Gold Science and Technology
img

Wechat

Adv. Search
Online Submission Peer Review Office Work

Gold Science and Technology ›› 2020, Vol. 28 ›› Issue (2): 293-300.doi: 10.11872/j.issn.1005-2518.2020.02.165

• Mining Technology and Mine Management • Previous Articles    

Study on the Influence of Altitude on Smoke Propagation Law in Mine Roadway Fire

Rui HUANG1(),E WU1(),Lin WU1,2   

  1. 1.School of Resources and Safety Engineering,Central South University,Changsha 410083,Hunan,China
    2.Safety and Security Theory Innovation and Promotion Center(STIPC),Central South University,Changsha 410083,Hunan,China
  • Received:2019-10-05 Revised:2020-01-17 Online:2020-04-30 Published:2020-05-07
  • Contact: E WU E-mail:huangrui@csu.edu.cn;wue2397588229@126.com

RichHTML

3

PDF (PC)

638

Abstract:

In the process of mine safety production,frequent mine fire accidents have caused huge casualties and economic losses,which has become one of the major concerns.The environment conditions of mines at different altitudes are completely different,which directly affects the evolution of the mine fire,and brings great challenges to the emergency rescue work during the mine fire.Therefore,it is of great practical significance to study the effect of altitude on the law of smoke spread during the mine roadway fire period.In this paper,based on the construction of the mine fire model,the key paramaters of the fire smoke at the characteristic height of the human eye (z=1.6 m) were used as the focus,fire scenarios of the mine mechanical and electrical chamber at five groups of different altitudes from 0 m to 4 000 m(equal points) was simulated by using the Fire Dynamics Simulator(FDS).By observing the process of smoke diffusion and dynamic temperature rise in different fire scenarios,the law of smoke diffusion and temperature distribution in mine roadway at different altitudes was analyzed.At the same time,the changes of temperature,smoke behavior(CO concentration),visibility and other fire smoke characteristic parameters in the mine fire at different altitudes were compared,so as to analyze the influence of altitude on the safety evacuation of underground personnel during mine fires.The results show that:(1)With the increase of altitude,the rate of smoke spread and the influence range of smoke in the mine fire are correspondingly reduced.In the transverse diction,the effective and safe evacuation route should be far away from the fire side in the tunnel;(2)With the increase of altitude,the characteristic parameters of fire smoke also change to some extent,that is the peak temperature and CO concentration decrease,while the visibility gradually increases;(3)Compared with low-altitude areas,when the fire occurs in the mine with relatively high altitude,the safety evacuation time is prolonged and the safety evacuation distance is shortened,which makes the possibility of people’s safety escape is greater.In general,this paper reveals the mechanism of the effect of altitude on the smoke spread of mine fire,which can be used as reference for the prevention and control of mine fire accidents.

Key words: altitude, mine fire, smoke flow, temperature field, CO concentration, numerical simulation

CLC Number: 

  • TD26

Table 1

Physical parameters of cable"

参数名称参数取值
密度/(kg·m-31 380
比热容/(kJ·kg-1·K-11.289
热导率/(W·m-1·K-10.192

Fig.1

Fire model of mine"

Table 2

Size of obstructions in the model(m)"

方向巷道尺寸机电硐室尺寸配电柜尺寸拓展计算域
x4426
y100414
z3.7326

Table 3

Initial environmental parameters at five altitudes"

海拔高度/m温度/℃压力/kPaO2质量分数/(kg·kg-1
020101.3250.2312
1 0002089.8740.2152
2 0001579.4940.1978
3 00010.570.1070.1807
4 000761.6390.1629

Fig.2

Longitudinal distribution of temperature at different altitudes"

Fig.3

Comparison of spatial and temporal evolution of smoke at different altitudes"

Fig.4

Variation curve of CO concentration with time"

Fig.5

Comparison of visibility at different altitudes"

