矿井火灾灾变时期风流控制技术研究
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摘要
矿井火灾是煤矿五大灾害之一,具有突发性、发展迅猛、灭火和救护困难大等特点。风流受到火灾动力的影响,极易发生紊乱,甚至造成整个矿井通风状况的改变。火灾发生后有毒有害气体的传播会对生产区域造成污染,极大的威胁到矿井工人的生命健康安全。通过矿井火灾风流控制系统的建立,利用自动风门等实现风流的远程控制,当发生火灾时使火灾烟气按照预定的控风方案通过专门的回风巷道排出,有效的阻止了火灾烟气影响范围的扩大化,使火灾的影响范围限定在损失最小的范围之内,并为人员的逃生避灾提供指导,对降低人员的伤亡率方面有着重大的现实意义。
本文通过基于CFD计算流体力学的数值模拟方法对矿井火灾时期的风流流场、温度场、污染物组分分布场三个方面进行研究。在不影响火灾模拟的基础上,通过充分简化,运用Gambit软件对孔庄煤矿2号和5号胶带巷建立物理模型。在Fluent中,采用RNGκ-ε两方程湍流模型、P1辐射模型、能量方程、组分输运模型及Mixture多相流模型进行解算,分别得到了CO和烟气浓度、温度、风流速度在巷道纵向上的分布情况以及距火源点不同距离的横截面上的CO浓度的分布情况,为确定传感器在巷道中布置的位置提供了依据。通过非稳态模拟,建立了CO前锋扩散距离与时间的数学模型。
在数值模拟的基础上,建立了孔庄煤矿胶带巷火灾时期风流控制系统,并对自动风门和传感器进行了阐述。通过井下工作人员的逃生实验,建立了孔庄煤矿人行巷道中人员的逃生速度模型,结合CO的扩散模型,讨论了人行巷道中避难救生舱的安装位置。最后,对2号和5号胶带巷风流控制系统中风门、传感器和警报器的安设位置、安设数量进行了详细说明。
Fire is one of five major disasters in coal mine. It has many special characters such as breaking out suddenly, fire developing quickly, putting out fire and rescuing hardly. Under the influence of fire power, air is easily to be disturbed, even the air in the whole ventilation system. Poisonous gases produced by fire will spread and pollute production areas. It is a great threat to safety and health of mine workers. Through the airflow control system is established, automatic air doors are used to realize airflow remote controlling. When breaking out of fire, smoke is exhaust by special return roadway. It is effectively limited smoke influence area and the loss. It provides escaping guidance to personnel. It has great practical significance to reduce the staff casualty rate.
Based on CFD technology, this thesis stimulates ventilation flow field, temperature field and pollutants distribution field during fire. By simplifying enough without impact on the fire simulation, Gambit is used to establish physical models of No.2 and No.5 belt roadway in Kongzhuang Coal Mine. By using RNG k-εturbulence model, P1 radiation model, energy equation, and Mixture Multiphase flow model in Fluent, the concentration of CO and smoke, temperature and air flow speed in the length wise direction and CO distribution in the cross section of different distances away from ignition sources are obtained. The results provide basis for sensors arrangement position in the tunnel. Through non-steady simulation, CO diffusion mathematical model is established.
Based on the numerical simulation, the ventilation automatic control system during fire in the belt roadway of Kongzhuang Coal Mine is established. Automatic door and sensors are introduced. By underground escape experiments, personnel escape velocity model in pathway of Kongzhuang Coal Mine is established. Combined with CO diffusion models, the installation site of rescue capsules is studied. Finally, the install location and quantity details of air doors, sensors and alarms in No.2 and No.5 belt roadway are introduced.
