地铁车站通风与火灾的CFD仿真模拟与实验研究
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摘要
随着城市地铁的大规模建设,地铁车站环境和地铁火灾成为研究人员越来越关心的课题。建立良好的地铁环境的目的不仅仅在于提供一个安全、舒适的乘车环境,而且对于节省能源,降低建设费用与运行费用都有实际的意义。
正确的选择模型方程,合理的划分计算网格,对CFD数值模拟的结果有着重要的影响。本课题比较了现场测试结果与计算结果,分析了湍流模型的选择对整个地铁系统温度场、气流场的计算结果的影响,得到了双方程计算准确性优于零方程的结论。计算网格是由计算域内不连续的部分组成的,在每一个成分中,求解控制室内流动和热传递的方程。计算网格的划分对计算结果、计算时间以及计算收敛都将会有很大的影响。求解的时间和精确度直接取决于网格的质量,好的网格划分将会节省计算时间以及提高计算的准确性,本文对不同网格的计算结果与实测值进行了分析比较,得到了较为优化的网格划分。
现场测试的目的是获取计算模拟所需要的边界条件(温度、速度等),验证湍流模型用于模拟站台通风的可行性。本文利用CFD方法模拟一个岛式站台冬季工况的温度场和气流场,在实验条件允许的情况下测得一些实验数据,将模拟结果与实验结果进行对比验证,证明了地铁车站计算机模拟的可靠性,并从中采集并确定了某些边界条件。并对列车进站过程进行了仿真模拟。
不同城市的气候条件、室外温湿度差异很大,因此选用何种环控方案,应根据客观条件、工程造价、运行效果等方面综合分析。本文以南方的深圳,北方的天津和东北的沈阳为例,对这三个不同地区的夏季空调工况的气流场和温度场进行了模拟计算。对天津岛式和侧式车站的不同气流组织进行了方案优化,对沈阳空调通风方案进行了比较,提出了适合于天津和沈阳地铁车站的通风方式。通过CFD数值模拟对屏蔽门的经济性、轨底排风与顶部局部排风的作用进行了分析。
本文针对地铁火灾发生的各种状况如有屏蔽门和无屏蔽门的站台、站厅及列车火灾的各种情况的温度场和气流场进行了CFD仿真模拟,并分析了火灾发生的位置及排烟量对地铁车站气流场和温度场的影响。盐水实验模拟研究方法属于小尺寸模拟试验。本文针对站台及列车着火两种情况进行了盐水实验,实验结果与模拟结果进行了比较。
利用实体燃烧实验与模拟的结果分析比较,对CFD方法研究火灾的可靠性和适用性进行了近一步的验证。
本课题开发了一套专门用于地铁环控数值模拟的汉化专用软件。
Along with the development of subway in city, researchers pay more and more attention to the subway environment and subway fire. To build good subway environment means not only to provide a safe and comfortable environment but also to reduce energy consumption, construction costs and operation costs.
To select model equation properly and compartmentalize calculating mesh rationally is very important to the results of CFD numerical simulation. This paper compares the results of field tests and simulation, analyses the effects of turbulence model on temperature field and air distribution in subway system and draw the conclusion that the calculating results of two-equation are more accurate than those of zero equation. Calculating meshes are made up of many incontinuous parts in calculating district. In every part calculate the equation of airflow and heat transfer. The determination of calculating meshes has huge effects on calculating results, time consumption and conservation results. This paper gives the optimizing meshes.
The purpose of field tests is to obtain the boundary condition and verify the feasibility of using turbulence model to simulate platform ventilation, which are the two important conditions of simulating ventilation scheme. This paper use CFD method to simulate temperature field and air distribution of an island platform in winter condition, and measure some experiment data under permit condition to compare with the results of simulation in order to prove the reliability of computer simulation and select some boundary conditions.
Which environment control scheme should be selected depends on objective condition, construction cost, operation effect, etc. for the large difference of climatic conditions and temperature and humidity. This paper calculates the temperature field and air distribution of Shenzhen (south), Tianjin (north) and Shenyang (northeast) under summer condition. Optimizes the air distribution of island and side subway platform of Tianjin, compares air conditioning scheme and ventilation scheme of Shenzhen, and gives the suitable ventilation scheme. Analyses the economical efficiency of shield gate, the action of exhaust air under railway and top part exhaust using CFD simulation.
This paper analog simulates temperature field and air distribution of some fire conditions using CFD method and analyses the effect of fire location and exhaust smoke level on temperature field and air distribution. The method of saltwater experiment belongs to small size simulation experiment. This paper makes saltwater experiment of platform fire and train fire and compares the results with computer simulation results.To testifie the reliability and applicability, this paper analyses and compares results of CFD method and substantive fire.
The thesis develops a set of software of the simulation on subway station in Chinese.
