "maxFuelpowerdefect", units=units.DEGC, description="Max Fuel Temperature in powerdefect transient", ) pb.defParam( "maxCladsteadystate", units=units.DEGC, description="Max Clading Temperature in steady state transient", ) pb.defParam( "maxDPA", units="dpa", description="Maximum DPA based on pin-level max if it exists, block level max otherwise", ) pb.defParam("maxFuelulof", units=units.DEGC, description="maxFuelulof") pb.defParam("maxFuelulohs", units=units.DEGC, description="maxFuelulohs") pb.defParam("maxFuelutop", units=units.DEGC, description="maxFuelutop") pb.defParam( "maxFuelptop", units=units.DEGC, description="Max Clading Temperature in protected Transient Overpower (PTOP) transient", ) pb.defParam( "maxFuellockrotor", units=units.DEGC, description="Max Clading Temperature in lock rotor transient", ) pb.defParam( "maxFuelplohs", units=units.DEGC, description="Max Clading Temperature in protected loss of heat sink (PLOHS) transient", ) pb.defParam( "maxFuelplof", units=units.DEGC, description="Max Clading Temperature in protected loss of flow (PLOF) transient", ) pb.defParam( "maxFuelplof2pump", units=units.DEGC, description="Max Clading Temperature in protected loss of 2 primary pumps (PLOF2pump) transient", ) pb.defParam("maxGridDpa", units="dpa", description="Grid plate max dpa") pb.defParam( "maxProcessMemoryInMB", units="MB", description="Maximum memory used by an ARMI process", ) pb.defParam( "maxTH2SigmaCladIDT", units=units.DEGC, description="Max 2-sigma temperature of the inner-diameter of the cladding", default=0.0, categories=["block-max"], ) pb.defParam( "maxTranPCT", units=units.DEGC, description="Max Peak Clading Temperature of transients", ) pb.defParam( "minProcessMemoryInMB", units="MB", description="Minimum memory used by an ARMI process", ) pb.defParam( "minutesSinceStart", units="min", description="Run time since the beginning of the calculation", ) pb.defParam( "outsideFuelRing", units="int", description="The ring with the fraction of flux that best meets the target", ) pb.defParam( "outsideFuelRingFluxFr", units=None, description="Ratio of the flux in a ring to the total reactor fuel flux", ) pb.defParam( "peakGridDpaAt60Years", units="dpa", description="Grid plate peak dpa after 60 years irradiation", ) pb.defParam( "topInitiator", units="$", description="Worth in $ of most valuable rod in critical position", ) pb.defParam( "totalIntrinsicSource", units="neutrons/s", description="Full core intrinsic neutron source from spontaneous fissions before a decay period", ) pb.defParam( "totalIntrinsicSourceDecayed", units="neutrons/s", description="Full core intrinsic source from spontaneous fissions after a decay period", ) with pDefs.createBuilder( location=ParamLocation.AVERAGE, default=0.0, categories=["thermal hydraulics"] ) as pb: pb.defParam( "assemblyPumpHead", units="Pa", description="Pressure drop for the max power assembly in zone", ) pb.defParam( "CoreAvgTOut", units=units.DEGC, description="Core average outlet temperature", ) pb.defParam("CoreMdot", units="kg/s", description="Mass flow rate of full core") pb.defParam( "outletTempIdeal", units=units.DEGC, description="Average outlet tempeture loop through all assemblies after doing TH", ) pb.defParam( "SCMaxDilationPressure", units="Pa", description="The maximum dilation pressure in the core", ) pb.defParam( "SCorificeEfficiency", units=None, description="Ratio of total flow rate for the optimized orificing scheme to total flow rate for an ideal orificing scheme", ) pb.defParam( "SCovercoolingRatio", units=None, description="Ratio of the max flow rate to the average flow rate", ) pb.defParam( "THmaxDeltaPPump", units="Pa", description="The maximum pumping pressure rise required to pump the given mass flow rate through the rod bundle", ) pb.defParam( "THmaxDilationPressure", units="", description="THmaxDilationPressure" ) pb.defParam( "THoutletTempIdeal", units=units.DEGC, description="Average outlet temperature loop through all assemblies after doing TH", ) pb.defParam("vesselTemp", units=units.DEGC, description="vessel temperature") pb.defParam( "LMDT", units=units.DEGC, description="Log mean temperature difference in heat exchanger", ) pb.defParam( "peakTemperature", units=units.DEGC, description="peak temperature anywhere in the reactor", ) with pDefs.createBuilder( location=ParamLocation.AVERAGE, default=0.0, categories=["neutronics"] ) as pb: pb.defParam( "maxdetailedDpaPeak", units="dpa", description="Highest