Publication Date:
2011-08-19
Description:
Based on multilevel partitioning, this paper develops a structural parallelizable solution methodology that enables a significant reduction in computational effort and memory requirements for very large scale linear and nonlinear steady and transient thermal (heat conduction) models. Due to the generality of the formulation of the scheme, both finite element and finite difference simulations can be treated. Diverse model topologies can thus be handled, including both simply and multiply connected (branched/perforated) geometries. To verify the methodology, analytical and numerical benchmark trends are verified in both sequential and parallel computer environments.
Keywords:
FLUID MECHANICS AND HEAT TRANSFER
Type:
Numerical Heat Transfer, Part B: Fundamentals (ISSN 1040-7790); 19; 127-152
Format:
text