There were two sets of thermalModels in conjugateHeatTransfer library and
solidModels library. They are now merged into the conjugateHeatTransferLibrary
1. minCellVolumeRefinement: selects all cells with volume higher than specified
one
2. minPatchDistanceRefinement: selects all cells at the distance greater than
specified distance from a set of patches
3. compositeRefinementSelection: selects intersection of all sets obtained from
other (basic) refinement selections
Scaling the fluxes and killing non-orthogonal correction vectors in case
bridging is used, both in order to ensure global conservation across bridged GGI
with potentially partially overlapping faces.
Need to create volPointInterpolation object within the time loop (after the mesh
has been read) in order to avoid issues related to already calculated demand
driven data.
1. dynamicRefinePolyFvMesh class (replaced by dynamicPolyRefinementFvMesh)
2. polyRef class (replaced by polyhedralRefinement polyMesh modifier)
3. polyRefinementHistory (not required anymore)
Removed redundant check of split points at the boundaries. In case of dynamic
load balancing, it should perform possible unrefinement where the split point is
on the processor boundary. Although this has not been tested yet.
There was a bug when we had refinement and unrefinement in the same iteration.
Setting split points to unrefine needs to take into account existing cells to
refine by considering point neighbours, not face neighbours. This ensures that
the first split point to unrefine is far away from refinement region.
Only one topo change iteration per time step. This is handled withing
dynamicPolyRefinementFvMesh class instead of polyhedralRefinement
(is a polyMeshModifier) in order to skip the unnecessary cell/point selection
step as well.
While ensuring point consistent refinement/unrefinement, we need to loop over
all points in order to correctly take into account point consistency across
processor boundaries.
Rewrite of private data using lazy evaluation. The data was calculated on
creation and mesh update, which caused a very messy problem.
volPointInterpolation is a mesh object and it relies on pointMesh, which is
another mesh object. Therefore, in order to have valid update of
volPointInterpolation on topo changes, pointMesh needs to be updated first. This
is avoided by using lazy evaluation.