正确的选择模型方程,合理的划分计算网格,对CFD数值模拟的结果有着重要的影响。本课题比较了现场测试结果与计算结果,分析了湍流模型的选择对整个地铁系统温度场、气流场的计算结果的影响,得到了双方程计算准确性优于零方程的结论。计算网格是由计算域内不连续的部分组成的,在每一个成分中,求解控制室内流动和热传递的方程。计算网格的划分对计算结果、计算时间以及计算收敛都将会有很大的影响。求解的时间和精确度直接取决于网格的质量,好的网格划分将会节省计算时间以及提高计算的准确性,本文对不同网格的计算结果与实测值进行了分析比较,得到了较为优化的网格划分。
现场测试的目的是获取计算模拟所需要的边界条件(温度、速度等),验证湍流模型用于模拟站台通风的可行性。本文利用CFD方法模拟一个岛式站台冬季工况的温度场和气流场,在实验条件允许的情况下测得一些实验数据,将模拟结果与实验结果进行对比验证,证明了地铁车站计算机模拟的可靠性,并从中采集并确定了某些边界条件。并对列车进站过程进行了仿真模拟。
不同城市的气候条件、室外温湿度差异很大,因此选用何种环控方案,应根据客观条件、工程造价、运行效果等方面综合分析。本文以南方的深圳,北方的天津和东北的沈阳为例,对这三个不同地区的夏季空调工况的气流场和温度场进行了模拟计算。对天津岛式和侧式车站的不同气流组织进行了方案优化,对沈阳空调通风方案进行了比较,提出了适合于天津和沈阳地铁车站的通风方式。通过CFD数值模拟对屏蔽门的经济性、轨底排风与顶部局部排风的作用进行了分析。
本文针对地铁火灾发生的各种状况如有屏蔽门和无屏蔽门的站台、站厅及列车火灾的各种情况的温度场和气流场进行了CFD仿真模拟,并分析了火灾发生的位置及排烟量对地铁车站气流场和温度场的影响。盐水实验模拟研究方法属于小尺寸模拟试验。本文针对站台及列车着火两种情况进行了盐水实验,实验结果与模拟结果进行了比较。
利用实体燃烧实验与模拟的结果分析比较,对CFD方法研究火灾的可靠性和适用性进行了近一步的验证。
本课题开发了一套专门用于地铁环控数值模拟的汉化专用软件。
Along with the development of subway in city, researchers pay more and more attention to the subway environment and subway fire. To build good subway environment means not only to provide a safe and comfortable environment but also to reduce energy consumption, construction costs and operation costs.
To select model equation properly and compartmentalize calculating mesh rationally is very important to the results of CFD numerical simulation. This paper compares the results of field tests and simulation, analyses the effects of turbulence model on temperature field and air distribution in subway system and draw the conclusion that the calculating results of two-equation are more accurate than those of zero equation. Calculating meshes are made up of many incontinuous parts in calculating district. In every part calculate the equation of airflow and heat transfer. The determination of calculating meshes has huge effects on calculating results, time consumption and conservation results. This paper gives the optimizing meshes.
The purpose of field tests is to obtain the boundary condition and verify the feasibility of using turbulence model to simulate platform ventilation, which are the two important conditions of simulating ventilation scheme. This paper use CFD method to simulate temperature field and air distribution of an island platform in winter condition, and measure some experiment data under permit condition to compare with the results of simulation in order to prove the reliability of computer simulation and select some boundary conditions.
Which environment control scheme should be selected depends on objective condition, construction cost, operation effect, etc. for the large difference of climatic conditions and temperature and humidity. This paper calculates the temperature field and air distribution of Shenzhen (south), Tianjin (north) and Shenyang (northeast) under summer condition. Optimizes the air distribution of island and side subway platform of Tianjin, compares air conditioning scheme and ventilation scheme of Shenzhen, and gives the suitable ventilation scheme. Analyses the economical efficiency of shield gate, the action of exhaust air under railway and top part exhaust using CFD simulation.
This paper analog simulates temperature field and air distribution of some fire conditions using CFD method and analyses the effect of fire location and exhaust smoke level on temperature field and air distribution. The method of saltwater experiment belongs to small size simulation experiment. This paper makes saltwater experiment of platform fire and train fire and compares the results with computer simulation results.To testifie the reliability and applicability, this paper analyses and compares results of CFD method and substantive fire.
The thesis develops a set of software of the simulation on subway station in Chinese.
引文
[1]Schafer, Andreas, Victor,David G.,The future mobility of the world population,Transportation Research Part A: Policy and Practice 2000 ,34(3):171-205
[2]周翊民,城市轨道交通的发展趋势及其动因分析,百家论坛,2001,2,1-4
[3]王梦恕, 我国城市交通的发展方向,铁道工程学报,2003,77(10):43-47
[4]Li, Bengang, Tao, Shu, Dawson, R.W.,Evaluation and analysis of traffic noise from the main urban roads in Beijing,Applied Acoustics,2002,10(63):1137-1142
[5]轩辕啸雯,世界各国地铁建设情况分析,交通工程科技,2001:23-29
[6]Page, M. New York City subway link-up,Journal Of Rock Mechanics And Mining Sciences & Geomechanics,1996,33(7):324
[7] 世界城市地铁与轻轨最新动态,北京,中国铁道出版社,2000-2001
[8]海文,多功能的东京地铁,环球经济. 2003:3
[9]康宁,美国的地下空间开发和利用,浙江地质,2001,11(1):11-13
[10]张新军,起小琴. 韩国城市地铁与轻轨交题发展概况,铁道运输与经济, 2003, 25(1):13
[11]韩林飞, 张桃, 莫斯科地铁建筑, 世界建筑导报, 1998, 000(003):28-31
[12]周家高,巴黎地铁今昔,城市,2003,3:60-61
[13]程煜,自力更生的新加坡地铁,环球财经:国际技术经济研究专刊,2003,3:47-48
[14]管建华,香港地铁调查随想,地铁与轻轨,2002,000(002):5-6
[15]雷风行,中国地铁建设的概况及发展思路,世界隧道,1996,1:1-6
[16]马沂文,我国地铁发展概况,电力机车与城轨车辆,2003,000(001):52-52
[17]李世英,世界地铁及消防,公安科技情报,1991.000(007), 25-29
[18]高浩荣,韩国地铁火灾事故已造成130死140多伤,新浪网, 2003/02/18
[19]Subway Environment Design Handbook VⅡ,USA, Transit Development Corporation,1975
[20]Ming-Tsun Ke , Tsung-Che Cheng, Wen-Por Wang,Numerical Simulation For Optimizing The Design Of Subway Environmental Control System,Building And Environmental,2002,37:1139-1152
[21] Cheng TC, Simulations Of Ventilation And Smoke System For Subway
Tunnel.,S Thesis,National Taipei University Of Technology, Taiwan,
[22]Tsal RJ, Adler MS,Evaluation Of Numerical Methods For Ductwork And Pipeline Optimization. ASHRAE Transactions 1987,93(1):17–34.
