自然风对竖井排烟特长公路隧道火灾烟气扩散特性的影响

doi:10.3973/j.issn.2096-4498.2025.02.007

隧道建设（中英文） ›› 2025, Vol. 45 ›› Issue (2): 315-323.DOI: 10.3973/j.issn.2096-4498.2025.02.007

自然风对竖井排烟特长公路隧道火灾烟气扩散特性的影响

陈利¹，刘兵¹，曹志²，陈佳佳¹，张恒^{3, 4}，张志强^{3, 4, *}

（1. 中铁十六局集团第一工程有限公司，北京 101300； 2. 中铁十六局集团第五工程有限公司，河北唐山 064000； 3. 极端环境岩土和隧道工程智能建养全国重点实验室，四川成都 610031； 4. 西南交通大学土木工程学院，四川成都 610031）

出版日期:2025-02-20 发布日期:2025-02-20
作者简介:陈利(1985—)，男，湖北黄梅人，2008年毕业于华中科技大学，电气及其自动化专业，本科，高级工程师，现从事隧道工程技术管理工作。E-mail： 53262602@qq.com。 *通信作者：张志强， E-mail： clarkchang68@163.com。

Influence of Natural Wind on Fire Smoke Diffusion Characteristics Through Shafts in Extra-Long Highway Tunnels

CHEN Li¹, LIU Bing¹, CAO Zhi², CHEN Jiajia¹, ZHANG Heng^{3, 4}, ZHANG Zhiqiang^{3, 4, *}

(1. China Railway 16th Bureau Group No. 1 Engineering Co., Ltd., Beijing 101300, China; 2. China Railway 16th Bureau Group No. 5 Engineering Co., Ltd., Tangshan 064000, Hebei, China; 3. State Key Laboratory of Intelligent Geotechnics and Tunnelling, Chengdu 610031, Sichuan, China; 4. School of Civil Engineering, Southwest Jiaotong University, Chengdu 610031, Sichuan, China)

Online:2025-02-20 Published:2025-02-20

摘要/Abstract

摘要： 为探明隧道内自然风对火灾烟气扩散特性的影响，为隧道火灾的通风与排烟系统优化提供科学依据，对云山特长公路隧道洞内自然风进行现场监测，得到洞内自然风分布规律。采用数值模拟方法，建立竖井排烟作用下三维火灾动力学模型，对同向及反向自然风影响下隧道温度场及烟气场进行分析，结果表明： 1）该隧道所处环境的温度能够维持隧道内外相对较大且稳定的热位差，有利于形成自然风，最大自然风速可达5.0 m/s以上。2）在纵向风速3.0 m/s时，同向自然风会扩大隧道温升范围，火源与排烟口之间隧道下部区域温度较低。3）反向自然风会抑制高温场的扩散，且火源与排烟口之间温度随自然风速的增大而升高。4）当隧道内同向自然风速不超过2.5 m/s时火源与排烟口之间烟气质量分数最大，隧道上部空间烟气质量分数大于下部空间。5）当同向自然风速大于3.5 m/s时，下游烟气层结构被破坏，烟气在纵断面内均匀分布。6）反向自然风有利于限制烟气向排烟口下游蔓延，随着自然风的增大，排烟口下游烟气蔓延长度逐渐减小且趋于恒定。7）隧道内同向及反向自然风均会使排烟效率降低，相比无自然风条件，4.0 m/s的同向及反向自然风使竖井排烟效率分别降低22.43%、21.55%，同向自然风对竖井排烟效率的影响程度大于反向自然风。

关键词: 特长公路隧道, 自然风, 隧道火灾, 竖井排烟, 烟气蔓延, 现场测试, 数值模拟

Abstract: The authors examine the effects of natural wind in tunnels on fire smoke diffusion characteristics, with the aim of providing a scientific basis for optimizing tunnel fire ventilation and smoke exhaust systems. The natural wind conditions in the Yunshan extra-long highway tunnel are monitored on site to determine its distribution pattern. In addition, a three-dimensional fire dynamics model is developed through a numerical simulation to evaluate the temperature and smoke fields under the influence of smoke exhaust through a shaft, where the effects of natural wind blowing from both the same and opposite directions are analyzed. Key findings include: (1) The ambient temperature in the tunnel maintains a substantial and stable thermal potential difference between the inside and outside, promoting the formation of natural wind, with a maximum speed exceeding 5.0 m/s. (2) At a longitudinal wind speed of 3.0 m/s, natural wind from the same direction increases the range of temperature rise within the tunnel while lowering the temperature in the lower section between the fire source and exhaust outlet. (3) The natural wind from opposite directions inhibits the diffusion of the high-temperature field, with temperatures between the fire source and smoke outlet rising as natural wind speed increases. (4) When the natural wind speed from the same direction does not exceed 2.5 m/s, smoke concentration peaks between the fire source and the smoke outlet, with higher concentrations in the upper part of the tunnel as compared to the lower part. (5) At wind speeds exceeding 3.5 m/s from the same direction, the stratification of downstream flue gas is disrupted, leading to a more uniform distribution of flue gas. (6) Natural wind from opposite directions helps to limit the downstream spread of smoke from the exhaust port: as wind speed increases, the distance that smoke spreads downstream decreases and approaches a constant value. (7) Both natural wind from the same and opposite directions reduce smoke exhaust efficiency. Specifically, at a wind speed of 4.0 m/s, the smoke exhaust efficiency of the shaft decreases by 22.43% and 21.55%, respectively, compared to conditions without natural wind. The effects of natural wind from the same direction on the smoke exhaust efficiency are greater than those of wind from opposite directions.

Key words: extra-long highway tunnel, natural wind, tunnel fire, smoke exhaust through shaft, smoke spread, on-site test, numerical simulation

陈利, 刘兵, 曹志, 陈佳佳, 张恒, 张志强. 自然风对竖井排烟特长公路隧道火灾烟气扩散特性的影响[J]. 隧道建设, 2025, 45(2): 315-323.

CHEN Li, LIU Bing, CAO Zhi, CHEN Jiajia, ZHANG Heng, ZHANG Zhiqiang. Influence of Natural Wind on Fire Smoke Diffusion Characteristics Through Shafts in Extra-Long Highway Tunnels[J]. Tunnel Construction, 2025, 45(2): 315-323.

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自然风对竖井排烟特长公路隧道火灾烟气扩散特性的影响

Influence of Natural Wind on Fire Smoke Diffusion Characteristics Through Shafts in Extra-Long Highway Tunnels

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