本文通过基于CFD计算流体力学的数值模拟方法对矿井火灾时期的风流流场、温度场、污染物组分分布场三个方面进行研究。在不影响火灾模拟的基础上,通过充分简化,运用Gambit软件对孔庄煤矿2号和5号胶带巷建立物理模型。在Fluent中,采用RNGκ-ε两方程湍流模型、P1辐射模型、能量方程、组分输运模型及Mixture多相流模型进行解算,分别得到了CO和烟气浓度、温度、风流速度在巷道纵向上的分布情况以及距火源点不同距离的横截面上的CO浓度的分布情况,为确定传感器在巷道中布置的位置提供了依据。通过非稳态模拟,建立了CO前锋扩散距离与时间的数学模型。
在数值模拟的基础上,建立了孔庄煤矿胶带巷火灾时期风流控制系统,并对自动风门和传感器进行了阐述。通过井下工作人员的逃生实验,建立了孔庄煤矿人行巷道中人员的逃生速度模型,结合CO的扩散模型,讨论了人行巷道中避难救生舱的安装位置。最后,对2号和5号胶带巷风流控制系统中风门、传感器和警报器的安设位置、安设数量进行了详细说明。
Fire is one of five major disasters in coal mine. It has many special characters such as breaking out suddenly, fire developing quickly, putting out fire and rescuing hardly. Under the influence of fire power, air is easily to be disturbed, even the air in the whole ventilation system. Poisonous gases produced by fire will spread and pollute production areas. It is a great threat to safety and health of mine workers. Through the airflow control system is established, automatic air doors are used to realize airflow remote controlling. When breaking out of fire, smoke is exhaust by special return roadway. It is effectively limited smoke influence area and the loss. It provides escaping guidance to personnel. It has great practical significance to reduce the staff casualty rate.
Based on CFD technology, this thesis stimulates ventilation flow field, temperature field and pollutants distribution field during fire. By simplifying enough without impact on the fire simulation, Gambit is used to establish physical models of No.2 and No.5 belt roadway in Kongzhuang Coal Mine. By using RNG k-εturbulence model, P1 radiation model, energy equation, and Mixture Multiphase flow model in Fluent, the concentration of CO and smoke, temperature and air flow speed in the length wise direction and CO distribution in the cross section of different distances away from ignition sources are obtained. The results provide basis for sensors arrangement position in the tunnel. Through non-steady simulation, CO diffusion mathematical model is established.
Based on the numerical simulation, the ventilation automatic control system during fire in the belt roadway of Kongzhuang Coal Mine is established. Automatic door and sensors are introduced. By underground escape experiments, personnel escape velocity model in pathway of Kongzhuang Coal Mine is established. Combined with CO diffusion models, the installation site of rescue capsules is studied. Finally, the install location and quantity details of air doors, sensors and alarms in No.2 and No.5 belt roadway are introduced.
引文
[1]王洪德.基于网络流理论的火灾时期风流控制系统研究[J].大连铁道学院学报,2005.9,26(3):59-63.
[2]王显政,杨富,朱凤山,胡省三等.煤矿安全新技术[M].北京:煤炭工业出版社,2002.
[3]王树玉.煤矿五大灾害事故分析和防治对策[M].徐州:中国矿业大学出版社,2006.
[4]周福宝.井巷网络火灾特性及其应用研究[D].徐州:中国矿业大学,2003.
[5]王耀青,杨娟.矿井通风网络风流控制的实用算法[J].武汉科技大学学报(自然科学版),2000.12,23(4):331-334.
[6]张国枢.通风安全学[M].徐州:中国矿业大学出版社,2004.4.
[7]Swaminathan S, Smidts C. The Event Sequence Diagram Framework for Dynamic Probabilistic Risk Assessmen[J]. Reliability Engineering & System Safety,1999,63(1): 73-90.
[8]苏春.基于GSPN模型的系统动态可靠性仿真研究[J].中国机械工程,2008,19(1).
[9]苏春,许映秋.复杂机电产品动态可靠性建模理论与方法研究[J].中国制造业信息化,2006,35(9).
[10]苏春,王圣金,许映秋.复杂系统动态可靠性建模及其数值仿真研究[J].机械设计,2007,24(2).
[11]贾进章,刘剑.矿井火灾时期通风系统可靠性[M].煤炭工业出版社,2005:10-48.
[12]张仿彦.煤矿安全监控系统在矿井胶带火灾防治中的应用[J].煤矿开采,2002(9):64-66.
[13]程居山等.矿山机械[M].徐州:中国矿业大学出版社,1997.
[14]煤炭工业部安全司.矿井安全监控原理与应用[M].徐州:中国矿业大学出版社,1996.
[15]肖全兴.矿井通风安全管理预警提示系统的研制[J].徐煤科技,1996(1):24-26.
[16]王卫军.煤矿火灾预测预报的研究[J].矿业安全与环保,2004(6):30-33.
[17]刘伟,周心权,谭文辉等.用分区法优化布置火源探测传感器的研究用分区法优化布置火源探测传感器的研究[J].煤炭工程师,1998(4).