peak dpa of any block in the problem", ) pb.defParam( "maxFlux", units="n/cm^2/s", description="Max neutron flux in the core" ) pb.defParam( "adjWeightedFisSrc", units="1/cm^2/s^2", description="Volume-integrated adjoint flux weighted fission source", ) pb.defParam( "maxDetailedDpaThisCycle", units="dpa", description="Max increase in dpa this cycle (only defined at EOC)", ) pb.defParam( "dpaFullWidthHalfMax", units="cm", description="Full width at half max of the detailedDpa distribution", ) pb.defParam( "elevationOfACLP3Cycles", units="cm", description="minimum axial location of the ACLP for 3 cycles at peak dose", ) pb.defParam( "elevationOfACLP7Cycles", units="cm", description="minimum axial location of the ACLP for 7 cycles at peak dose", ) pb.defParam( "maxpercentBu", units="%FIMA", description="Max percent burnup on any block in the problem", ) pb.defParam("rxSwing", units="pcm", description="Reactivity swing") pb.defParam( "maxBuF", units="%", description="Maximum burnup seen in any feed assemblies", ) pb.defParam( "maxBuI", units="%", description="Maximum burnup seen in any igniter assemblies", ) pb.defParam("keff", units=None, description="Global multiplication factor") pb.defParam( "peakKeff", units=None, description="Maximum keff in the simulation" ) pb.defParam( "fastFluxFrAvg", units=None, description="Fast flux fraction average" ) pb.defParam( "leakageFracTotal", units=None, description="Total leakage fraction" ) pb.defParam( "leakageFracPlanar", units=None, description="Leakage fraction in planar" ) pb.defParam( "leakageFracAxial", units=None, description="Leakage fraction in axial direction", ) pb.defParam( "maxpdens", units="W/cm^3", description="Maximum avg. volumetric power density of all blocks", ) pb.defParam( "maxPD", units="MW/m^2", description="Maximum areal power density of all assemblies", ) pb.defParam( "jumpRing", units=None, description=( "Radial ring number where bred-up fuel assemblies shuffle jump from the low power to the " "high power region." ), ) with pDefs.createBuilder( default=0.0, location=ParamLocation.AVERAGE, categories=["reactivity coefficients"], ) as pb: pb.defParam("axial", units="cents/K", description="Axial expansion coefficient") pb.defParam("doppler", units="cents/K", description="Doppler coefficient") pb.defParam( "dopplerConst", units="cents * K^(n-1)", description="Doppler constant" ) pb.defParam( "fuelDensity", units="cents/K", description="Fuel temperature coefficient" ) pb.defParam( "coolantDensity", units="cents/K", description="Coolant temperature coefficient", ) pb.defParam( "totalCoolantDensity", units="cents/K", description="Coolant temperature coefficient weighted to include bond and interstitial effects", ) pb.defParam( "cladDensity", units="cents/K", description="Clad temperature coefficient" ) pb.defParam( "structureDensity", units="cents/K", description="Structure temperature coefficient", ) pb.defParam( "Voideddoppler", units="cents/K", description="Voided Doppler coefficient" ) pb.defParam( "VoideddopplerConst", units="cents * K^(n-1)", description="Voided Doppler constant", ) pb.defParam("voidWorth", units="$", description="Coolant void worth") pb.defParam("voidedKeff", units=None, description="Voided keff") pb.defParam( "radialHT9", units="cents/K", description="Radial expansion coefficient when driven by thermal expansion of HT9.", ) pb.defParam( "radialSS316", units="cents/K", description="Radial expansion coefficient when driven by thermal expansion of SS316.", ) with pDefs.createBuilder( default=0.0, location=ParamLocation.AVERAGE, categories=["reactivity coefficients", "kinetics"], ) as pb: pb.defParam( "beta", units=None, description="Effective delayed neutron fraction", default=None, ) pb.defParam( "betaComponents", units=None, description="Group-wise delayed neutron fractions.", default=None, ) pb.defParam( "betaDecayConstants", units="1/s", description="Group-wise precursor decay constants", default=None, ) pb.defParam( "promptNeutronGenerationTime", units="s", description="Prompt neutron generation time", ) pb.defParam( "promptNeutronLifetime", units="s", description="Prompt neutron lifetime" ) with pDefs.createBuilder( default=0.0, location=ParamLocation.AVERAGE, categories=["reactivity coefficients", "core wide"], ) as pb: # CORE WIDE REACTIVITY COEFFICIENTS pb.defParam( "rxFuelAxialExpansionCoeffPerTemp", units="dk/kk'-K", description="Fuel Axial Expansion