Monte Carlo method for radiative heat transfer analysis of general gas-particle enclosures

A hybrid two-dimensional finite element-Monte Carlo numerical solution method has been developed for solving complex transient non-linear gas radiation enclosure problems. Solid conducting media are coupled to conducting gaseous or particulate participating media and both may be internally energy ge

An analytical method is developed to study the radiative energy transfer in a non-grey-gas layer by using a Monte Carlo method. The gas is composed of water vapour, carbon dioxide and nitrogen. The profiles of the monochromatic absorption coefficient of each component gas are calculated by using the

The zone method is applied to non-orthogonal curvilinear grids for the computation of radiative heat transfer. The interchange areas are calculated by the Monte Carlo technique which has been fitted with a generalized ray tracing procedure. The method is applied to two complex three-dimensional (3-D

## Abstract Direct simulation Monte Carlo (DSMC) method has been widely used to study gaseous flow and heat transfer in micro‐fluidic devices. For flows associated with microelectromechanical systems (MEMS), the heat‐flux‐specified (HFS) boundary condition broadly exists. However, problems with HFS

An algorithm for total heat transfer in a furnace chamber was analysed for various operating conditions. The emphasis is on radiative heat transfer by carbon dioxide and water vapour, and methods of calculating their overlap. The algorithm was used for real-time monitoring of the reheating of slabs