Smoke and Combustion Products

B. Levin
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引用次数: 2

Abstract

Seventy-six percent of the people that died in structural fires in 1990 died from the inhalation of toxic combustion products, not from burns (1). This percentage has been rising by about one percentage point per year since 1979. Although total deaths in fires are declining, the percentage attributed to smoke inhalation has increased. An area of research called combustion toxicity has evolved to study the adverse health effects caused by smoke or fire atmospheres. According to the American Society for Testing and Materials (ASTM), smoke consists of “the airborne solid and liquid particulates and gases evolved when a material undergoes pyrolysis or combustion” (2) and therefore, includes combustion products. In this chapter, a fire atmosphere is defined as all the effluents generated by the thermal decomposition of materials or products regardless of whether that effluent is produced under smoldering, nonflaming, or flaming conditions. The objectives of combustion toxicity research are to identify potentially harmful products from the thermal degradation of materials, to determine the best measurement methods for the identification of the toxicants as well as the degree of toxicity, to determine the effect of different fire exposures on the composition of the toxic combustion products, to predict the toxicity of the combustion atmospheres based on the concentrations and the interaction of the toxic products, and to establish the physiological effects of such products on living organisms. The ultimate goals of this field of research are to reduce human fire fatalities due to smoke inhalation, to determine effective treatments for survivors, and to prevent unnecessary suffering of fire casualties caused by smoke inhalation. Other reviews of various aspects of this subject can be found in Refs 3–8. Keywords: Smoke; Combustion; Fire deaths; Toxic gases; Particulates; Toxic potency; Fire hazard; Fire risk; Toxicity assessment; Suppressants; Test methods; Predictive models
烟雾和燃烧产物
1990年死于结构性火灾的人中有76%死于吸入有毒燃烧产物,而不是烧伤(1)。自1979年以来,这一比例每年上升约一个百分点。虽然火灾造成的总死亡人数在下降,但吸入烟雾造成的死亡人数比例有所上升。一个叫做燃烧毒性的研究领域已经发展到研究烟雾或火灾环境对健康造成的不利影响。根据美国材料试验协会(ASTM)的说法,烟雾由“材料在热解或燃烧过程中产生的空气中的固体和液体颗粒和气体”组成(2),因此也包括燃烧产物。在本章中,火灾气氛被定义为材料或产品热分解产生的所有流出物,无论该流出物是在阴燃、非燃烧或燃烧条件下产生的。燃烧毒性研究的目标是识别材料热降解产生的潜在有害产物,确定识别有毒物质及其毒性程度的最佳测量方法,确定不同火灾暴露对有毒燃烧产物组成的影响,根据有毒产物的浓度和相互作用预测燃烧气氛的毒性。并确定这些产品对生物体的生理作用。这一研究领域的最终目标是减少因吸入烟雾而导致的火灾死亡人数,为幸存者确定有效的治疗方法,并防止因吸入烟雾而造成不必要的火灾伤亡。关于这个主题的各个方面的其他评论可以在参考文献3-8中找到。关键词:烟;燃烧;火灾死亡;有毒气体;微粒;有毒的效力;火灾隐患;火灾风险;毒性的评估;抑制剂;测试方法;预测模型
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