{ // From buoyantSimpleFoam rho = thermo.rho(); volScalarField rUA = 1.0/UEqn().A(); surfaceScalarField rhorUAf("(rho*(1|A(U)))", fvc::interpolate(rho*rUA)); U = rUA*UEqn().H(); UEqn.clear(); phi = fvc::interpolate(rho)*(fvc::interpolate(U) & mesh.Sf()); bool closedVolume = adjustPhi(phi, U, p); surfaceScalarField buoyancyPhi = rhorUAf*fvc::interpolate(rho)*(g & mesh.Sf()); phi += buoyancyPhi; // Solve pressure for (int nonOrth=0; nonOrth<=nNonOrthCorr; nonOrth++) { fvScalarMatrix pEqn ( fvm::laplacian(rhorUAf, p) == fvc::div(phi) ); pEqn.setReference(pRefCell, pRefValue); // retain the residual from the first iteration if (nonOrth == 0) { eqnResidual = pEqn.solve().initialResidual(); maxResidual = max(eqnResidual, maxResidual); } else { pEqn.solve(); } if (nonOrth == nNonOrthCorr) { // For closed-volume cases adjust the pressure and density levels // to obey overall mass continuity if (closedVolume) { p += (initialMass - fvc::domainIntegrate(psi*p)) /fvc::domainIntegrate(psi); } // Calculate the conservative fluxes phi -= pEqn.flux(); // Explicitly relax pressure for momentum corrector p.relax(); // Correct the momentum source with the pressure gradient flux // calculated from the relaxed pressure U += rUA*fvc::reconstruct((buoyancyPhi - pEqn.flux())/rhorUAf); U.correctBoundaryConditions(); } } #include "continuityErrs.H" rho = thermo.rho(); rho.relax(); Info<< "Min/max rho:" << min(rho).value() << ' ' << max(rho).value() << endl; // Update thermal conductivity K = thermo.Cp()*turb.alphaEff(); }