[23]Kumar.S.And Cox,G, Mathematical Modeling Of Fires In Road Tunnels, Fifth International Symposium on The Aerodynamics And Ventilation Of Vehicle Tunnels,BHRE,1985,61
[24]chow,w.k, simulation of tunnel fire using a zone model, tunneling and underground and space technology,1996,11(2):221-236
[25]w. k. chow,simulation of tunnel fires using a zone model,Tunneling and Underground Space Technology,1996, 11(2):221-236
[26]J.P. Kunsch,Simple model for control of .re gases in a ventilated tunnel,Fire Safety Journal 2002,37: 67–81
[27]Lee CK, Chaiken RF, Singer JM,Interaction Between Duct Fires And Ventilation Flow. Combust Sci Technol 1979,20:59–72.
[28]Woodburn, P. J., Britter, R. E. ,CFD Simulations of a Tunnel Fire--Part I,Fire Safety Journal 1996, 26(1): 35-62
[29]Modic, Jurij ,Fire simulation in road tunnels,Tunneling and Underground Space Technology,2003, 18(5):525-530
[30]Nam, Soonil,Numerical simulation of smoke movement in clean room environments,Fire Safety Journal,2000, 34(2):169-189
[31]Ma, T.G., Quintiere, J.G.,Numerical simulation of axi-symmetric fire plumes: accuracy and limitations,Fire Safety Journal,2003,38(5):467-492
[32]Novozhilov, V.,Computational Fluid Dynamics Modeling Of Compartment Fires,Progress In Energy And Combustion Science ,2001,27(6), 611-666
[33]Jia, F., Galea, E.R.,Patel, M.K. ,The numerical simulation of the noncharring pyrolysis process and fire development within a compartment,Applied Mathematical Modelling,1999,23(8):587-607
[34]Cheng, L.H.,Ueng, T.H.; Liu, C.W.,Simulation of ventilation and fire in the underground facilities,Fire Safety Journal ,2001,36(6):597-619
[35]McGrattan, K. B., Baum, H. R., Rehm, R. G. ,Large eddy simulations of smoke movement,Fire Safety Journal 1998,30(2):161-178
[36]Yeoh, G.H., Yuen, R.K.K.; Lo, S.M., Chen, D.H.,On numerical comparison of enclosure fire in a multi-compartment building,Fire Safety Journal ,2003,38(1):85-94
[37]Woodburn, P. J.; Britter, R. E. ,CFD Simulations of a Tunnel Fire--Part II,Fire Safety Journal ,1996,26(1):63-90
[38]McGrattan, Kevin B., Baum, Howard R., Rehm, Ronald G.,Numerical simulation of smoke plumes from large oil fires,Atmospheric Environment,1996,30(24):4125-4136
[39]H.K. Versteeh,W. Malalasekera,An introduction to computational fluid dynamics, The finite volume method,Essex:Longman Scientific &. Technical,1995
[40]J. Niu, J.V.D. Kooi,Numerical investigations of thermal comfort and indoor contaminant distribution in a room with cooled ceiling system,Proceedings of Indoor Air ’93 5,1993:331-336
[41]G. Gan,Towards a better indoor thermal environment-A CFD analysis of the performance of chilled ceiling system,Proceedings of the 4th International Symposium on Ventilation for Contaminant Control,1994:551-556
[42]陶文铨 编著,数值传热学(第二版),西安交通大学出版社,2001
[43]T.V. Jacobsen, P.V. Neilsen,Numerical modeling of thermal environment in a displacement-ventilated room,in: Proceedings of the ‘Indoor Air’ 93’,Helsinki, Finland, 1993, 5:301-306
[44]Y. Li, L. Fuchs, M. Sandberg,Numerical prediction of airflow and heat-radiation in a room with displacement ventilation,Energy and Buildings,1993,20:27-43
[45]S.J. Rees, J.J. McGuirk, P. Haves,Numerical investigation of transient buoyant flow in a room with a displacement ventilation and chilled ceiling system,International Journal of Heat and Mass Transfer,2001,44:3067—3080
[46]Hee-Jin Park, Dale Holland,The effect of location of a convective heat source on displacement ventilation: CFD study,Building and Environment,2001,36:883-889
[47]Hu, Zehua; Sun, Da-Wen, Effect of fluctuation in inlet airflow temperature on CFD simulation of air-blast chilling process, Journal of food engineering, 2001,48:311-316
[48]Gadgil, A.J., Lobscheid, C., Abadie, M.O., Finlayson, E.U.,Indoor pollutant mixing time in an isothermal closed room: an investigation using CFD,Atmospheric Environment,2003,37: 5577-5586
[49]Gan, G.,Evaluation of room air distribution systems using computational fluid dynamics,Fuel and Energy Abstracts,1996,37(2-3):132
