Citation

de Ris JL, Khan MM. Fire Mater. 2000; 24(5): 219-226.

Copyright

(Copyright © 2000, John Wiley and Sons)

DOI

unavailable

PMID

unavailable

Abstract

The determination of material properties, such as thermal conductivity, for use in fire models requires precise knowledge of all hear losses, For example, the ignition and subsequent burning of solid samples is sensitive to heat losses from the rear surface of the tested sample. The heat loss depends on the sample holder and its environment. Theoretical predictions of ignition and pyrolysis in standard flammability apparatuses show that the construction of the sample holder has a surprisingly large effect on measured properties especially for thermally thin samples. This makes flammability measurements and inferred thermal properties apparatus dependent, For example, ignition measurements of 6.4 mm (1/4 ") plywood samples show a 40% reduction in the critical heat flux for ignition, The back and sides of the sample were sealed by wrapping it with aluminium foil tape. Heat losses from the sample were minimized by placing it on a sample holder having four layers of 3.2 mm (1/8 ") thick insulating ceramic paper surrounded by an outer layer of aluminium tape. A detailed mathematical model is developed to fully characterize the thermal response of a sample to a prescribed heat flux in a standard flammability apparatus, The model is used to estimate the residual heat losses not eliminated by the sample holder. Model predictions accurately track the temperature response of blackened brass plates of different thicknesses exposed to several different incident heat fluxes. Brass, of course, has well known thermophysical properties; so, it also provides an excellent means for in situ calibration of the incident heat fluxes.