1 杨彪.高寒高海拔地区矿山工程设计要点思考[J].中国钼业,2018,42(3):11-16.
Yang Biao.Key design considerations for the mine engineering in the alpine and high-altitude regions[J].China Molybdenum Industry,2018,42(3):11-16.
2 张念,谭忠盛,毛军,等.高海拔铁路隧道火灾燃烧特性试验研究[J].中国安全科学学报,2011,21(12):52-57.
Zhang Nian,Tan Zhongsheng,Mao Jun,et al.Experimental study on combustion characteristics of fire in high-altitude railway tunnels[J].China Safety Science Journal,2011,21(12):52-57.
3 洪洋,周科平,梁志鹏,等.基于VR技术的非煤矿山火灾应急培训系统的开发[J].黄金科学技术,2019,27(4):629-636.
Hong Yang,Zhou Keping,Liang Zhipeng,et al.Development of non-coal mine fire contingency training system based on VR technology[J].Gold Science and Technology,2019,27(4):629-636.
4 徐乐奕.辽宁连山钼业集团兴利矿业有限公司“12·17”重大火灾事故[J].现代班组,2018(11):29.
Xu Leyi.“12·17” major fire accident in Liaoning Lianshan Molybdenum Group Xingli Mining Co.,Ltd.[J].Modern Group,2018(11):29.
5 Zarzecki M,Quintiere J G,Lyon R E,et al.The effect of pressure and oxygen concentration on the combustion of PMMA[J].Combustion and Flame,2013,160(8):1519-1530.
6 Mcallister S,Fernandez-Pello C,Urban D,et al.The combined effect of pressure and oxygen concentration on piloted ignition of a solid combustible[J].Combustion and Flame,2010,157(9):1753-1759.
7 Li Z H,He Y P,Zhang H,et al.Combustion characteristics of n-heptane and wood crib fires at different altitudes[J].Proceedings of the Combustion Institute,2009,32(2):2481-2488.
8 于春雨,张永明,方俊,等.西藏高原环境下点式感烟火灾探测器的灵敏度[J].中国科学技术大学学报,2007,37(3):290-295.
Yu Chunyu,Zhang Yongming,Fang Jun,et al.Sensitivity of point-type smoke fire detectors in plateau environment of Tibet[J].Journal of University of Science and Tech-nology of China,2007,37(3):290-295.
9 Zhang Y,Ji J,Li J,et al.Effects of altitude and sample width on the characteristics of horizontal flame spread over wood sheets[J].Fire Safety Journal,2012,51:120-125.
10 Joo H I,Gülder Ö L.Soot formation and temperature field structure in co-flow laminar methane-air diffusion flames at pressures from 10 to 60 atm[J].Proceedings of the Combustion Institute,2009,32(1):769-775.
11 Ji J,Guo F Y,Gao Z H,et al.Numerical investigation on the effect of ambient pressure on smoke movement and temperature distribution in tunnel fires[J].Applied Thermal Engineering,2017,118:663-669.
12 Ji J,Guo F Y,Gao Z H,et al.Effects of ambient pressure on transport characteristics of thermal-driven smoke flow in a tunnel[J].International Journal of Thermal Scien-ces,2018,125:210-217.
13 Wang J,Pan Y Y,Lu S,et al.CO concentration decay profile and ceiling jet entrainment in aircraft cargo compartment fires at reduced pressures[J].Applied Thermal En-gineering,2017,110(5):772-778.
14 Yan Z G,Guo Q H,Zhu H H.Full-scale experiments on fire characteristics of road tunnel at high altitude[J].Tunnelling and Underground Space Technology,2017,66:134-146.
15 张念,谭忠盛.高海拔特长铁路隧道火灾烟气分布特性数值模拟研究[J].中国安全科学学报,2013,23(6):52-57.
Zhang Nian,Tan Zhongsheng.Numerical simulation study on smoke distribution of fire in high-altitude super-long railway tunnels[J].China Safety Science Journal,2013,23(6):52-57.
16 袁建平,方正,黄海峰,等.水平隧道火灾通风纵向临界风速模型[J].土木建筑与环境工程,2009,31(6):66-70.
Yuan Jianping,Fang Zheng,Huang Haifeng,et al.Model of critical velocity for fire ventilation in horizontal tunnels[J].Journal of Civil and Environmental Engineering,2009,31(6):66-70.
17 McGrattan K B,Baum H R,Rehm R G,et al.Fire Dynamics Simulator (Version 2),Technical Reference Guide[M].Maryland:National Institute of Standards and Technology,2001.
18 He Y P,Jamieson C,Jeary A,et al.Effect of computation domain on simulation of small compartment fires[J].Fire Safety Science,2017,9(9):1365-1376.
19 苟红松,李永生,罗占夫.高海拔地区隧道施工通风风量计算及风机选型研究[J].隧道建设,2012,32(1):53-56.
Gou Hongsong,Li Yongsheng,Luo Zhanfu.Study on air volume calculation and fan selection for tunneling ventilation in plateau area[J].Tunnel Construction,2012,32(1):53-56.
20 何磊.高原矿山独头巷道增氧通风数值模拟研究[J].现代矿业,2011,27(2):37-40.
He Lei.Study on oxygen enhancing ventilation in blind drift at plateau mine by numerical simulation[J].Modern Mining,2011,27(2):37-40.
21 王光福.高原寒区对工程机械性能的技术研究与应用[J].甘肃科技,2009,25(10):44-45,71.