[50]Nijemeisland, Michiel, Dixon, Anthony G.,Comparison of CFD simulations to experiment for convective heat transfer in a gas–solid fixed bed,Chemical Engineering Journal Volume,2001,82(1-3):231-246
[51]M. Cehlin, B. Moshfegh,M. Sandberg,Measurements of air temperatures
close to a low-velocity diffuser in displacement ventilation using an infrared camera,Energy and Buildings,2002,34:687-698
[52]H.K. Versteeh,W. Malalasekera,An introduction to computational fluid dynamics, The finite volume method,Essex:Longman Scientific &. Technical,1995
[53]陶文铨 著,计算传热学的近代进展,科学出版社,2000
[54]Wu, Y., Bakar, M.Z.A.,Control of smoke flow in tunnel fires using longitudinal ventilation systems – a study of the critical velocity,Fire Safety Journal,2000,35,(4) :363-390
[55]Li, Jojo S.M., Chow, W.K., Numerical studies on performance evaluation of tunnel ventilation safety system,Tunneling and Underground Space, 2003,18(5):435-452
[56]Laslandes, S.; Sacré, C., Transport of particles by a turbulent flow around an obstacle – a numerical and a wind tunnel approach,Journal of Wind Engineering and Industrial Aerodynamics,1998,74:577-587
[57]Bartzanas, T., Boulard, T.; Kittas, C.,Numerical simulation of the airflow and temperature distribution in a tunnel greenhouse equipped with insect-proof screen in the openings,Computers and Electronics in Agriculture,2002,34(1-3):207-221
[58]Gidhagen, L.,Johansson, C., Str?m, J.,Model simulation of ultrafine particles inside a road tunnel,Atmospheric Environment,2003,37(15):2023-2036
[59]Ghani, S.A.A. Abdul, Aroussi, A.,Rice, E.,Simulation of road vehicle natural environment in a climatic wind tunnel,Simulation Practice and Theory,2001,8(6-7):359-375
[60]Wu, Y., Bakar, M.Z.A.,Control of smoke flow in tunnel fires using longitudinal ventilation systems – a study of the critical velocity,Fire Safety Journal,200035(4):363-390
[61]欧阳沁 江泳,关于地铁隧道区间段阻塞研究工况临界通风速度的研究(Ⅰ),地铁与轻轨,2002,56(2) :34-41
[62]舒宁 钟汉枢 等,计算流体力学在纵向式公路隧道火灾通风中的仿真,2001,16(4):210-516
[63] Richard Bettis, Controlling Smoke in Tunnel Fires, Fire prevention,1995,280:19-23
[64]王永东 夏永旭,公路隧道纵向通风系统局部影响数值模拟,西安公路交通大学学报,2001,21(4):50-54
[65]Abu-Zaid, Sameer A. Analyzing a Transit Subway Station During Fire Emergency Using Computational Fluid Dynamics. Transportation research record. NO. 1521, (1996): 159
[65]Deng, Mark P.,Miclea, Paul C., McKinney, Dan,CFD modeling considerations for train fires in underground subway stations,Proceedings of the 1996 ASME Fluids Engineering Division Summer Meeting. Part 3 (of 3) Jul 7-11 1996 v 238 n 3 1996 San Diego, CA,USA, Sponsored by : ASME ASME New York NY USA p 547-555 FEDSDL
[67]Elias, Steven R.,Raw, Michael J.; Bostwick, Peter, Numerical simulation of subway station fires and ventilation. American Society of Mechanical Engineers, Fluids Engineering Division (Publication) FED Proceedings of the 1996 ASME Fluids Engineering Division Summer Meeting. Part 3 (of 3) Jul 7-11 1996 v 238 n 3 1996 San Diego, CA,USA, Sponsored by : ASME New York NY USA p 557-562 FEDSDL
[68]Subway Environment Design Handbook VⅡ,USA,Transit Development Corporation, 1995
[69]中华人民共和国国家标准,地下铁道设计规范(GB50157-92),中国计划出版社,1993
[70]T.Y.Chen,Y.T.Lee,C.C.Hsu, Investigation of Piston-effect and jet fan-effect in model vehicle tunnels,Journal of Wind Engineering and Industrial Aerodynamics ,1998,73: 99-110
[71]S. V. 帕坦卡 著,张政 译,传热与流体流动的数值计算,科学出版社,1984
[72]傅德薰主编,流体力学数值模拟,国防工业出版社,1993
[73]陈材侃编著,计算流体力学,重庆出版社,1992
[74]陶文铨 著,数值传热学,西安交通大学出版社,1988
[75]朱自强 等著,应用计算流体力学,北京航空航天大学出版社,1998.8
[76]朱自强 等著,应用计算流体力学,北京航空航天大学出版社,1998.8
[77]刘超群 著,多重网格法及其在计算流体力学中的应用,清华大学出版社,1995
[78]冯炼,地铁环境控制系统的应用及其数值模拟软件,城市轨道交通研究.1999,2(2).37-39
[79]陈云娜,浅谈地铁环控通风,地下工程与隧道,1995,3:38-42
[80]中华人民共和国国家标准,地下铁道设计规范(GB50157-2003),中国计划出版社,2003
[81]Qingyuan Zhang, Kenji Asano, HajimeImai,Regional Characteristics of
Air-conditioning Loads for Residences in China, Seventh International IBPSA Conference. August 13-15,2001.