[18]肖国清,温丽敏,张培红.陈宝智.煤矿火灾后果动态模拟研究[J].煤炭学报, 2001(10):512-515.
[19]张兴凯.矿井火灾燃烧过程及其风流流动状态的研究[D].沈阳:东北大学,1993.
[20]J.loneketal. Rough Set Reduction of Attributes and Domains for Neural Networks[J], Computational Intelligence,1995(11):339-347.
[21]张兴凯,王振财,姚尔义.矿井火灾时期风流非稳定状态的通风原理[J].煤矿安全,1993(6).
[22]Newman J S. Experimental evaluation of fire-induced stratification[J]. Combustion & Flame,1983(57):347-355.
[23]Wu Y, Bakar M Z A. Control of Smoke flow in tunnel fires using longitudinal ventilation system-a study of the critical velocity[J]. Fire Safety Journal,2000(35):363-390.
[24]周力行.湍流气粒两相流动和燃烧的理论与数值模拟[M].北京:科学出版社,1994.
[25]周奠邦.煤矿胶带输送机的火灾防治[J].化工劳动保护,1994(3):11-12.
[26]Atkinson G T, Wu Y. Smoke control in sloping tunnels[J]. Fire Safety Journal,1996(27): 335-341.
[27]韩莹,赵国材,李琨.煤矿井下带式输送机智能型火灾报警系统[J].煤矿机电,1997(5):84-86.
[28]Kunsch J P. Simple model for control of fire gases in a ventilated tunnel[J]. Fire Safety Journal,2002(37):67-81.
[29]Jurij Modic. Fire simulation in road tunnels[J]. Tunnelling and Undergroud Space Technology,2003(18):525.
[30]Steven J. Luzik. Howto limit fire and explosion hazards with oil-flooded rotary screw copressors[J]. Mining Engineering,1987(9):880.
[31]蒋曙光等.远控风门胶带巷防火系统的研究[J].矿业安全与环保,1999(1):14-16.
[32]孙增圻.智能控制理论与技术[M].北京:清华大学出版社,1997.
[33]王德明.矿井火灾救灾决策支持系统的研究[D].徐州:中国矿业大学,1993.
[34]周心权,吴兵.矿井火灾救灾理论与实践[M].北京:煤炭工业出版社,1996.
[35]朱江.计算流体动力学在隧道安全中的应用[J].武警学院年报,2009.2,25(2):40-43.
[36]闫小康,王利军.fluent软件在通风工程中的应用[J].煤矿机械.2005(11),153-155.
[37]廖曙江.大空间建筑内活动火灾荷载火灾发展及蔓延的特性研究[D].重庆:重庆大 学,2002.
[38]何佳,徐志胜,倪天晓等.公路隧道火灾危险性分析及其防护[J].四川建筑,2007(6):207-209.
[39]于丽.终南山特长公路隧道火灾模式下通风设计和控制技术研究[D].成都:西南交通大学,2009.
[40]耿继元.矿井火灾时期烟流动态过程的数值模拟[D].辽宁阜新:辽宁阜新辽宁工程技术大学,2007.
[41]王德明,程远平,周福宝,季经纬.矿井火灾火源燃烧特性的实验研究[J].中国矿业大学学报,2002.1,31(2):30-33.
[42]张国枢,谭允祯等.通风安全学[M].中国矿业大学出版社,2000.
[43]王志刚.胶带输送机火灾发展规律[J].煤矿安全,1998.4(4):45-47.
[44]程卫民,张圣柱,刘祥来,任宝宏,祝琳.矿井胶带巷火灾预警与风流控制技术研究[J].矿业安全与环保,2009.10,36(5):18-24.
[45]傅祝满,范维澄.建筑火灾区域模拟燃烧及组分浓度的计算[J].燃烧科学与技术,1997,3(2):163-168.
[46]朱志强.W型火焰燃烧室燃烧过程及污染物生成的数值模拟[D].北京:华北电力大学,2000.
[47]王福军.计算流体动力学分析——CFD软件原理与应用[M].清华大学出版社,2004.
[48]杨洁.多房间多层建筑火灾烟气流动的数值模拟及排烟设计[D].哈尔滨工程大学,2004.
[49]王春.地铁车站通风与火灾三维数值模拟研究[D].成都:西南交通大学,2005.
