// -*- mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- // vi: set et ts=4 sw=4 sts=4: /* This file is part of the Open Porous Media project (OPM). OPM is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 2 of the License, or (at your option) any later version. OPM is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with OPM. If not, see . Consult the COPYING file in the top-level source directory of this module for the precise wording of the license and the list of copyright holders. */ /*! * \file * * \copydoc Ewoms::WaterAirProblem */ #ifndef EWOMS_WATER_AIR_PROBLEM_HH #define EWOMS_WATER_AIR_PROBLEM_HH #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include namespace Ewoms { template class WaterAirProblem; } BEGIN_PROPERTIES NEW_TYPE_TAG(WaterAirBaseProblem); // Set the grid type SET_TYPE_PROP(WaterAirBaseProblem, Grid, Dune::YaspGrid<2>); // Set the problem property SET_TYPE_PROP(WaterAirBaseProblem, Problem, Ewoms::WaterAirProblem); // Set the material Law SET_PROP(WaterAirBaseProblem, MaterialLaw) { private: typedef typename GET_PROP_TYPE(TypeTag, Scalar) Scalar; typedef typename GET_PROP_TYPE(TypeTag, FluidSystem) FluidSystem; typedef Opm::TwoPhaseMaterialTraits Traits; // define the material law which is parameterized by effective // saturations typedef Opm::RegularizedBrooksCorey EffMaterialLaw; public: // define the material law parameterized by absolute saturations // which uses the two-phase API typedef Opm::EffToAbsLaw type; }; // Set the thermal conduction law SET_PROP(WaterAirBaseProblem, ThermalConductionLaw) { private: typedef typename GET_PROP_TYPE(TypeTag, Scalar) Scalar; typedef typename GET_PROP_TYPE(TypeTag, FluidSystem) FluidSystem; public: // define the material law parameterized by absolute saturations typedef Opm::SomertonThermalConductionLaw type; }; // set the energy storage law for the solid phase SET_TYPE_PROP(WaterAirBaseProblem, SolidEnergyLaw, Opm::ConstantSolidHeatCapLaw); // Set the fluid system. in this case, we use the one which describes // air and water SET_TYPE_PROP(WaterAirBaseProblem, FluidSystem, Opm::H2OAirFluidSystem); // Enable gravity SET_BOOL_PROP(WaterAirBaseProblem, EnableGravity, true); // Use forward differences instead of central differences SET_INT_PROP(WaterAirBaseProblem, NumericDifferenceMethod, +1); // Write newton convergence SET_BOOL_PROP(WaterAirBaseProblem, NewtonWriteConvergence, false); // The default for the end time of the simulation (1 year) SET_SCALAR_PROP(WaterAirBaseProblem, EndTime, 1.0 * 365 * 24 * 60 * 60); // The default for the initial time step size of the simulation SET_SCALAR_PROP(WaterAirBaseProblem, InitialTimeStepSize, 250); // The default DGF file to load SET_STRING_PROP(WaterAirBaseProblem, GridFile, "./data/waterair.dgf"); // Use the restarted GMRES linear solver with the ILU-2 preconditioner from dune-istl SET_TAG_PROP(WaterAirBaseProblem, LinearSolverSplice, ParallelIstlLinearSolver); SET_TYPE_PROP(WaterAirBaseProblem, LinearSolverWrapper, Ewoms::Linear::SolverWrapperRestartedGMRes); #if DUNE_VERSION_NEWER(DUNE_ISTL, 2,7) SET_TYPE_PROP(WaterAirBaseProblem, PreconditionerWrapper, Ewoms::Linear::PreconditionerWrapperILU); #else SET_TYPE_PROP(WaterAirBaseProblem, PreconditionerWrapper, Ewoms::Linear::PreconditionerWrapperILUn); #endif SET_INT_PROP(WaterAirBaseProblem, PreconditionerOrder, 2); END_PROPERTIES namespace Ewoms { /*! * \ingroup TestProblems * \brief Non-isothermal gas injection problem where a air * is injected into a fully water saturated medium. * * During buoyancy driven upward migration, the gas passes a * rectangular high temperature area. This decreases the temperature * of the high-temperature area and accelerates gas infiltration due * to the lower viscosity of the gas. (Be aware that the pressure of * the gas is approximately constant within the lens, so the density * of the gas is reduced. This more than off-sets the viscosity * increase of the gas at constant density.) * * The