A stochastic combustion model for fire plumes

A stochastic model for compartment fires in buildings is derived from basic physical laws. It consists of just three variables, which form a Markov vector satisfying a stochastic differential equation. The deterministic version of the model can be calibrated to closely mimic more elaborate models. S

Models In the literature for fluldlzed bed coal combustors are tabulated and examined with regard to their crItIca assumptions These models are shown to not represent, even qualltatlvely, the expected behavior of the large scale atmospheric fluldlzed bed combustor (AFBC) with Its large-particle tube

Models are developed to describe horizontal insulated cables and cable trays exposed to a fire plume. The models also apply to cables protected by fire-retardant coatings. A cable or coated cable can ignite when its surface is hot enough to generate flammable gas, unless the level of 0 2 available i

Asymptotic and scaling analyses are applied to develop a simple model for a turbulent convective plume at high Bayleigh number R in a high Prandtl number fluid layer whose lower boundary surface maintains steady local buoyant sources. The convective plume is assumed to be axisymmetric and conical wh