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1. Toxicity of combustion products from burning polymers: development and evaluation of methods

Author

P. L. Wright and C. H. Adams

Subjects

Male, Paper, Hot Temperature, Time Factors, Materials science, Injury control, Polymers, Accident prevention, Health, Toxicology and Mutagenesis, Polyurethanes, Poison control, chemical and pharmacologic phenomena, Fires, Lethal Dose 50, Propane, Organophosphorus Compounds, Smoke, Methods, Animals, chemistry.chemical_classification, Gossypium, Methanol, Textiles, Temperature, technology, industry, and agriculture, Public Health, Environmental and Occupational Health, Articles, Polymer, Pulp and paper industry, Wood, Rats, chemistry, Wool, Combustion products, Female

Abstract

Laboratory and room-scale experiments were conducted with natural and synthetic polymers: cotton, paper, wood, wool, acetate, acrylic, nylon, and urethane. Smoke and off-gases from single materials were generated in a dual-compartment 110-liter exposure chamber. Multicomponent, composite fuel loads were burned within a 100 m3 facility subdivided into rooms. In chamber experiments, mortality depended on the amount of material burned, i.e., fuel consumption (FC). Conventional dose (FC)/mortality curves were obtained, and the amount of fuel required to produce 50% mortality (FC50) was calculated. With simple flame ignition, cotton was the only material that produced smoke concentrations lethal to rats; FC50 values for cotton ranged from 2 g to 9 g, depending on the configuration of the cotton sample burned. When supplemental conductive heat was added to flame ignition, the following FC50 values were obtained; nylon, 7 g; acrylic, 8 g; newsprint, 9 g; cotton, 10 g; and wood, 11 g. Mortality resulting from any given material depended upon the specific conditions employed for its thermal decomposition. Toxicity of off-gasses from pyrolysis of phosphorus-containing trimethylol propane—polyurethane foams was markedly decreased by addition of a flame ignition source. Further studies are needed to determine the possible relevance of single-material laboratory scale smoke toxicity experiments. Room-scale burns were conducted to assess the relative contributions of single materials to toxicity of smoke produced by a multicomponent self-perpetuating fire. Preliminary results suggest that this approach permits a realistic evaluation of the contribution of single materials to the toxicity of smoke from residential fires. ImagesFIGURE 2.

Published

1976