[50]黄鹏.地铁隧道及车站内流动特性的数值模拟研究[D].北京:北京交通大学,2007.
[51]纪慧琢.高海拔特长隧道火灾烟气流动特性的数值模拟分析[D].北京:北京交通大学,2010.
[52]Qingyan Chen. Comparison of dieffernt κ-ε models for indoor airflow computation Numerical Heat Transfer(Part B),1995; 28:353-369.
[53]赵相相.地铁隧道火灾烟气流动与控制规律研究[D].广东广州:广州大学,2006.
[54]冯炼,刘应清.地铁火灾烟气控制的数值模拟[J].地下空间,2002.3,22(1):61-64.
[55]那艳玲.地铁车站通风与火灾的CFD仿真模拟与实验研究[D].天津:天津大学. 2003.
[56]江帆,黄鹏. FLUENT高级应用与实例分析[M].清华大学出版社,2008.
[57]胡隆华.隧道火灾烟气蔓延的热物理特性研究[D].合肥:中国科学技术大学,2006.
[58]L. H. Hu, Y. Z. Li, R. Huo, L.Yi, C.L.Shi and W. K. Chow, Experimental Studies on the Rise Time of Buoyant Fire Plume Fronts Induced by Pool Fires, Journal of Fire Sciences,2004, Vol,22, No.1, P.69-86.
[59]L. H. Hu, R. Huo, Y. Z. Li and H. B. Wang, Experimental Study on the Burning Characteristics of wood Cribs in a Confined Space, Journal of Fire Sciences,2004, Vol.22, No. 6, P.473-489.
[60]L. H. Hu, W. K. Chow, Y. Z. Li, R. Huo, Measurement of smoke layer interface height for hot smoke tests in tunnels,13th International Heat Transfer conference, Sydney, NSW, Australia,13-18 August 2006.
[61]杨晖.地铁空间内空气与火灾烟气流动特性的数值研究[D].北京:北京交通大学,2010.6.
[62]张圣柱.矿井胶带巷火灾预警与风流控制技术研究[D].青岛:山东科技大学,2009.
[63]彭磊,张健,张鹏.通风控制下建筑物通道内火灾烟气运动的数值模拟[J].科学技术及工程,2006.11,6(21):3414-3417.
[64]李北海.中庭式大空间建筑火灾探测与排烟智能控制系统研究[D].重庆:重庆大学,2002.
[65]于勇.FLUENT入门与进阶教程(第1版)[M].北京理工大学出版社,2008.
[66]韩占忠,王敬,兰小平.FLUENT流体工程仿真计算实例与应用[M].北京理工大学出版社,2008.
[67]张建文,杨振亚,张政.流体流动与传热过程的数值模拟基础与应用[M].化学工业出版社,2009.
[68]王瑞金,张凯,王刚.Fluent技术基础与应用实例[M].清华大学出版社,2007.
[69]张凯,王瑞金,王刚Fluent技术基础与应用实例(第2版)[M].清华大学出版社,2010.
[70]王东.基于温度和CO影响下公路隧道火灾人员逃生研究[D].西安:长安大学,2010.
[71]PIARC COMMITTEE ON ROAD TUNNELS. Report to the ⅩⅧth World Road Congress, Marrakesh(Morocco), September 1991(ref.19.05. B)/COMITE AIPCR DES TUNNELS ROUTIES, rapport au XIXE Congres mondial dela Route, Bruxelles (Belgique), September 1987(ref.18.05. F).
[72]Allen R. Tunnel operations. Tunnel Management International [J]. Vol.6, No.4.
[73]STUDIENG ELLSCHAFT STAHLANWENDUNG E. V:" EUREKA-Project EU 499 Firetun:Fire in transport tunnels; Report on full-sale tests", Verlag and Vertriebsgesellsvhaft, Diuisseldorf, November 1995.
[74]J. A. Gonzalel and N. H. Danziger. Tunnel ventilation design for fire safety,6th-International symposium on the aerodynamics and ventilation of vehicle tunnels, England, Sept 1988, P575-P592.
[75]张玉春,何川.基于人员疏散随机性的公路隧道火灾风险分析[J].土木工程学报,2010.7,43(7):113-118.
[76]何新建,蒋曙光,吴征艳,刘文,孟燕.龙东煤矿西翼运输巷远控气动火灾应急救援系统[J].煤炭科学技术,2008.8,36(8):53-54.