[82] Qingyuan Zhang, Kenji Asano,Development of the Typical Weather Data for the Main Chinese Cities,Journal of Architecture,Planning and Environmental
engine-ering,No.54302001
[83]天津市地下铁道1 号线工程可行性研究报告. 铁道部第三勘测设计院,2001年8月
[84]天津市地铁工程气象资料汇编,天津市气候服务中心提供.2000 年10 月31 日
[85]华人民共和国国家标准. 采暖通风与空气调节设计规范(GBJ19-87). 中
国计划出版社,1989.
[86]天津市地下铁道1 号线环控系统初步设计中审稿. 上海市隧道工程轨道交通设计研究院,2001 年12 月.
[87]李景广,有效通风及其相关的研究和模拟,博士学位论文,天津,天津大学2001
[88]茂又弘道,津田帮彦. 地铁内的发热及热负荷计算. 隧道绎丛,1993(8):16-25
[89]娄晓军,变频控制的地铁变风量环控方案研究,硕士学位论,天津,天津大学文,2002
[90] 王良柱,地铁侧式站台通风CFD模拟与优化,硕士学位论文,天津,天津大学,2002
[91]深圳地铁一期工程施工图设计环境控制篇,铁道第三勘查设计院,2002
[92]冯炼,地铁屏蔽门的环境控制效果研究,西南交通大学学报,2002,37(2):154-157
[93] 高净,站台屏蔽门的运行模式及控制方法,铁道机车车辆,1999,6:31-32
[94] 朱颖心 秦绪忠 江 亿,站台屏蔽门在地铁热环境控制中的经济性分析,建筑科学,1997,4:42-46
[95] 高净,深圳地铁车站站台屏蔽门系统(PSD),地铁与轻轨,1999,3:27-23
[96]全国气象参数一览表,www.honhye.com.cn
[97]地下大型商场火灾蔓延规律和烟气流动特性研究报告,公安部天津消防科研所,2001
[98]范维澄 王清安 姜冯辉,火灾学简明教程,1995,10月
[99]Glasspool, Ian,A major fire event recorded in the mesofossils and petrology of the Late Permian,Lower Whybrow coal seam, Sydney Basin, Australia,Palaeogeography, Palaeoclimatology, Palaeoecology,2000,164(1-4):357-380
[100]伦敦地铁安全防火措施,中国消防,1998,10:42
[101]李世英,世界地铁及地铁消防,1991,7:25-29
[102] 陈鼎榕,地铁火灾事故下的安全疏散,城市轨道交通研究.2003,6(2):29-31
[103]芮立群,地铁的火灾疏散和防排烟,城市公用事业.1997,11(1),10-12
[104]晨佳,地铁车站火灾时疏散能力计算,地下工程与隧道.1992.000(004).-33-35
[105]美国有轨交通系统标准NFPAl30,1986
[106]日本火灾学会论文集,1987
[107]Thomas P H. Modeling Of Compantment Fires.Fire Safty journal,1963,5:181-190
[108]张和平,周小东,万田玉,受限空间烟气运动盐水模拟研究的现状和展望,中国安全科学学报,1999,9(1):30-35
[109]K.D.Sleckel,H.R.Beum,J.G,Quinliere,Saltwater Modeling Of Fire Induce Flows In Multicompartment Enclassures,1986
[110]M.V.,Chobotov,E.E.,Zukoski And T.,Kubots. Gravity Currents With Heat Transfer Effect Nbs-Grc-87-522,California Institute Of Technology Pasadena,Ca,Dec.,1986
[111]C.M.Fleischmann,P.J.Pagni And R.B.Willianmson, Salt Water Modeling
[112]张和平.火灾烟气运动盐水实验模拟和受限空间初起火灾烟气运动特性的研究.中国科学技术大学博算士学位论文,1996.1.