domain is sized 40 m times 40 m. The rectangular area with * increased temperature (380 K) starts at (20 m, 5 m) and ends at (30 * m, 35 m). * * For the mass conservation equation, no-flow boundary conditions are * used on the top and on the bottom of the domain, while free-flow * conditions apply on the left and the right boundary. Gas is * injected at bottom from 15 m to 25 m at a rate of 0.001 kg/(s m^2) * by means if a forced inflow boundary condition. * * At the free-flow boundaries, the initial condition for the bulk * part of the domain is assumed, i. e. hydrostatic pressure, a gas * saturation of zero and a geothermal temperature gradient of 0.03 * K/m. */ template class WaterAirProblem : public GET_PROP_TYPE(TypeTag, BaseProblem) { typedef typename GET_PROP_TYPE(TypeTag, BaseProblem) ParentType; typedef typename GET_PROP_TYPE(TypeTag, Scalar) Scalar; typedef typename GET_PROP_TYPE(TypeTag, GridView) GridView; // copy some indices for convenience typedef typename GET_PROP_TYPE(TypeTag, FluidSystem) FluidSystem; typedef typename GET_PROP_TYPE(TypeTag, Indices) Indices; enum { numPhases = FluidSystem::numPhases, // energy related indices temperatureIdx = Indices::temperatureIdx, energyEqIdx = Indices::energyEqIdx, // component indices H2OIdx = FluidSystem::H2OIdx, AirIdx = FluidSystem::AirIdx, // phase indices liquidPhaseIdx = FluidSystem::liquidPhaseIdx, gasPhaseIdx = FluidSystem::gasPhaseIdx, // equation indices conti0EqIdx = Indices::conti0EqIdx, // Grid and world dimension dim = GridView::dimension, dimWorld = GridView::dimensionworld }; static const bool enableEnergy = GET_PROP_VALUE(TypeTag, EnableEnergy); typedef typename GET_PROP_TYPE(TypeTag, EqVector) EqVector; typedef typename GET_PROP_TYPE(TypeTag, RateVector) RateVector; typedef typename GET_PROP_TYPE(TypeTag, BoundaryRateVector) BoundaryRateVector; typedef typename GET_PROP_TYPE(TypeTag, PrimaryVariables) PrimaryVariables; typedef typename GET_PROP_TYPE(TypeTag, Constraints) Constraints; typedef typename GET_PROP_TYPE(TypeTag, Simulator) Simulator; typedef typename GET_PROP_TYPE(TypeTag, Model) Model; typedef typename GET_PROP_TYPE(TypeTag, MaterialLaw) MaterialLaw; typedef typename GET_PROP_TYPE(TypeTag, MaterialLawParams) MaterialLawParams; typedef typename GET_PROP_TYPE(TypeTag, ThermalConductionLawParams) ThermalConductionLawParams; typedef typename GET_PROP_TYPE(TypeTag, SolidEnergyLawParams) SolidEnergyLawParams; typedef typename GridView::ctype CoordScalar; typedef Dune::FieldVector GlobalPosition; typedef Dune::FieldMatrix DimMatrix; public: /*! * \copydoc Doxygen::defaultProblemConstructor */ WaterAirProblem(Simulator& simulator) : ParentType(simulator) { } /*! * \copydoc FvBaseProblem::finishInit */ void finishInit() { ParentType::finishInit(); maxDepth_ = 1000.0; // [m] eps_ = 1e-6; FluidSystem::init(/*Tmin=*/275, /*Tmax=*/600, /*nT=*/100, /*pmin=*/9.5e6, /*pmax=*/10.5e6, /*np=*/200); layerBottom_ = 22.0; // intrinsic permeabilities fineK_ = this->toDimMatrix_(1e-13); coarseK_ = this->toDimMatrix_(1e-12); // porosities finePorosity_ = 0.3; coarsePorosity_ = 0.3; // residual saturations fineMaterialParams_.setResidualSaturation(liquidPhaseIdx, 0.2); fineMaterialParams_.setResidualSaturation(gasPhaseIdx, 0.0); coarseMaterialParams_.setResidualSaturation(liquidPhaseIdx, 0.2); coarseMaterialParams_.setResidualSaturation(gasPhaseIdx, 0.0); // parameters for the Brooks-Corey law fineMaterialParams_.setEntryPressure(1e4); coarseMaterialParams_.setEntryPressure(1e4); fineMaterialParams_.setLambda(2.0); coarseMaterialParams_.setLambda(2.0); fineMaterialParams_.finalize(); coarseMaterialParams_.finalize(); // parameters for the somerton law of thermal conduction computeThermalCondParams_(fineThermalCondParams_, finePorosity_); computeThermalCondParams_(coarseThermalCondParams_, coarsePorosity_); // assume constant volumetric heat capacity and granite solidEnergyLawParams_.setSolidHeatCapacity(790.0 // specific heat capacity of granite [J / (kg K)] * 2700.0); // density of granite [kg/m^3] solidEnergyLawParams_.finalize(); } /*! * \name Problem parameters */ //! \{ /*! * \copydoc FvBaseProblem::name */ std::string name() const { std::ostringstream oss; oss << "waterair_" << Model::name(); if (GET_PROP_VALUE(TypeTag, EnableEnergy)) oss << "_ni"; return oss.str(); } /*! * \copydoc FvBaseProblem::endTimeStep */ void endTimeStep() { #ifndef NDEBUG // checkConservativeness() does not include the effect of constraints, so we // disable it for this problem... //this->model().checkConservativeness(); // Calculate storage terms EqVector storage; this->model().globalStorage(storage); // Write mass balance information for rank 0 if (this->gridView().comm().rank() == 0) { std::cout << "Storage: " << storage << std::endl << std::flush; } #endif // NDEBUG } /*! * \copydoc FvBaseMultiPhaseProblem::intrinsicPermeability * * In this problem, the upper part of the domain is sightly less * permeable than the lower one. */ template const DimMatrix& intrinsicPermeability(const Context& context, unsigned spaceIdx, unsigned timeIdx) const { const GlobalPosition& pos = context.pos(spaceIdx, timeIdx); if (isFineMaterial_(pos)) return fineK_; return coarseK_; } /*! * \copydoc FvBaseMultiPhaseProblem::porosity */ template Scalar porosity(const Context& context, unsigned spaceIdx, unsigned timeIdx) const { const GlobalPosition& pos = context.pos(spaceIdx, timeIdx); if (isFineMaterial_(pos)) return finePorosity_; else return coarsePorosity_; } /*! * \copydoc FvBaseMultiPhaseProblem::materialLawParams */ template const MaterialLawParams& materialLawParams(const Context& context, unsigned spaceIdx, unsigned timeIdx) const { const GlobalPosition& pos = context.pos(spaceIdx, timeIdx); if (isFineMaterial_(pos)) return fineMaterialParams_; else return coarseMaterialParams_; } /*! * \brief Return the parameters for the energy storage law of the rock * * In this case, we assume the rock-matrix to be granite. */ template const SolidEnergyLawParams& solidEnergyLawParams(const Context& context OPM_UNUSED, unsigned spaceIdx OPM_UNUSED, unsigned timeIdx OPM_UNUSED) const { return solidEnergyLawParams_; } /*! * \copydoc FvBaseMultiPhaseProblem::thermalConductionParams */ template const ThermalConductionLawParams& thermalConductionLawParams(const Context& context, unsigned spaceIdx, unsigned timeIdx) const { const GlobalPosition& pos = context.pos(spaceIdx, timeIdx); if (isFineMaterial_(pos)) return fineThermalCondParams_; return coarseThermalCondParams_; } //! \} /*! * \name Boundary conditions */ //! \{ /*! * \copydoc FvBaseProblem::boundary * * For this problem, we inject air at the inlet on the center of * the lower domain boundary and use a no-flow condition on the * top boundary and a and a free-flow condition on the left and * right boundaries of the domain. */ template void boundary(BoundaryRateVector& values, const Context& context, unsigned spaceIdx, unsigned timeIdx) const { const auto& pos = context.cvCenter(spaceIdx, timeIdx); assert(onLeftBoundary_(pos) || onLowerBoundary_(pos) || onRightBoundary_(pos) || onUpperBoundary_(pos)); if (onInlet_(pos)) { RateVector massRate(0.0); massRate[conti0EqIdx + AirIdx] = -1e-3; // [kg/(m^2 s)] // impose an forced inflow boundary condition on the inlet values.setMassRate(massRate); if (enableEnergy) { Opm::CompositionalFluidState fs; initialFluidState_(fs, context, spaceIdx, timeIdx); Scalar hl = fs.enthalpy(liquidPhaseIdx); Scalar hg = fs.enthalpy(gasPhaseIdx); values.setEnthalpyRate(values[conti0EqIdx + AirIdx] * hg + values[conti0EqIdx + H2OIdx] * hl); } } else if (onLeftBoundary_(pos) || onRightBoundary_(pos)) { Opm::CompositionalFluidState fs; initialFluidState_(fs, context, spaceIdx, timeIdx); // impose an freeflow boundary condition values.setFreeFlow(context, spaceIdx, timeIdx, fs); } else // no flow on top and bottom values.setNoFlow(); } //! \} /*! * \name Volumetric terms */ //! \{ /*! * \copydoc FvBaseProblem::initial * * For this problem, we set the medium to be fully saturated by * liquid water and assume hydrostatic pressure. */ template void initial(PrimaryVariables& values, const Context& context, unsigned spaceIdx, unsigned timeIdx) const { Opm::CompositionalFluidState fs; initialFluidState_(fs, context, spaceIdx, timeIdx); const auto& matParams = materialLawParams(context, spaceIdx, timeIdx); values.assignMassConservative(fs, matParams, /*inEquilibrium=*/true); } /*! * \copydoc FvBaseProblem::source * * For this problem, the source term of all components is 0 * everywhere. */ template void source(RateVector& rate, const Context& context OPM_UNUSED, unsigned spaceIdx OPM_UNUSED, unsigned timeIdx OPM_UNUSED) const { rate = 0; } //! \} private: bool onLeftBoundary_(const GlobalPosition& pos) const { return pos[0] < eps_; } bool onRightBoundary_(const GlobalPosition& pos) const { return pos[0] > this->boundingBoxMax()[0] - eps_; } bool onLowerBoundary_(const GlobalPosition& pos) const { return pos[1] < eps_; } bool onUpperBoundary_(const GlobalPosition& pos) const { return pos[1] > this->boundingBoxMax()[1] - eps_; } bool onInlet_(const GlobalPosition& pos) const { return onLowerBoundary_(pos) && (15.0 < pos[0]) && (pos[0] < 25.0); } bool inHighTemperatureRegion_(const GlobalPosition& pos) const { return (20 < pos[0]) && (pos[0] < 30) && (pos[1] < 30); } template void initialFluidState_(FluidState& fs, const Context& context, unsigned spaceIdx, unsigned timeIdx) const { const GlobalPosition& pos = context.pos(spaceIdx, timeIdx); Scalar densityW = 1000.0; fs.setPressure(liquidPhaseIdx, 1e5 + (maxDepth_ - pos[1])*densityW*9.81); fs.setSaturation(liquidPhaseIdx, 1.0); fs.setMoleFraction(liquidPhaseIdx, H2OIdx, 1.0); fs.setMoleFraction(liquidPhaseIdx, AirIdx, 0.0); if (inHighTemperatureRegion_(pos)) fs.setTemperature(380); else fs.setTemperature(283.0 + (maxDepth_ - pos[1])*0.03); // set the gas saturation and pressure fs.setSaturation(gasPhaseIdx, 0); Scalar pc[numPhases]; const auto& matParams = materialLawParams(context, spaceIdx, timeIdx); MaterialLaw::capillaryPressures(pc, matParams, fs); fs.setPressure(gasPhaseIdx, fs.pressure(liquidPhaseIdx) + (pc[gasPhaseIdx] - pc[liquidPhaseIdx])); typename FluidSystem::template ParameterCache paramCache; typedef Opm::ComputeFromReferencePhase CFRP; CFRP::solve(fs, paramCache, liquidPhaseIdx, /*setViscosity=*/true, /*setEnthalpy=*/true); } void computeThermalCondParams_(ThermalConductionLawParams& params, Scalar poro) { Scalar lambdaGranite = 2.8; // [W / (K m)] // create a Fluid state which has all phases present Opm::ImmiscibleFluidState fs; fs.setTemperature(293.15); for (unsigned phaseIdx = 0; phaseIdx < numPhases; ++phaseIdx) { fs.setPressure(phaseIdx, 1.0135e5); } typename FluidSystem::template ParameterCache paramCache; paramCache.updateAll(fs); for (unsigned phaseIdx = 0; phaseIdx < numPhases; ++phaseIdx) { Scalar rho = FluidSystem::density(fs, paramCache, phaseIdx); fs.setDensity(phaseIdx, rho); } for (unsigned phaseIdx = 0; phaseIdx < numPhases; ++phaseIdx) { Scalar lambdaSaturated; if (FluidSystem::isLiquid(phaseIdx)) { Scalar lambdaFluid = FluidSystem::thermalConductivity(fs, paramCache, phaseIdx); lambdaSaturated = std::pow(lambdaGranite, (1-poro)) + std::pow(lambdaFluid, poro); } else lambdaSaturated = std::pow(lambdaGranite, (1-poro)); params.setFullySaturatedLambda(phaseIdx, lambdaSaturated); if (!FluidSystem::isLiquid(phaseIdx)) params.setVacuumLambda(lambdaSaturated); } } bool isFineMaterial_(const GlobalPosition& pos) const { return pos[dim-1] > layerBottom_; } DimMatrix fineK_; DimMatrix coarseK_; Scalar layerBottom_; Scalar finePorosity_; Scalar coarsePorosity_; MaterialLawParams fineMaterialParams_; MaterialLawParams coarseMaterialParams_; ThermalConductionLawParams fineThermalCondParams_; ThermalConductionLawParams coarseThermalCondParams_; SolidEnergyLawParams solidEnergyLawParams_; Scalar maxDepth_; Scalar eps_; }; } // namespace Ewoms #endif