Wang Guangfu.Technical research and application of engineering machinery performance in plateau cold region[J].Gansu Science and Technology,2009,25(10):44-45,71.
22 于润沧.采矿工程师手册(下)[M].北京:冶金工业出版社,2009:1879-1890.
Yu Runcang.Mining Engineer’s Handbook(Volume Ⅱ)[M].Beijing:Metallurgical Industry Press,2009:1879-1890.
23 Tan X J,Chen W Z,Yang D S,et al.Study on the influence of airflow on the temperature of the surrounding rock in a cold region tunnel and its application to insulation layer design[J].Applied Thermal Engineering,2014,67(1/2):320-334.
24 Ji J,Wan H X,Li Y F,et al.Influence of relative location of two openings on fire and smoke behaviors in stairwell with a compartment[J].International Journal of Thermal Sciences,2015,89:23-33.
25 王晓波.长大隧道火灾安全疏散研究[J].地下空间与工程学报,2016,12(5):1364-1370.
Wang Xiaobo.Research on safe evacuation in large and long tunnel during fire[J].Chinese Journal of Underground Space and Engineering,2016,12(5):1364-1370.
[1] Qinli ZHANG,Chaoyu JIANG,Xiang GAO,Bin LIU. Study on Optimization of Structural Parameters of Hexagonal Mining Method with Large Cross-section [J]. Gold Science and Technology, 2020, 28(1): 42-50.
[2] Long TIAN,Zhiyong ZHOU,Jianhong CHEN. Numerical Simulation of Temperature Distribution in Mining Area of High Temperature Mine with Auxiliary Ventilation [J]. Gold Science and Technology, 2020, 28(1): 61-69.
[3] Yuan GAO,Qingfa CHEN,Tenglong JIANG. Research on Three-Dimensional Numerical Model Construction Method and Cemented Filling Treatment of Complex Cavities in Daxin Manganese Mine [J]. Gold Science and Technology, 2019, 27(6): 851-861.
[4] Jun TIAN, Jianpo LIU, Yong YANG, Changyin ZHANG. Study on the Failure Law of Backfill Induced by Blasting Disturbance During Cut and Fill Mining Process [J]. Gold Science and Technology, 2019, 27(5): 687-695.
[5] Enxiang SONG, Qiang LI, Jing ZHANG, Kang PENG. Research and Application of Artificial False Bottom in Mining of Orebody in Alteration Zone [J]. Gold Science and Technology, 2019, 27(5): 722-730.
[6] Shijiao YANG,Zhihui WANG. Numerical Simulation on Stability of Shallow-buried Goaf Group with Overlying Highway [J]. Gold Science and Technology, 2019, 27(4): 505-512.
[7] Zilong LIU,Hongying YANG,Linlin TONG,Guobao CHEN. Experimental Study on Flotation Optimization of Copper Oxide Ore in High Altitude Environment [J]. Gold Science and Technology, 2019, 27(4): 589-597.
[8] Yang HONG,Keping ZHOU,Zhipeng LIANG,Yemin HU. Development of Non-coal Mine Fire Contingency Training System Based on VR Technology [J]. Gold Science and Technology, 2019, 27(4): 629-636.
[9] Rui LIANG,Ruili YU,Wenhai ZHOU,Xiaobin HUANG,Jianyong WANG,Zhengyu XIONG. Application of Air Interval Charge Blasting Model in Mining Room [J]. Gold Science and Technology, 2019, 27(3): 358-367.
[10] Shikang QIN,Qingfa CHEN,Tingchang YIN. Connotation Differences and Research Progress of the Freeze-Thaw Damages of Rock and Rock Mass [J]. Gold Science and Technology, 2019, 27(3): 385-397.
[11] Feng LIU,Zhaokun WANG,Fengshan MA,Bo WANG,Jianbo WANG,Chunlei DONG. Current Situation and Prospect of Destressing Techniques in Deep Mine [J]. Gold Science and Technology, 2019, 27(3): 425-432.
[12] Chuanfeng FANG,Jinmiao WANG,Shanbing LI,Mingtao JIA. Numerical Simulation Research of Natural Caving Method Based on PFC2D-DFN [J]. Gold Science and Technology, 2019, 27(2): 189-198.
[13] Chun WANG,Cheng WANG,Zuqiang XIONG,Luping CHENG,Huaibin WANG. Deformation Characteristics of the Surrounding Rock in Deep Mining Roadway Under Dynamic Disturbance [J]. Gold Science and Technology, 2019, 27(2): 232-240.
[14] Nao LV,Haibo WANG. Numerical Simulation of Collapse Disaster Before and After Weakening of Thick and Hard Roof [J]. Gold Science and Technology, 2019, 27(2): 257-264.
[15] Conglu WANG,Tong LI. Analysis of Influence of Deep Mine’s Linear Heat Source on Effective Ventilation Based on Ventsim Software [J]. Gold Science and Technology, 2019, 27(2): 271-277.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!

©2018 Gold Science and Technology 

Telephone:0931-8277791 

E-mail: hjkx@lzb.ac.cn Postcode:730000 

Powered by Beijing Magtech Co. Ltd

陇ICP备17001318号-1