[113]伍作朋,吴丽琼,火灾模化与相似理论,消防科技,1997,3:7-9
[2]周翊民,城市轨道交通的发展趋势及其动因分析,百家论坛,2001,2,1-4
[3]王梦恕, 我国城市交通的发展方向,铁道工程学报,2003,77(10):43-47
[4]Li, Bengang, Tao, Shu, Dawson, R.W.,Evaluation and analysis of traffic noise from the main urban roads in Beijing,Applied Acoustics,2002,10(63):1137-1142
[5]轩辕啸雯,世界各国地铁建设情况分析,交通工程科技,2001:23-29
[6]Page, M. New York City subway link-up,Journal Of Rock Mechanics And Mining Sciences & Geomechanics,1996,33(7):324
[7] 世界城市地铁与轻轨最新动态,北京,中国铁道出版社,2000-2001
[8]海文,多功能的东京地铁,环球经济. 2003:3
[9]康宁,美国的地下空间开发和利用,浙江地质,2001,11(1):11-13
[10]张新军,起小琴. 韩国城市地铁与轻轨交题发展概况,铁道运输与经济, 2003, 25(1):13
[11]韩林飞, 张桃, 莫斯科地铁建筑, 世界建筑导报, 1998, 000(003):28-31
[12]周家高,巴黎地铁今昔,城市,2003,3:60-61
[13]程煜,自力更生的新加坡地铁,环球财经:国际技术经济研究专刊,2003,3:47-48
[14]管建华,香港地铁调查随想,地铁与轻轨,2002,000(002):5-6
[15]雷风行,中国地铁建设的概况及发展思路,世界隧道,1996,1:1-6
[16]马沂文,我国地铁发展概况,电力机车与城轨车辆,2003,000(001):52-52
[17]李世英,世界地铁及消防,公安科技情报,1991.000(007), 25-29
[18]高浩荣,韩国地铁火灾事故已造成130死140多伤,新浪网, 2003/02/18
[19]Subway Environment Design Handbook VⅡ,USA, Transit Development Corporation,1975
[20]Ming-Tsun Ke , Tsung-Che Cheng, Wen-Por Wang,Numerical Simulation For Optimizing The Design Of Subway Environmental Control System,Building And Environmental,2002,37:1139-1152
[21] Cheng TC, Simulations Of Ventilation And Smoke System For Subway
Tunnel.,S Thesis,National Taipei University Of Technology, Taiwan,
[22]Tsal RJ, Adler MS,Evaluation Of Numerical Methods For Ductwork And Pipeline Optimization. ASHRAE Transactions 1987,93(1):17–34.
[23]Kumar.S.And Cox,G, Mathematical Modeling Of Fires In Road Tunnels, Fifth International Symposium on The Aerodynamics And Ventilation Of Vehicle Tunnels,BHRE,1985,61
[24]chow,w.k, simulation of tunnel fire using a zone model, tunneling and underground and space technology,1996,11(2):221-236
[25]w. k. chow,simulation of tunnel fires using a zone model,Tunneling and Underground Space Technology,1996, 11(2):221-236
[26]J.P. Kunsch,Simple model for control of .re gases in a ventilated tunnel,Fire Safety Journal 2002,37: 67–81
[27]Lee CK, Chaiken RF, Singer JM,Interaction Between Duct Fires And Ventilation Flow. Combust Sci Technol 1979,20:59–72.
[28]Woodburn, P. J., Britter, R. E. ,CFD Simulations of a Tunnel Fire--Part I,Fire Safety Journal 1996, 26(1): 35-62
[29]Modic, Jurij ,Fire simulation in road tunnels,Tunneling and Underground Space Technology,2003, 18(5):525-530
[30]Nam, Soonil,Numerical simulation of smoke movement in clean room environments,Fire Safety Journal,2000, 34(2):169-189
[31]Ma, T.G., Quintiere, J.G.,Numerical simulation of axi-symmetric fire plumes: accuracy and limitations,Fire Safety Journal,2003,38(5):467-492
[32]Novozhilov, V.,Computational Fluid Dynamics Modeling Of Compartment Fires,Progress In Energy And Combustion Science ,2001,27(6), 611-666
[33]Jia, F., Galea, E.R.,Patel, M.K. ,The numerical simulation of the noncharring pyrolysis process and fire development within a compartment,Applied Mathematical Modelling,1999,23(8):587-607
[34]Cheng, L.H.,Ueng, T.H.; Liu, C.W.,Simulation of ventilation and fire in the underground facilities,Fire Safety Journal ,2001,36(6):597-619
[35]McGrattan, K. B., Baum, H. R., Rehm, R. G. ,Large eddy simulations of smoke movement,Fire Safety Journal 1998,30(2):161-178
[36]Yeoh, G.H., Yuen, R.K.K.; Lo, S.M., Chen, D.H.,On numerical comparison of enclosure fire in a multi-compartment building,Fire Safety Journal ,2003,38(1):85-94
[37]Woodburn, P. J.; Britter, R. E. ,CFD Simulations of a Tunnel Fire--Part II,Fire Safety Journal ,1996,26(1):63-90
[38]McGrattan, Kevin B., Baum, Howard R., Rehm, Ronald G.,Numerical simulation of smoke plumes from large oil fires,Atmospheric Environment,1996,30(24):4125-4136
[39]H.K. Versteeh,W. Malalasekera,An introduction to computational fluid dynamics, The finite volume method,Essex:Longman Scientific &. Technical,1995
[40]J. Niu, J.V.D. Kooi,Numerical investigations of thermal comfort and indoor contaminant distribution in a room with cooled ceiling system,Proceedings of Indoor Air ’93 5,1993:331-336
[41]G. Gan,Towards a better indoor thermal environment-A CFD analysis of the performance of chilled ceiling system,Proceedings of the 4th International Symposium on Ventilation for Contaminant Control,1994:551-556
[42]陶文铨 编著,数值传热学(第二版),西安交通大学出版社,2001
[43]T.V. Jacobsen, P.V. Neilsen,Numerical modeling of thermal environment in a displacement-ventilated room,in: Proceedings of the ‘Indoor Air’ 93’,Helsinki, Finland, 1993, 5:301-306
[44]Y. Li, L. Fuchs, M. Sandberg,Numerical prediction of airflow and heat-radiation in a room with displacement ventilation,Energy and Buildings,1993,20:27-43
