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[1]游温娇,徐志胜,孔杰.盾构铁路隧道坡度对火灾烟气蔓延的影响研究*[J].中国安全生产科学技术,2021,17(9):132-138.[doi:10.11731/j.issn.1673-193x.2021.09.021]
 YOU Wenjiao,XU Zhisheng,KONG Jie.Study on influence of slope on fire smoke spread in shield railway tunnel[J].JOURNAL OF SAFETY SCIENCE AND TECHNOLOGY,2021,17(9):132-138.[doi:10.11731/j.issn.1673-193x.2021.09.021]
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盾构铁路隧道坡度对火灾烟气蔓延的影响研究*
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《中国安全生产科学技术》[ISSN:1673-193X/CN:11-5335/TB]

卷:
17
期数:
2021年9期
页码:
132-138
栏目:
职业安全卫生管理与技术
出版日期:
2021-09-30

文章信息/Info

Title:
Study on influence of slope on fire smoke spread in shield railway tunnel
文章编号:
1673-193X(2021)-09-0132-07
作者:
游温娇徐志胜孔杰
(1.浙江警察学院,浙江 杭州 310053;
2.中南大学 防灾科学与安全技术研究所,湖南 长沙 410075;
3.中国计量大学 质量与安全工程学院,浙江 杭州 310018)
Author(s):
YOU Wenjiao XU Zhisheng KONG Jie
(1.Zhejiang Police College,Hangzhou Zhejiang 310053,China;
2.Institute of Disaster Prevention Science and Safety Technology,Central South University,Changsha Hunan 410075,China;
3.College of Quality and Safety Engineering,China Jiliang University,Hangzhou Zhejiang 310018,China)
关键词:
火灾安全铁路隧道烟气蔓延坡度隧道烟囱效应
Keywords:
fire safety railway tunnel smoke spread slope tunnel stack effect
分类号:
X932
DOI:
10.11731/j.issn.1673-193x.2021.09.021
文献标志码:
A
摘要:
为研究坡度隧道内列车阻滞后的火灾烟气蔓延行为,利用火灾动力学模拟软件(FDS)建立盾构铁路隧道火灾模型和CRH6高速列车阻滞模型,隧道坡度分别为0%、1.0%、1.5%、2.0%、2.5%、3.0%、3.5%和4.0%,通过分析隧道内烟气、温度、能见度等特征参数的变化规律,研究坡度隧道内高温烟气的受力情况,探讨坡度变化对火灾烟气蔓延的作用机理。结果表明,坡度隧道内发生火灾,随着烟气的蔓延,隧道内形成沿坡度方向的烟囱效应力,使得烟气在火源两侧呈不对称分布。火源下游区域的高温烟气在火风压和烟囱效应的协同作用下蔓延速度比上游更快,下游烟气层分界中性面与隧道轴线平行,上游烟气层分界中性面呈现水平状态。有坡度的铁路隧道内发生火灾,建议向火源下游方向施加纵向机械通风,人员向火源的上游方向疏散逃生更安全。
Abstract:
In order to study the fire smoke spread behavior after the train blocks in the slope tunnel,a fire model of shield railway tunnel and a block model of CRH6 high-speed train were established by using the Fire Dynamics Simulation (FDS) software.The tunnel slopes were set to be 0%,1.0%,1.5%,2.0%,2.5%,3.0%,3.5% and 4.0%,respectively,through analyzing the change laws of characteristic parameters such as smoke,temperature and visibility in the tunnel,the force status of high-temperature smoke in the slope tunnel was studied,and the action mechanism of slope change on the fire smoke spread was discussed.The results showed that when the fire occurred in the slope tunnel,with the spread of smoke,the stack effect force along the slope direction was formed in the tunnel,which made the smoke distribute asymmetrically on two sides of fire source.The high-temperature smoke in downstream region of fire source spread faster than that in upstream region under the synergistic effect of fire wind pressure and stack effect.The neutral surface of the smoke layer in downstream region was parallel to the tunnel axis,and the neutral surface of the smoke layer in upstream region presented a horizontal state.In case of a fire in slope railway tunnel,it was recommended to apply longitudinal mechanical ventilation to the downstream direction of fire source,and it was safer for people to evacuate to the upstream direction of fire source.

参考文献/References:

[1]曹正卯.关角隧道运营通风防灾技术研究[D].成都:西南交通大学,2011.
[2]王明年,李琦,于丽,等.高海拔隧道通风、供氧、防灾与节能技术的发展[J].隧道建设,2017,37(10):1209-1216. WANG Mingnian,LI Qi,YU Li,et al.Development of new technologies for ventilation,oxygen supply,disaster prevention and energy saving for high-altitude tunnels[J].Tunnel Construction,2017,37(10):1209-1216.
[3]郭春,王明年,赵海东.铁路特长隧道火灾应急救援问题研究[J].中国安全科学学报,2007,17(9):153-158,181. GUO Chun,WANG Mingnian,ZHAO Haidong.Research on the emergency rescue of fire in super long rail way tunnel [J].China Safety Science Journal,2007,17(9):153-158,181.
[4]李国良,司剑钧,李宁,等.兰渝铁路西秦岭特长隧道方案研究[J].现代隧道技术,2014,51(3):7-14. LI Guoliang,SI Jianjun,LI Ning,et al.Construction scheme of the west Qinling extra-long tunnel on the Lanzhou-Chongqing railway [J].Modern Tunnelling Technology,2014,51(3):7-14.
[5]周惠贤.新建铁路兰州至重庆线夏官营至广元段西秦岭隧道防灾救援技术研究[D].成都:西南交通大学,2014.
[6]徐志胜,孔杰,游温娇,等.单洞双线铁路隧道火灾人员疏散安全性分析[J].中国安全生产科学技术,2019,15(1):183-188. XU Zhisheng,KONG Jie,YOU Wenjiao,et al.Analysis on safety of personnel evacuation in fire of single-hole double-line railway tunnel [J].Journal of Safety Science and Technology,2019,15(1):183-188.
[7]王爱武,徐志胜,游温娇,等.CRH6高速列车火灾规模及影响因素研究[J].安全与环境学报,2019,19(4):1259-1265. WANG Aiwu,XU Zhisheng,YOU Wenjiao,et al.Analysis of the fire scale and the influential factors of CRH6 express train[J].Journal of Safety and Environment,2019,19(4):1259-1265.
[8]LEE S R,HONG S R.A numerical study on smoke movement in longitudinal ventilation tunnel fires for different aspect ratio[J].Building and Environment,2006,41(1):719-725.
[9]HU L H,CHEN L F,WU L,et al.An experimental investigation and correlation on buoyant gas temperature below ceiling in a slopping tunnel fire[J].Applied Thermal Engineering,2013,51(1):246-254.
[10]SUN J H,LI K Y,HAN J Y,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(1):516-526.
[11]CHOW W K,GAO Y,ZHAO J H,et al.A study on tilted tunnel fire under natural ventilation[J].Fire Safety Journal,2016,81(1):44-57.
[12]TANG W,HU L H,CHEN L F.Effect of blockage-fire distance on buoyancy driven back-layering length and critical velocity in a tunnel:An experimental investigation and global correlations[J].Applied Thermal Engineering,2013,60(1):7-14.
[13]WU Y,BAKAR M Z A.Control of smoke flow in tunnel fires using longitudinal ventilation systems-a study of the critical velocity[J].Fire Safety Journal,2000,35(1):363-390.
[14]LI Y Z,LEI B,HAUKURI.Study of critical velocity and backlayering length in longitudinally ventilated tunnel fires[J].Fire Safety Journal,2010,45(6):361-370.
[15]LEE Y P,TSAI K C.Effect of vehicular blockage on critical ventilation velocity and tunnel fire behavior in longitudinally ventilated tunnels[J].Fire Safety Journal,2012,53(1):35-42.
[16]GANNOUNI S,MAAD R B.Numerical study of the effect of blockage on critical velocity and back-layering length in longitudinally ventilated tunnel fires[J].Tunnelling and Underground Space Technology,2015,48(1):147-155.
[17]YI L,XU Q Q,XU Z S,et al.An experimental study on critical velocity in sloping tunnel with longitudinal ventilation under fire[J].Tunnelling and Underground Space Technology,2014,43(1):198-203.
[18]WENG M C,LU X L,LIU F,et al.Study on the critical velocity in a sloping tunnel fire under longitudinal ventilation[J].Applied Thermal Engineering,2016,94(1):422-434.
[19]ZHANG S G,CHENG X D,YAO Y Z,et al.An experimental investigation on blockage effect of metro train on the smoke back-layering in subway tunnel fires[J].Applied Thermal Engineering,2016,99(1):214-223.
[20]ZHU K,YAO Y Z,ZHANG S G,et al.Smoke movement in a sloping subway tunnel under longitudinal ventilation with blockage[J].Fire Technology,2017,53(6):1985-2006.
[21]ZHANG S G,YAO Y Z,ZHU K,et al.Prediction of smoke back-layering length under different longitudinal ventilations in the subway tunnel with metro train[J].Tunnelling and Underground Space Technology,2016,53(1):13-21.
[22]KEVIN MCGRATTAN,GLENN FORNEY.Fire Dynamics Simulator (Version 4) uesr’s Guide[M].NIST,2004.
[23]HWANG C C,EDWARDS J C.The critical ventilation velocity in tunnel fires-a computer simulation[J].Fire Safety Journal,2005(40):213-144.
[24]FAN C G,JI J,WANG W,et al.Effects of vertical shaft arrangement on natural ventilation performance during tunnel fires[J].Elsevier Ltd,2014,73(1):158-169.
[25]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].Pergamon,2013,66(1):531-542.
[26]国家铁路局.高速铁路设计规范:TB 10621—2014[S].北京:中国铁道出版社,2015.

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备注/Memo

备注/Memo:
收稿日期: 2020-04-30
* 基金项目: 浙江省安全工程与技术研究重点实验室项目(202002)
作者简介: 游温娇,博士,讲师,主要研究方向为隧道消防、社会治安管理。
更新日期/Last Update: 2021-10-02