Small scale pool fires: The case of toluene

IF 3.6 3区工程技术 Q2 ENGINEERING, CHEMICAL

Journal of Loss Prevention in The Process Industries Pub Date : 2024-09-10 DOI:10.1016/j.jlp.2024.105430

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引用次数: 0

Abstract

Industrial applications adopting toluene as a solvent have been largely extended in recent years, including solutions within the framework of the energy transition and energy storage technologies. The potential use of this flammable compound in a different set of operative conditions and compositions requires a comprehensive and complete knowledge of its fire behaviour and combustion kinetic. To this scope, an innovative experimental procedure applicable to liquid reactive systems was developed for this scope and implemented at different boundary conditions. More specifically, the specimen was exposed to air and heat fluxes between 7 and 50 kW/m², at a constant sample surface of 0.01 m², an initial sample thickness of 0.01 m, and a distance between the sample and the horizontally oriented conical-shaped heater of 0.025 m. Measurements were compared with data from the current literature, when available, demonstrating the robustness and validity of the adopted procedure. Although an increase in the external flux leads to growing mass burning rates (i.e., from 0.47 g/s to 0.85 g/s), negligible effects on the ignitability were observed. Conversely, a peak in the heat release rate at 35 kW/m² was measured. The observed reduction at higher external heat fluxes was attributed to less effective combustion, demonstrating that the maximum expected heat flux cannot be considered as an aprioristic worst-case scenario for the evaluation of pool fires. The collected data were, then, further utilized to obtain insights on the formation of the main products, including soot tendency. Based on the collected data a simplified kinetic model suitable for the computational fluid dynamics was proposed to reproduce the chemistry of the system.

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小规模池火：甲苯案例

近年来，采用甲苯作为溶剂的工业应用已在很大程度上得到扩展，包括能源转型和能源储存技术框架内的解决方案。要在不同的工作条件和组成中使用这种易燃化合物，就必须全面、完整地了解其燃烧行为和燃烧动力学。为此，我们开发了一种适用于液体反应系统的创新实验程序，并在不同的边界条件下实施。更具体地说，试样暴露在 7 至 50 kW/m2 的空气和热通量中，试样表面恒定为 0.01 m2，初始试样厚度为 0.01 m，试样与水平方向锥形加热器之间的距离为 0.025 m。虽然外部通量的增加会导致质量燃烧率的增加（即从 0.47 克/秒增加到 0.85 克/秒），但对点燃性的影响可以忽略不计。相反，在 35 kW/m2 处测得的热释放率达到峰值。在外部热通量较高的情况下，观察到的热释放率降低是由于燃烧效果较差，这表明最大预期热通量不能作为评估池火灾的最坏情况的先决条件。然后，进一步利用收集到的数据来了解主要产物的形成情况，包括烟尘倾向。根据收集到的数据，提出了一个适合计算流体动力学的简化动力学模型，以再现系统的化学反应。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Loss Prevention in The Process Industries 工程技术-工程：化工

CiteScore

7.20

自引率

14.30%

发文量

226

审稿时长

52 days

期刊介绍： The broad scope of the journal is process safety. Process safety is defined as the prevention and mitigation of process-related injuries and damage arising from process incidents involving fire, explosion and toxic release. Such undesired events occur in the process industries during the use, storage, manufacture, handling, and transportation of highly hazardous chemicals.