期刊文献+

地铁新环控系统可行性分析及性能优化 被引量:9

Feasibility Analysis and Performance Optimization for New Environmental Control System of Subway
下载PDF
导出
摘要 为降低地铁环控系统能耗,根据目前传统屏蔽门系统和安全门系统的优劣性,提出了可控风口的新环控系统.以某新建地铁为例对新系统的舒适性、通风及节能效果进行了分析论证.利用计算流体力学方法对列车进站和出站过程进行了非稳态模拟,分析了列车进站、出站过程产生的活塞风对站台站厅舒适性、通风效果的影响,并根据系统负荷及运行条件进行了节能效果分析.结果表明,新环控系统可兼顾屏蔽门和安全门系统的优点,当按照优化后的开口和控制方案运行地铁新环控系统时,站台内乘客活动区域气流速度小于5,m/s,满足舒适性要求,同时可在屏蔽门系统的基础上降低能耗17.3%,节能效果显著. In order to reduce the energy consumption of the environmental control system of subway station, a new environmental control system with controllable slit was proposed according to the advantages and disadvantages exist- ing in the traditional platform screen door (PSD) and safety door systems. A newly-built subway station was intro- duced to analyze and demonstrate the comfort, ventilation and energy-saving effect of the new system. Transient simu- lation on the process of trains pulling in and out of a station was carried out by using computational fluid dynamics (CFD) method to analyze the comfort and ventilation in the station influenced by piston wind. Moreover, energy- saving effect was analyzed according to the load of the system and operating conditions. The result shows that the new environmental control system contains the advantages of both PSD and safety door systems, the air velocity of the passenger activity areas in the platform is less than 5 m/s using the optimized opening and operating programs, meet- ing the comfort requirement, and the energy consumption can be reduced by 17.3% compared with PSD systems.
出处 《天津大学学报》 EI CAS CSCD 北大核心 2012年第3期268-272,共5页 Journal of Tianjin University(Science and Technology)
基金 国家自然科学基金资助项目(51076112) 教育部高等学校博士点基金资助项目(200800560041)
关键词 屏蔽门 活塞风 可控风口 计算流体力学 节能 platform screen door piston wind controllable slit computational fluid dynamics energy-saving
  • 相关文献

参考文献5

二级参考文献10

  • 1Ke Ming-Tsun,Cheng Tsung-Che,Wang Wen-Por.Numerical simulation for optimizing the design of subway environmental control system[J].Building and Environmental,2002,37:1139-1152.
  • 2Cheng L H,Ueng T H,Liu C W.Simulation of ventilation and fire in the underground facilities[J].Fire Safety Journal,2001,36(6):597-619.
  • 3Woodburn P J,Britter R E.CFD simulations of a tunnel fire (Part Ⅱ)[J].Fire Safety Journal,1996,26(1):63-90.
  • 4Ghani S A A,Abdul Aroussi A,Rice E.Simulation of road vehicle natural environment in a climatic wind tunnel[J].Simulation Practice and Theory,2001,8 (6/7):359-375.
  • 5Ming-Tsun Ke, Tsung-Che Cheng. Numerical Simulation for Optimizing the Design of Subway Environmental Control System [ J ]. Building and Environment, 2002, 37: 1139-1152.
  • 6Kazuhiro Fukuyo. Application of Computational Fluid Dynamics and Pedestrian-Behavior Simulations to the Design of Task-Ambient Air-Conditioning Systems of a Subway Station[J]. Energy, 2006,31:706 - 718.
  • 7Chen F, Chien S W, Jang H M, et al. Stack Effects on Smoke Propagation in Subway Stations [ J]. Continuum Mech. Thermodyn,2003,15:425 - 440.
  • 8Chen F, Guo S C, Chuay H Y, et al. Smoke Control of Fires in Subway Stations[J]. Theoret. Comput. Fluid Dynamics, 2003,16 : 349 - 368.
  • 9Kim J Y, Kim K Y. Experimental and Numerical Analyses of Train-Induced Unsteady Tunnel Flow in Subway [J]. Tunnelling and Underground Space Technology, 2007,22 : 166- 172.
  • 10AnyuanLiu,YufengDuan,等.Numerical Simulation of Heat Transfer in a Gas Solid Crossflow Moving Packed Bed Heat Exchanger[J].Journal of Thermal Science,2001,10(3):228-232. 被引量:9

共引文献33

同被引文献57

引证文献9

二级引证文献50

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部