公路隧道火灾烟气层高度判定方法

doi:10.16265/j.cnki.issn1003-3033.2020.04.023

中国安全科学学报 ›› 2020, Vol. 30 ›› Issue (4): 147-153.doi: 10.16265/j.cnki.issn1003-3033.2020.04.023

公路隧道火灾烟气层高度判定方法

杨小龙, 张玉春^** 教授, 高云骥讲师, 靳开颜, 李智胜, 李涛工程师

西南交通大学消防工程系,四川成都 6111756

收稿日期:2020-01-08 修回日期:2020-03-25 出版日期:2020-04-28 发布日期:2021-01-27
通讯作者: **张玉春(1980—),男,四川什邡人,博士,教授,主要从事大型复杂建筑火灾防治、防灾救援及应急保障等工作。E-mail:zycfire@swjtu.edu.cn。
作者简介:杨小龙(1997—),男,宁夏银川人,硕士研究生,主要研究方向为隧道火灾。E-mail:1062824909@qq.com。
基金资助:
国家自然科学基金资助(51578464)。

Determination method of smoke layer height in road tunnel fire

YANG Xiaolong, ZHANG Yuchun, GAO Yunji, JIN Kaiyan, LI Zhisheng, LI Tao

Department of Fire Protection Engineering, Southwest Jiaotong University, Chengdu Sichuan 611756, China

Received:2020-01-08 Revised:2020-03-25 Online:2020-04-28 Published:2021-01-27

摘要/Abstract

摘要： 浮力频率法、N百分比法、积分比法为常用的3种判断隧道火灾烟气层底部高度的方法,这3种判断方法计算结果与视觉观察结果通常存在偏差,为研究偏差程度及原因,基于火灾动力学模拟软件(FDS)建立长隧道模型,设定6种火源功率,通过竖向能见度分布验证现存判断方法与视觉结果的偏差程度,提出能见度突变法。结果表明:4种方法计算得出隧道火灾烟气层底部高度结果与视觉观察结果的偏差顺序为(按差值占隧道高度比例排序):能见度突变法(1.63%)＜浮力频率法(4.88%)＜N百分比法(N＝30,7.88%)＜积分比法(8.50%);积分比法和浮力频率法结果大于视觉结果;隧道竖向能见度值随高度增加先保持恒定,后突变迅速下降,且HRR越大,下降越快,能见度值越低。

关键词: 隧道火灾, 数值模拟, 火灾模拟软件(FDS), 烟气层高度, 能见度分布

Abstract: Buoyancy frequency method, N percentage method, integral ratio method, are three common methods to determine smoke layer height in tunnel fire, the calculations of three methods are often biased from visual observations.In order to study and explain deviations of calculation results from visual observations, which were found in three common determination methods of smoke layer height in tunnel fire, a long tunnel model was established based on FDS, and six types of fire source power were set. Then, vertical visibility distribution was used to verify deviation between existing determination method and visual results before visibility mutation method was proposed. The results show that the deviation calculated fromabove four methods ranks as visibility mutation method (1.63%) < buoyancy frequency method (4.88%) <N percentage method (N=30, 7.88%) < integral ratio method (8.50%), among which results of integral ratio and buoyancy frequency method are higher than visual ones. It is also found that visibility value in vertical direction of tunnel remains constant and then decreases abruptly as the height increases, and the greater fire power is, the faster it declines, and the lower visibility value there is.

Key words: tunnel fire, numerical simulation, fire dynamics simulator (FDS), smoke layer height, visibility distribution

中图分类号:

X932

杨小龙, 张玉春, 高云骥, 靳开颜, 李智胜, 李涛. 公路隧道火灾烟气层高度判定方法[J]. 中国安全科学学报, 2020, 30(4): 147-153.

YANG Xiaolong, ZHANG Yuchun, GAO Yunji, JIN Kaiyan, LI Zhisheng, LI Tao. Determination method of smoke layer height in road tunnel fire[J]. China Safety Science Journal, 2020, 30(4): 147-153.

