Citation

Di Blasi C. Fire Safety J. 1995; 25(4): 287-304.

Copyright

(Copyright © 1995, Elsevier Publishing)

DOI

unavailable

PMID

unavailable

Abstract

The effects of solid thickness on the initial stages of concurrent flame spread are studied through numerical simulation. The two-dimensional mathematical formulation of the problem is based on the fully elliptic, reactive Navier-Stokes equations coupled to energy and mass conservation equations for a charring solid. For all fuel thicknesses, uniform burn-out, pyrolysis and flame propagation rates are approached after an accelerative stage. As with the opposed flow problem, three main regimes of spread rate are established based on the dependence on fuel thickness. The first (kinetic) regime, where spread rates increase with the thickness, is established for samples below 0.008 x 10-2 m. Both flame and pyrolysis lengths are very short. In the second (thermally thin) regime, the spread rates decrease as the solid thickness is increased while the flame and the pyrolysis regions become successively larger. Finally, as the fuel thickness is increased above 0.5 x 10-2 m, the thermally thick regime, signified by constant spread rates, is simulated. As no experimental measurements of spread rate dependency on the thickness of charring materials are available, numerical predictions are compared with a thermal theory to assess its validity limits.