Coefficient", ) pb.defParam( "rxGridPlateRadialExpansionCoeffPerTemp", units="dk/kk'-K", description="Grid Plate Radial Expansion Coefficient", ) pb.defParam( "rxAclpRadialExpansionCoeffPerTemp", units="dk/kk'-K", description="ACLP Radial Expansion Coefficient", ) pb.defParam( "rxControlRodDrivelineExpansionCoeffPerTemp", units="dk/kk'-K", description="control rod driveline expansion coefficient", ) pb.defParam( "rxCoreWideCoolantVoidWorth", units="dk/kk'", description="Core-Wide Coolant Void Worth", ) pb.defParam( "rxSpatiallyDependentCoolantVoidWorth", units="dk/kk'", description="Spatially-Dependent Coolant Void Worth", ) # FUEL COEFFICIENTS pb.defParam( "rxFuelDensityCoeffPerTemp", units="dk/kk'-K", description="Fuel Density Coefficient", ) pb.defParam( "rxFuelDopplerCoeffPerTemp", units="dk/kk'-K", description="Fuel Doppler Coefficient", ) pb.defParam( "rxFuelDopplerConstant", units="dk/kk' K**(n-1)", description="Fuel Doppler Constant", ) pb.defParam( "rxFuelVoidedDopplerCoeffPerTemp", units="dk/kk'-K", description="Fuel Voided-Coolant Doppler Coefficient", ) pb.defParam( "rxFuelVoidedDopplerConstant", units="dk/kk' K**(n-1)", description="Fuel Voided-Coolant Doppler Constant", ) pb.defParam( "rxFuelTemperatureCoeffPerTemp", units="dk/kk'-K", description="Fuel Temperature Coefficient", ) pb.defParam( "rxFuelVoidedTemperatureCoeffPerTemp", units="dk/kk'-K", description="Fuel Voided-Coolant Temperature Coefficient", ) # CLAD COEFFICIENTS pb.defParam( "rxCladDensityCoeffPerTemp", units="dk/kk'-K", description="Clad Density Coefficient", ) pb.defParam( "rxCladDopplerCoeffPerTemp", units="dk/kk'-K", description="Clad Doppler Coefficient", ) pb.defParam( "rxCladDopplerConstant", units="dk/kk' K**(n-1)", description="Clad Doppler Constant", ) pb.defParam( "rxCladTemperatureCoeffPerTemp", units="dk/kk'-K", description="Clad Temperature Coefficient", ) # STRUCTURE COEFFICIENTS pb.defParam( "rxStructureDensityCoeffPerTemp", units="dk/kk'-K", description="Structure Density Coefficient", ) pb.defParam( "rxStructureDopplerCoeffPerTemp", units="dk/kk'-K", description="Structure Doppler Coefficient", ) pb.defParam( "rxStructureDopplerConstant", units="dk/kk' K**(n-1)", description="Structure Doppler Constant", ) pb.defParam( "rxStructureTemperatureCoeffPerTemp", units="dk/kk'-K", description="Structure Temperature Coefficient", ) # COOLANT COEFFICIENTS pb.defParam( "rxCoolantDensityCoeffPerTemp", units="dk/kk'-K", description="Coolant Density Coefficient", ) pb.defParam( "rxCoolantTemperatureCoeffPerTemp", units="dk/kk'-K", description="Coolant Temperature Coefficient", ) with pDefs.createBuilder( location=ParamLocation.AVERAGE, categories=["equilibrium"] ) as pb: pb.defParam("boecKeff", units=None, description="BOEC Keff", default=0.0) pb.defParam( "cyclics", units="int", description=( "The number of cyclic mode equilibrium-cycle " "iterations that have occurred so far" ), default=0, ) pb.defParam( "maxCyclicNErr", units=None, description="Maximum relative number density error", default=0.0, ) with pDefs.createBuilder( location=ParamLocation.AVERAGE, categories=["equilibrium"] ) as pb: pb.defParam( "breedingRatio", units="N/A", description="Breeding ratio of the reactor", default=0.0, ) pb.defParam("ConvRatioCore", units="?", description="?") pb.defParam("absPerFisCore", units="?", description="?") pb.defParam( "axialExpansionPercent", units="%", description="Percent of axial growth of fuel blocks", default=0.0, ) pb.defParam("corePow", units="?", description="?") pb.defParam("coupledIteration", units="?", description="?", default=0) pb.defParam("fisFrac", units="?", description="?") pb.defParam("fisRateCore", units="?", description="?") pb.defParam( "maxcladWastage", units="microns", description="Maximum clad wastage in any block in the core", default=0.0, categories=["block-max"], ) pb.defParam( "maxdilationTotal", units="?", description="?", default=0.0, categories=["block-max"], ) pb.defParam( "maxresidence", units="?", description="?", default=0.0, categories=["block-max"], ) pb.defParam("medAbsCore", units="?", description="?") pb.defParam("medFluxCore", units="?", description="?") pb.defParam("medSrcCore", units="?", description="?") pb.defParam("pkFlux", units="?", description="?") pb.defParam( "power", units="W", description="Rated thermal power of the reactor core. Corresponds to the " "nuclear power generated in the core.", ) pb.defParam( "powerDecay", units="W", description="Decay power from decaying radionuclides", ) return pDefs