参考文献

[1] JIANG Xuepeng, LIU Meijia, WANG Jie. Study on air entrainment coeffcient of one-dimensional horizontal movement stage of tunnel fire smoke in top central exhaust[J]. Tunnelling and Underground Space Technology,2016,60:1-9.
[2] TANG F, LI L J, DONG M S, et al. Characterization of buoyant flow stratification behaviors by Richardson (Froude) number in a tunnel fire with complex combination of longitudinal ventilation and ceiling extraction[J]. Applied Thermal Engineering, 2017,110: 1 021-1 028.
[3] YANG D, HU L H, HUO R, et al. Experimental study on buoyant flow stratification induced by a fire in a horizontal channel[J]. Applied Thermal Engineering, 2010,30(8): 872-878.
[4] 姜学鹏,陈姝,郭昆.集中排烟公路隧道临界排烟速率计算模型[J].中国安全科学学报,2017,27(10): 50-55.
JIANG Xuepeng, CHEN Shu, GUO Kun. Model for prediction of critical smoke extraction rate from road tunnel with central exhaust system[J]. China Safety Science Journal,2017,27(10): 50-55.
[5] COOPER L Y. An experimental study of hot layer stratification in full-scale multiroom fire scenarios[J]. Heat Transfer,1982, 104(4): 741-749.
[6] HE Yaping, Fernando Anthony, LUO Mingchun, et al. Determination of interface height from measured parameter profile in enclosure fire experiment[J]. Fire Safety Journal, 1998,31(1): 19-38.
[7] 李俊楠.积分比值法计算室内火灾烟气层分界面高度值的研究[J].防灾科技学院学报,2014,16(4): 20-24.
LI Junnan. Study on calculation of interval height value of indoor fire smoke layer by integral ratio method[J].Journal of Institute of Disaster Prevention Science and Technology,2014,16(4): 20-24.
[8] STRANG E. Entrainment and mixing in stratified shear flows[J]. Journal of Fluid Mechanics,2001,428:349-386.
[9] GAO Z H, JI J, FAN C G, et al. Determination of smoke layer interface height of medium scale tunnel fire scenarios[J]. Tunnelling and Underground Space Technology,2016,56: 118-124.
[10] XU Zhisheng, ZHAO Jiaming, LIU Qiulin, et al. Experimental investigation on smoke spread characteristics and smoke layer height in tunnels[J]. Fire and Materials, 2019,43(3): 303-309.
[11] JI J, GAO Z H, FAN C G, et al. Large eddy simulation of stack effect on natural smoke exhausting effect in urban road tunnel fires[J].International Journal of Heat and Mass Transfer,2013,66: 531-542.
[12] JI Jie, WAN Huaxian, LI Kaiyuan, et al. A numerical study on upstream maximum temperature in inclined urban road tunnel fires[J]. International Journal of Heat and Mass Transfer, 2015,88: 516-526.
[13] YAO Yongzheng, LI Yingzhen, INGASON H. Numerical study on overall smoke control using naturally ventilated shafts during fires in a road tunnel[J]. International Journal of Thermal Sciences,2019,140: 491-504.
[14] LI Yingzhen,LEI Bo,INGASON H. Scale modeling and numerical simulation of smoke control for rescue stations in long railway tunnels[J]. Journal of Fire Protection Engineering,2012,22(2): 101-103.
[15] 邓玲.FDS场模拟计算中的网格分析[J].消防科学与技术,2006,25(2): 207-210.
DENG Ling. Mesh analysis in the field modeling FDS [J].Fire Science and Technology,2006,25(2): 207-210.
[16] 霍然,胡源,李元洲.建筑火灾安全工程导论: 第2版[M].合肥:中国科学技术大学出版社,2009: 114-115.
[17] 郝彧露,陈俊敏,陈柯衡,等.地下换乘大厅火灾烟气温度分布研究[J].中国安全科学学报,2018,28(5): 80-85.
HAO Yulu, CHEN Junmin, CHEN Keheng, et al.Study on temperature distribution of underground transfer hall fire smoke[J]. China Safety Science Journal, 2018,28(5): 80-85.

公路隧道火灾烟气层高度判定方法

Determination method of smoke layer height in road tunnel fire

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