[77]张睿,程卫民,上官昌培,潘刚,胶带巷火灾应急救援系统的应用与实践[J].煤矿安全,2010.7,43(7):36-39.
[78]赵忠杰.公路隧道火灾探测方法研究[D].西安:长安大学,2007.
[79]徐景德,周心权.煤矿胶带输送机火灾早期报警技术的研究[J].煤矿安全,1999.8,(8):31-33.
[80]杨庆.离子感烟探测报警系统在火灾烟气流动特性研究中的初步应用[J].消防技术与产品信息,2005,(8):82-83.
[81]陈章其,吴冲若.火灾传感器[J].电子器件,1995.3,18(1):55-58.
[82]朱红青,邬燕云,周心权.煤矿井下输送带火灾传感器报警限和间距设计研究及应用[J].煤炭科学技术,2001.11,29(11):42-44.
[83]李俊双等.采煤区(队)长[M].北京:煤炭工业出版社,2003.8,245.
[84]包志军,马培荪,仝建刚,王春雨.人行走速度规律的实验研究[J].实验室研究与探索,2000(6):39-42.
[2]王显政,杨富,朱凤山,胡省三等.煤矿安全新技术[M].北京:煤炭工业出版社,2002.
[3]王树玉.煤矿五大灾害事故分析和防治对策[M].徐州:中国矿业大学出版社,2006.
[4]周福宝.井巷网络火灾特性及其应用研究[D].徐州:中国矿业大学,2003.
[5]王耀青,杨娟.矿井通风网络风流控制的实用算法[J].武汉科技大学学报(自然科学版),2000.12,23(4):331-334.
[6]张国枢.通风安全学[M].徐州:中国矿业大学出版社,2004.4.
[7]Swaminathan S, Smidts C. The Event Sequence Diagram Framework for Dynamic Probabilistic Risk Assessmen[J]. Reliability Engineering & System Safety,1999,63(1): 73-90.
[8]苏春.基于GSPN模型的系统动态可靠性仿真研究[J].中国机械工程,2008,19(1).
[9]苏春,许映秋.复杂机电产品动态可靠性建模理论与方法研究[J].中国制造业信息化,2006,35(9).
[10]苏春,王圣金,许映秋.复杂系统动态可靠性建模及其数值仿真研究[J].机械设计,2007,24(2).
[11]贾进章,刘剑.矿井火灾时期通风系统可靠性[M].煤炭工业出版社,2005:10-48.
[12]张仿彦.煤矿安全监控系统在矿井胶带火灾防治中的应用[J].煤矿开采,2002(9):64-66.
[13]程居山等.矿山机械[M].徐州:中国矿业大学出版社,1997.
[14]煤炭工业部安全司.矿井安全监控原理与应用[M].徐州:中国矿业大学出版社,1996.
[15]肖全兴.矿井通风安全管理预警提示系统的研制[J].徐煤科技,1996(1):24-26.
[16]王卫军.煤矿火灾预测预报的研究[J].矿业安全与环保,2004(6):30-33.
[17]刘伟,周心权,谭文辉等.用分区法优化布置火源探测传感器的研究用分区法优化布置火源探测传感器的研究[J].煤炭工程师,1998(4).
[18]肖国清,温丽敏,张培红.陈宝智.煤矿火灾后果动态模拟研究[J].煤炭学报, 2001(10):512-515.
[19]张兴凯.矿井火灾燃烧过程及其风流流动状态的研究[D].沈阳:东北大学,1993.
[20]J.loneketal. Rough Set Reduction of Attributes and Domains for Neural Networks[J], Computational Intelligence,1995(11):339-347.
[21]张兴凯,王振财,姚尔义.矿井火灾时期风流非稳定状态的通风原理[J].煤矿安全,1993(6).
[22]Newman J S. Experimental evaluation of fire-induced stratification[J]. Combustion & Flame,1983(57):347-355.
[23]Wu Y, Bakar M Z A. Control of Smoke flow in tunnel fires using longitudinal ventilation system-a study of the critical velocity[J]. Fire Safety Journal,2000(35):363-390.
[24]周力行.湍流气粒两相流动和燃烧的理论与数值模拟[M].北京:科学出版社,1994.
[25]周奠邦.煤矿胶带输送机的火灾防治[J].化工劳动保护,1994(3):11-12.