[45]S.J. Rees, J.J. McGuirk, P. Haves,Numerical investigation of transient buoyant flow in a room with a displacement ventilation and chilled ceiling system,International Journal of Heat and Mass Transfer,2001,44:3067—3080
[46]Hee-Jin Park, Dale Holland,The effect of location of a convective heat source on displacement ventilation: CFD study,Building and Environment,2001,36:883-889
[47]Hu, Zehua; Sun, Da-Wen, Effect of fluctuation in inlet airflow temperature on CFD simulation of air-blast chilling process, Journal of food engineering, 2001,48:311-316
[48]Gadgil, A.J., Lobscheid, C., Abadie, M.O., Finlayson, E.U.,Indoor pollutant mixing time in an isothermal closed room: an investigation using CFD,Atmospheric Environment,2003,37: 5577-5586
[49]Gan, G.,Evaluation of room air distribution systems using computational fluid dynamics,Fuel and Energy Abstracts,1996,37(2-3):132
[50]Nijemeisland, Michiel, Dixon, Anthony G.,Comparison of CFD simulations to experiment for convective heat transfer in a gas–solid fixed bed,Chemical Engineering Journal Volume,2001,82(1-3):231-246
[51]M. Cehlin, B. Moshfegh,M. Sandberg,Measurements of air temperatures
close to a low-velocity diffuser in displacement ventilation using an infrared camera,Energy and Buildings,2002,34:687-698
[52]H.K. Versteeh,W. Malalasekera,An introduction to computational fluid dynamics, The finite volume method,Essex:Longman Scientific &. Technical,1995
[53]陶文铨 著,计算传热学的近代进展,科学出版社,2000
[54]Wu, Y., Bakar, M.Z.A.,Control of smoke flow in tunnel fires using longitudinal ventilation systems – a study of the critical velocity,Fire Safety Journal,2000,35,(4) :363-390
[55]Li, Jojo S.M., Chow, W.K., Numerical studies on performance evaluation of tunnel ventilation safety system,Tunneling and Underground Space, 2003,18(5):435-452
[56]Laslandes, S.; Sacré, C., Transport of particles by a turbulent flow around an obstacle – a numerical and a wind tunnel approach,Journal of Wind Engineering and Industrial Aerodynamics,1998,74:577-587
[57]Bartzanas, T., Boulard, T.; Kittas, C.,Numerical simulation of the airflow and temperature distribution in a tunnel greenhouse equipped with insect-proof screen in the openings,Computers and Electronics in Agriculture,2002,34(1-3):207-221
[58]Gidhagen, L.,Johansson, C., Str?m, J.,Model simulation of ultrafine particles inside a road tunnel,Atmospheric Environment,2003,37(15):2023-2036
[59]Ghani, S.A.A. Abdul, Aroussi, A.,Rice, E.,Simulation of road vehicle natural environment in a climatic wind tunnel,Simulation Practice and Theory,2001,8(6-7):359-375
[60]Wu, Y., Bakar, M.Z.A.,Control of smoke flow in tunnel fires using longitudinal ventilation systems – a study of the critical velocity,Fire Safety Journal,200035(4):363-390
[61]欧阳沁 江泳,关于地铁隧道区间段阻塞研究工况临界通风速度的研究(Ⅰ),地铁与轻轨,2002,56(2) :34-41
[62]舒宁 钟汉枢 等,计算流体力学在纵向式公路隧道火灾通风中的仿真,2001,16(4):210-516
[63] Richard Bettis, Controlling Smoke in Tunnel Fires, Fire prevention,1995,280:19-23
[64]王永东 夏永旭,公路隧道纵向通风系统局部影响数值模拟,西安公路交通大学学报,2001,21(4):50-54
[65]Abu-Zaid, Sameer A. Analyzing a Transit Subway Station During Fire Emergency Using Computational Fluid Dynamics. Transportation research record. NO. 1521, (1996): 159
[65]Deng, Mark P.,Miclea, Paul C., McKinney, Dan,CFD modeling considerations for train fires in underground subway stations,Proceedings of the 1996 ASME Fluids Engineering Division Summer Meeting. Part 3 (of 3) Jul 7-11 1996 v 238 n 3 1996 San Diego, CA,USA, Sponsored by : ASME ASME New York NY USA p 547-555 FEDSDL
[67]Elias, Steven R.,Raw, Michael J.; Bostwick, Peter, Numerical simulation of subway station fires and ventilation. American Society of Mechanical Engineers, Fluids Engineering Division (Publication) FED Proceedings of the 1996 ASME Fluids Engineering Division Summer Meeting. Part 3 (of 3) Jul 7-11 1996 v 238 n 3 1996 San Diego, CA,USA, Sponsored by : ASME New York NY USA p 557-562 FEDSDL
[68]Subway Environment Design Handbook VⅡ,USA,Transit Development Corporation, 1995
[69]中华人民共和国国家标准,地下铁道设计规范(GB50157-92),中国计划出版社,1993
[70]T.Y.Chen,Y.T.Lee,C.C.Hsu, Investigation of Piston-effect and jet fan-effect in model vehicle tunnels,Journal of Wind Engineering and Industrial Aerodynamics ,1998,73: 99-110
[71]S. V. 帕坦卡 著,张政 译,传热与流体流动的数值计算,科学出版社,1984
[72]傅德薰主编,流体力学数值模拟,国防工业出版社,1993
[73]陈材侃编著,计算流体力学,重庆出版社,1992
[74]陶文铨 著,数值传热学,西安交通大学出版社,1988
[75]朱自强 等著,应用计算流体力学,北京航空航天大学出版社,1998.8
[76]朱自强 等著,应用计算流体力学,北京航空航天大学出版社,1998.8
[77]刘超群 著,多重网格法及其在计算流体力学中的应用,清华大学出版社,1995
[78]冯炼,地铁环境控制系统的应用及其数值模拟软件,城市轨道交通研究.1999,2(2).37-39
[79]陈云娜,浅谈地铁环控通风,地下工程与隧道,1995,3:38-42
[80]中华人民共和国国家标准,地下铁道设计规范(GB50157-2003),中国计划出版社,2003
[81]Qingyuan Zhang, Kenji Asano, HajimeImai,Regional Characteristics of
Air-conditioning Loads for Residences in China, Seventh International IBPSA Conference. August 13-15,2001.
