大坡道长大隧道及隧道群环境下高速列车车内外压力波特性的实车试验研究

doi:10.3973/j.issn.2096-4498.2024.07.012

隧道建设（中英文） ›› 2024, Vol. 44 ›› Issue (7): 1454-1464.DOI: 10.3973/j.issn.2096-4498.2024.07.012

• 高速铁路隧道空气动力学专题 • 上一篇下一篇

大坡道长大隧道及隧道群环境下高速列车车内外压力波特性的实车试验研究

杜权，杜迎春，杨瑞，魏康，万有财，梅元贵^*

(兰州交通大学甘肃省轨道交通力学应用工程实验室，甘肃兰州 730070)

出版日期:2024-07-20 发布日期:2024-08-05
作者简介:杜权（1997—），男，甘肃会宁人，兰州交通大学车辆工程专业在读博士，研究方向为轨道交通空气动力学及应用。E-mail： duquan0915@163.com。*通信作者：梅元贵， E-mail： meiyuangui@163.com。

Full-Scale Test on Internal and External Pressure Wave Characteristics of High-Speed Trains in Long, Steep Tunnels and Tunnel Group Environments

DU Quan, DU Yingchun, YANG Rui, WEI Kang, WAN Youcai, MEI Yuangui^*

(Gansu Province Engineering Laboratory of Rail Transit Mechanics Application, Lanzhou Jiaotong University, Lanzhou 730070, Gansu, China)

Online:2024-07-20 Published:2024-08-05

摘要/Abstract

摘要： 高速列车通过25‰单面坡隧道时，形成压力波和大气压两者耦合下的车内外压力变化特征，因此，有必要研究在隧道大气压持续变化下的高速列车通过大坡道隧道时的气动载荷和车内压力舒适性问题。采用实车试验的方法，获取动车组通过西成高铁西安北—汉中线路的列车车内外压力测试数据。研究结果表明： 1）列车下坡通过25‰特长隧道时车外压力波动受隧道压力波与大气压的共同作用，整体呈上升的变化趋势； 2）单面坡上坡和单面坡下坡隧道的长度由1 541.2 m增大至8 399.2 m时，列车车内外最大压力峰值越靠近隧道出口，单面坡隧道长度越长，列车车内外压力峰值越大； 3）随着大坡道隧道长度的增大，列车头车和尾车的整车气密效率在不断减小，列车车内Δp/1 s、Δp/3 s、Δp/10 s和Δp/60 s在不断增大，相应的车内压力舒适性环境更恶劣，当列车通过长大坡道隧道群时，车内压力舒适性环境和列车车体的气密性能更差； 4）与压力保护阀逻辑控制相比，压力保护阀全程关闭时列车车内压力和不同时间间隔下的最大压力变化量要更小，车内压力舒适性环境更优。

关键词: 大坡道长大隧道, 隧道群, 车内外压力, 压力舒适性环境, 实车试验

Abstract: When a high-speed train passes through a tunnel with a 25‰ single-sided slope, the internal and external pressure wave generated by the high speed of the train couples with atmospheric pressure changes, resulting in distinctive internal and external pressure variations. Therefore, it is necessary to study the aerodynamic loads and in-train pressure comfort of high-speed trains passing through steep tunnels under various atmospheric pressures. In this study, real-train test methods are employed to obtain internal and external pressure data of a high-speed train passing through the Xi′an Bei station-Hanzhong station of the Xi′an-Chengdu high-speed railway. The results demonstrate the following: (1) When a single train descends through a 25‰ extra-long tunnel, the external pressure variation trend is consistent with the changes in atmospheric pressure due to decreasing tunnel altitude. (2) As the tunnel length increases from1 541.2 m to 8 399.2 m for both uphill and downhill single-sided slopes, the maximum internal and external pressure peaks of the train occur closer to the tunnel exit. Additionally, the maximum internal and external pressure peaks of the train increase linearly with the tunnel length. (3) As tunnel length increases, the airtightness of the train′s head and tail continuously decreases, resulting in an increase in the Δp/1 s, Δp/3 s, Δp/10 s, and Δp/60 s, which correspondingly leads to a deteriorating in-train pressure comfort environment. When the train passes through long, steep tunnel groups, both the train′s airtightness performance and in-train comfort environment worsen. (4) Compared to the logic control of the pressure protection valve, keeping the pressure protection valve closed throughout the journey results in smaller internal pressure variations and maximum pressure changes at different time intervals, thereby improving the in-train comfort environment.

Key words: long tunnels with steep slopes, tunnel groups, internal and external pressure, pressure comfort environment, real-train test

杜权, 杜迎春, 杨瑞, 魏康, 万有财, 梅元贵. 大坡道长大隧道及隧道群环境下高速列车车内外压力波特性的实车试验研究[J]. 隧道建设, 2024, 44(7): 1454-1464.

DU Quan, DU Yingchun, YANG Rui, WEI Kang, WAN Youcai, MEI Yuangui.

Full-Scale Test on Internal and External Pressure Wave Characteristics of High-Speed Trains in Long, Steep Tunnels and Tunnel Group Environments [J]. Tunnel Construction, 2024, 44(7): 1454-1464.

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大坡道长大隧道及隧道群环境下高速列车车内外压力波特性的实车试验研究

Full-Scale Test on Internal and External Pressure Wave Characteristics of High-Speed Trains in Long, Steep Tunnels and Tunnel Group Environments

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