Study on smoke propagation in tunnel construction of a hydropower station: A full-scale fire experiment

IF 3.7 Q1 PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH 安全科学与韧性(英文) Pub Date : 2023-06-01 DOI:10.1016/j.jnlssr.2022.11.002
Chang Liu , Huihang Cheng , Wenjun Nie , Senlin Jiang , Junfeng Chen , Peng Lin , Maohua Zhong
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引用次数: 1

Abstract

In this study, full-scale fire experiments were conducted in a hydropower station to investigate smoke propagation during tunnel construction. The flame height, smoke temperature and stratification, smoke descent and spread velocity were analyzed via measurements and on-site observations. The initial combustion stage was largely affected by ignition source during tunnel construction for diesel pool fire, and the average flame height in the fully developed stage could reach 1.4–2.1 m in experimental fire scenarios. The gradient of the smoke temperature evolution near the fire was the opposite for the upstream and downstream regions. The longitudinal temperature distribution was concentrated in a small range at the heights of the smoke layer, and gradually decreased by air entrainment as the height decreased, while further increasing in the lower half of the tunnel height in the near-fire region under heat radiation from the fire source. Moreover, distinct and stable smoke stratification formed during the fully developed combustion stage, and the smoke layer interface was at approximately half the tunnel height. Smoke descent was aggravated in the decay stage of combustion, and the fire risk remained high after the fully developed period. The smoke front spread velocity was empirically determined for the full-scale tunnel fire scenarios. Conclusions from full-scale experiments can support smoke control design and on-site fire emergency response plans for hydropower stations.

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水电站隧道施工中烟气传播的全尺寸火灾试验研究
本文以某水电站为研究对象,对隧道施工过程中烟气的传播规律进行了实验研究。通过测量和现场观察,分析了火焰高度、烟雾温度和分层、烟雾下降和蔓延速度。柴油池火灾隧道施工初期燃烧阶段受点火源影响较大,实验火灾场景中充分发展阶段平均火焰高度可达1.4 ~ 2.1 m。火灾附近烟温演变的梯度在上游和下游地区相反。纵向温度分布在烟层高度处集中在一个小范围内,随着烟层高度的降低,随着烟层高度的降低,烟层温度随着烟层高度的降低而逐渐降低,在火源热辐射作用下,烟层温度在近火区隧道高度的下半部分进一步升高。燃烧充分发展阶段形成了明显而稳定的烟层,烟层界面位于巷道高度的一半左右。燃烧衰减期烟气下降加剧,充分发育期后火灾危险性仍然较高。在全尺寸隧道火灾场景下,通过经验确定了烟气前缘扩散速度。全尺寸试验的结论可以为水电站的防烟设计和现场火灾应急预案提供支持。
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来源期刊
安全科学与韧性(英文)
安全科学与韧性(英文) Management Science and Operations Research, Safety, Risk, Reliability and Quality, Safety Research
CiteScore
8.70
自引率
0.00%
发文量
0
审稿时长
72 days
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