[26]Atkinson G T, Wu Y. Smoke control in sloping tunnels[J]. Fire Safety Journal,1996(27): 335-341.
[27]韩莹,赵国材,李琨.煤矿井下带式输送机智能型火灾报警系统[J].煤矿机电,1997(5):84-86.
[28]Kunsch J P. Simple model for control of fire gases in a ventilated tunnel[J]. Fire Safety Journal,2002(37):67-81.
[29]Jurij Modic. Fire simulation in road tunnels[J]. Tunnelling and Undergroud Space Technology,2003(18):525.
[30]Steven J. Luzik. Howto limit fire and explosion hazards with oil-flooded rotary screw copressors[J]. Mining Engineering,1987(9):880.
[31]蒋曙光等.远控风门胶带巷防火系统的研究[J].矿业安全与环保,1999(1):14-16.
[32]孙增圻.智能控制理论与技术[M].北京:清华大学出版社,1997.
[33]王德明.矿井火灾救灾决策支持系统的研究[D].徐州:中国矿业大学,1993.
[34]周心权,吴兵.矿井火灾救灾理论与实践[M].北京:煤炭工业出版社,1996.
[35]朱江.计算流体动力学在隧道安全中的应用[J].武警学院年报,2009.2,25(2):40-43.
[36]闫小康,王利军.fluent软件在通风工程中的应用[J].煤矿机械.2005(11),153-155.
[37]廖曙江.大空间建筑内活动火灾荷载火灾发展及蔓延的特性研究[D].重庆:重庆大 学,2002.
[38]何佳,徐志胜,倪天晓等.公路隧道火灾危险性分析及其防护[J].四川建筑,2007(6):207-209.
[39]于丽.终南山特长公路隧道火灾模式下通风设计和控制技术研究[D].成都:西南交通大学,2009.
[40]耿继元.矿井火灾时期烟流动态过程的数值模拟[D].辽宁阜新:辽宁阜新辽宁工程技术大学,2007.
[41]王德明,程远平,周福宝,季经纬.矿井火灾火源燃烧特性的实验研究[J].中国矿业大学学报,2002.1,31(2):30-33.
[42]张国枢,谭允祯等.通风安全学[M].中国矿业大学出版社,2000.
[43]王志刚.胶带输送机火灾发展规律[J].煤矿安全,1998.4(4):45-47.
[44]程卫民,张圣柱,刘祥来,任宝宏,祝琳.矿井胶带巷火灾预警与风流控制技术研究[J].矿业安全与环保,2009.10,36(5):18-24.
[45]傅祝满,范维澄.建筑火灾区域模拟燃烧及组分浓度的计算[J].燃烧科学与技术,1997,3(2):163-168.
[46]朱志强.W型火焰燃烧室燃烧过程及污染物生成的数值模拟[D].北京:华北电力大学,2000.
[47]王福军.计算流体动力学分析——CFD软件原理与应用[M].清华大学出版社,2004.
[48]杨洁.多房间多层建筑火灾烟气流动的数值模拟及排烟设计[D].哈尔滨工程大学,2004.
[49]王春.地铁车站通风与火灾三维数值模拟研究[D].成都:西南交通大学,2005.
[50]黄鹏.地铁隧道及车站内流动特性的数值模拟研究[D].北京:北京交通大学,2007.
[51]纪慧琢.高海拔特长隧道火灾烟气流动特性的数值模拟分析[D].北京:北京交通大学,2010.
[52]Qingyan Chen. Comparison of dieffernt κ-ε models for indoor airflow computation Numerical Heat Transfer(Part B),1995; 28:353-369.
[53]赵相相.地铁隧道火灾烟气流动与控制规律研究[D].广东广州:广州大学,2006.
[54]冯炼,刘应清.地铁火灾烟气控制的数值模拟[J].地下空间,2002.3,22(1):61-64.
[55]那艳玲.地铁车站通风与火灾的CFD仿真模拟与实验研究[D].天津:天津大学. 2003.
[56]江帆,黄鹏. FLUENT高级应用与实例分析[M].清华大学出版社,2008.
[57]胡隆华.隧道火灾烟气蔓延的热物理特性研究[D].合肥:中国科学技术大学,2006.