[82] Qingyuan Zhang, Kenji Asano,Development of the Typical Weather Data for the Main Chinese Cities,Journal of Architecture,Planning and Environmental
engine-ering,No.54302001
[83]天津市地下铁道1 号线工程可行性研究报告. 铁道部第三勘测设计院,2001年8月
[84]天津市地铁工程气象资料汇编,天津市气候服务中心提供.2000 年10 月31 日
[85]华人民共和国国家标准. 采暖通风与空气调节设计规范(GBJ19-87). 中
国计划出版社,1989.
[86]天津市地下铁道1 号线环控系统初步设计中审稿. 上海市隧道工程轨道交通设计研究院,2001 年12 月.
[87]李景广,有效通风及其相关的研究和模拟,博士学位论文,天津,天津大学2001
[88]茂又弘道,津田帮彦. 地铁内的发热及热负荷计算. 隧道绎丛,1993(8):16-25
[89]娄晓军,变频控制的地铁变风量环控方案研究,硕士学位论,天津,天津大学文,2002
[90] 王良柱,地铁侧式站台通风CFD模拟与优化,硕士学位论文,天津,天津大学,2002
[91]深圳地铁一期工程施工图设计环境控制篇,铁道第三勘查设计院,2002
[92]冯炼,地铁屏蔽门的环境控制效果研究,西南交通大学学报,2002,37(2):154-157
[93] 高净,站台屏蔽门的运行模式及控制方法,铁道机车车辆,1999,6:31-32
[94] 朱颖心 秦绪忠 江 亿,站台屏蔽门在地铁热环境控制中的经济性分析,建筑科学,1997,4:42-46
[95] 高净,深圳地铁车站站台屏蔽门系统(PSD),地铁与轻轨,1999,3:27-23
[96]全国气象参数一览表,www.honhye.com.cn
[97]地下大型商场火灾蔓延规律和烟气流动特性研究报告,公安部天津消防科研所,2001
[98]范维澄 王清安 姜冯辉,火灾学简明教程,1995,10月
[99]Glasspool, Ian,A major fire event recorded in the mesofossils and petrology of the Late Permian,Lower Whybrow coal seam, Sydney Basin, Australia,Palaeogeography, Palaeoclimatology, Palaeoecology,2000,164(1-4):357-380
[100]伦敦地铁安全防火措施,中国消防,1998,10:42
[101]李世英,世界地铁及地铁消防,1991,7:25-29
[102] 陈鼎榕,地铁火灾事故下的安全疏散,城市轨道交通研究.2003,6(2):29-31
[103]芮立群,地铁的火灾疏散和防排烟,城市公用事业.1997,11(1),10-12
[104]晨佳,地铁车站火灾时疏散能力计算,地下工程与隧道.1992.000(004).-33-35
[105]美国有轨交通系统标准NFPAl30,1986
[106]日本火灾学会论文集,1987
[107]Thomas P H. Modeling Of Compantment Fires.Fire Safty journal,1963,5:181-190
[108]张和平,周小东,万田玉,受限空间烟气运动盐水模拟研究的现状和展望,中国安全科学学报,1999,9(1):30-35
[109]K.D.Sleckel,H.R.Beum,J.G,Quinliere,Saltwater Modeling Of Fire Induce Flows In Multicompartment Enclassures,1986
[110]M.V.,Chobotov,E.E.,Zukoski And T.,Kubots. Gravity Currents With Heat Transfer Effect Nbs-Grc-87-522,California Institute Of Technology Pasadena,Ca,Dec.,1986
[111]C.M.Fleischmann,P.J.Pagni And R.B.Willianmson, Salt Water Modeling
[112]张和平.火灾烟气运动盐水实验模拟和受限空间初起火灾烟气运动特性的研究.中国科学技术大学博算士学位论文,1996.1.
[113]伍作朋,吴丽琼,火灾模化与相似理论,消防科技,1997,3:7-9
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