[58]L. H. Hu, Y. Z. Li, R. Huo, L.Yi, C.L.Shi and W. K. Chow, Experimental Studies on the Rise Time of Buoyant Fire Plume Fronts Induced by Pool Fires, Journal of Fire Sciences,2004, Vol,22, No.1, P.69-86.
[59]L. H. Hu, R. Huo, Y. Z. Li and H. B. Wang, Experimental Study on the Burning Characteristics of wood Cribs in a Confined Space, Journal of Fire Sciences,2004, Vol.22, No. 6, P.473-489.
[60]L. H. Hu, W. K. Chow, Y. Z. Li, R. Huo, Measurement of smoke layer interface height for hot smoke tests in tunnels,13th International Heat Transfer conference, Sydney, NSW, Australia,13-18 August 2006.
[61]杨晖.地铁空间内空气与火灾烟气流动特性的数值研究[D].北京:北京交通大学,2010.6.
[62]张圣柱.矿井胶带巷火灾预警与风流控制技术研究[D].青岛:山东科技大学,2009.
[63]彭磊,张健,张鹏.通风控制下建筑物通道内火灾烟气运动的数值模拟[J].科学技术及工程,2006.11,6(21):3414-3417.
[64]李北海.中庭式大空间建筑火灾探测与排烟智能控制系统研究[D].重庆:重庆大学,2002.
[65]于勇.FLUENT入门与进阶教程(第1版)[M].北京理工大学出版社,2008.
[66]韩占忠,王敬,兰小平.FLUENT流体工程仿真计算实例与应用[M].北京理工大学出版社,2008.
[67]张建文,杨振亚,张政.流体流动与传热过程的数值模拟基础与应用[M].化学工业出版社,2009.
[68]王瑞金,张凯,王刚.Fluent技术基础与应用实例[M].清华大学出版社,2007.
[69]张凯,王瑞金,王刚Fluent技术基础与应用实例(第2版)[M].清华大学出版社,2010.
[70]王东.基于温度和CO影响下公路隧道火灾人员逃生研究[D].西安:长安大学,2010.
[71]PIARC COMMITTEE ON ROAD TUNNELS. Report to the ⅩⅧth World Road Congress, Marrakesh(Morocco), September 1991(ref.19.05. B)/COMITE AIPCR DES TUNNELS ROUTIES, rapport au XIXE Congres mondial dela Route, Bruxelles (Belgique), September 1987(ref.18.05. F).
[72]Allen R. Tunnel operations. Tunnel Management International [J]. Vol.6, No.4.
[73]STUDIENG ELLSCHAFT STAHLANWENDUNG E. V:" EUREKA-Project EU 499 Firetun:Fire in transport tunnels; Report on full-sale tests", Verlag and Vertriebsgesellsvhaft, Diuisseldorf, November 1995.
[74]J. A. Gonzalel and N. H. Danziger. Tunnel ventilation design for fire safety,6th-International symposium on the aerodynamics and ventilation of vehicle tunnels, England, Sept 1988, P575-P592.
[75]张玉春,何川.基于人员疏散随机性的公路隧道火灾风险分析[J].土木工程学报,2010.7,43(7):113-118.
[76]何新建,蒋曙光,吴征艳,刘文,孟燕.龙东煤矿西翼运输巷远控气动火灾应急救援系统[J].煤炭科学技术,2008.8,36(8):53-54.
[77]张睿,程卫民,上官昌培,潘刚,胶带巷火灾应急救援系统的应用与实践[J].煤矿安全,2010.7,43(7):36-39.
[78]赵忠杰.公路隧道火灾探测方法研究[D].西安:长安大学,2007.
[79]徐景德,周心权.煤矿胶带输送机火灾早期报警技术的研究[J].煤矿安全,1999.8,(8):31-33.
[80]杨庆.离子感烟探测报警系统在火灾烟气流动特性研究中的初步应用[J].消防技术与产品信息,2005,(8):82-83.
[81]陈章其,吴冲若.火灾传感器[J].电子器件,1995.3,18(1):55-58.
[82]朱红青,邬燕云,周心权.煤矿井下输送带火灾传感器报警限和间距设计研究及应用[J].煤炭科学技术,2001.11,29(11):42-44.
[83]李俊双等.采煤区(队)长[M].北京:煤炭工业出版社,2003.8,245.
[84]包志军,马培荪,仝建刚,王春雨.人行走速度规律的实验研究[J].实验室研究与探索,2000(6):39-42.