磁悬浮列车外形及制式对管道激波流场的影响分析

doi:10.3901/JME.2025.10.386

摘要/Abstract

摘要： 空气已经成为高速列车进一步提速的关键制约因素之一，高速运行导致列车能耗及环境噪声危害性剧增。为了发展下一代更高速交通运输系统，低真空管道和高速磁浮列车结合的交通运输系统构想得以提出和发展。低真空管道列车超高速运行导致管道内产生激波效应等特殊流动现象，高速列车诱发的长大管道内激波演化机制、列车外形及制式等参数对管道列车激波流场的影响机理等关键科学和工程问题有待探明。通过分析列车周围流场特征、三维管道列车激波结构、管道内侧壁面压力及系数、车体表面压力及系数、车体表面温度、列车气动阻力及系数等，探索不同外形及制式对管道列车激波特性及表征的列车阻力系数和其他空间物理量的影响，得出列车外形影响激波产生位置、形状长度、反射位置、激波空间曲线及相交线等激波特性，进而影响列车气动阻力系数及其他空间流场物理量。在管道列车激波流场的影响下，列车长度一致，随着车头流线型长度的增加，列车气动阻力系数、车体表面压力系数和车体表面温度等随之减小；同时，相比较外形的影响，轨道交通运营制式的影响较弱。

关键词: 磁悬浮列车, 外形, 制式, 管道列车, 激波流场

Abstract: Aerodynamic effect has become one of the key restrictive factors for the further speed increase of high-speed trains, and high-speed operation has led to a sharp increase in energy consumption and environmental noise hazards. In order to develop the next generation of higher-speed transportation systems, the concept of a transportation system combining low-vacuum pipelines and high-speed maglev trains has been proposed and developed. However, some specific flow phenomena including the shock wave effect appear as the high speed train passing through the low-vacuum pipeline at an ultra-high speed. Scientific and engineering issues such as the shock wave evolution mechanism in long pipelines, the influence of the train shape, the system mode and other parameters on the shock wave flow field of pipeline trains need to be explored. By analyzing the characteristics of the flow field around the train, the three-dimensional shock wave structure, the pressure on the internal pipeline wall and the train surface, the surface temperature and aerodynamic resistance of the train, the effect of different shapes and system modes on the shock wave, the aerodynamic resistance and other physical variables is explored. Results show that the train shape and the system mode have significant influence on the generation position, shape length, reflection position, special curve and intersecting line of the shock wave, meanwhile affect the train aerodynamic drag and other physical variables. When the length of the train is identical, the aerodynamic drag coefficient, the surface pressure coefficient and the surface temperature of the train decrease with the increase of the streamlined length of the train nose under the effect of shock waves inside the pipe. However, the influence of the rail transit system mode is relatively slight comparing with the parameter of train shape.

Key words: maglev train, shape, system mode, pipeline train, shock wave field

中图分类号:

U171

黄尊地, 周镇斌, 常宁. 磁悬浮列车外形及制式对管道激波流场的影响分析[J]. 机械工程学报, 2025, 61(10): 386-394.

HUANG Zundi, ZHOU Zhenbin, CHANG Ning. Analysis on the Shock Wave Field of Maglev Train Shape and Model in Tube[J]. Journal of Mechanical Engineering, 2025, 61(10): 386-394.

参考文献

[1] 沈志云. 关于我国发展真空管道高速交通的思考[J]. 西南交通大学学报，2005，40(2)：133-137. SHEN Zhiyun. On developing high-speed evacuated tube transportation in China[J]. Journal of Southwest Jiaotong University，2005，40(2)：133-137.
[2] 冯仲伟，方兴，李红梅，等. 低真空管道高速磁悬浮系统技术发展研究[J]. 中国工程科学，2018，20(6)：105-111. FENG Zhongwei，FANG Xing，LI Hongmei，et al. Technological development of high speed maglev system based on low vacuum pipeline[J]. Strategic Study of CAE，2018，20(6)：105-111.
[3] 徐飞，罗世辉，邓自刚. 磁悬浮轨道交通关键技术及全速度域应用研究[J]. 铁道学报，2019，41(3)：40-49. XU Fei，LUO Shihui，DENG Zigang. Study on key technologies and whole speed range application of maglev rail transport[J]. Journal of the China Railway Society，2019，41(3)：40-49.
[4] 熊嘉阳，邓自刚. 高速磁悬浮轨道交通研究进展[J]. 交通运输工程学报，2021，21(1)：177-198. XIONG Jiayang，DENG Zigang. Research progress of high-speed maglev rail transit[J]. Journal of Traffic and Transportation Engineering，2021，21(1)：177-198.
[5] 刘加利，张继业，张卫华. 真空管道高速列车气动特性分析[J]. 机械工程学报，2013，49(22)：137-143. LIU Jiali，ZHANG Jiye，ZHANG Weihua. Analysis of aerodynamic characteristics of high-speed trains in the evacuated tube[J]. Journal of Mechanical Engineering，2013，49(22)：137-143.
[6] 黄尊地，梁习锋，常宁．真空管道交通列车外流场仿真算法分析[J]. 工程热物理学报，2018，39(6)：1244-1250． HUANG Zundi，LIANG Xifeng，CHANG Ning. Analysis on simulation algorithm for train outflow field of vacuum pipeline traffic[J]. Journal of Engineering Thermophysics，2018，39(6)：1244-1250.
[7] BI H，LEI B. Aerodynamic characteristics of evacuated tube high-speed train[J]. International Conference on Transportation Engineering，2009：3736-3741.
[8] 米百刚，詹浩，朱军. 基于动网格的真空管道高速列车阻力计算方法研究[J]. 真空科学与技术学报，2013，33(9)：877-882. MI Baigang，ZHAN Hao，ZHU Jun. Simulation of aerodynamic drag of high-speed train in evacuated tube transportation[J]. Journal of Vacuum Science and Technology，2013，33(9)：877-882.
[9] 周晓，张殿业，张耀平. 真空管道中阻塞比对列车空气阻力影响的数值研究[J]. 真空科学与技术学报，2008，26(6)：535-538. ZHOU Xiao，ZHANG Dianye，ZHANG Yaoping. Numerical simulation of blockage rate and aerodynamic drag of high-speed train in evacuated tube transportation[J]. Journal of Vacuum Science and Technology，2008，26(6)：535-538.
[10] 贾文广，董晨光，周艳，等. 基于阻塞比的真空管道交通系统热压耦合研究[J]. 工程热物理学报，2013，34(9)：1745-1748. JIA Wenguang，DONG Chenguang，ZHOU Yan，et al. Study of thermal-pressure coupling effect in the evacuated tube transpotation system on blocking ratio[J]. Journal of Engineering Thermophysics，2013，34(9)：1745-1748.
[11] 汤兆平，孙剑萍，吴灵波. 真空管道运输系统的空气动力学分析及优化设计[J]. 机床与液压，2014，42(21)：164-168. TANG Zhaoping，SUN Jianping，WU Lingbo. Aerodynamic analysis and optimization design of ETT[J]. Machine Tool & Hydraulics，2014，42(21)：164-168.
[12] 刘加利，张继业，张卫华. 真空管道高速列车气动阻力及系统参数设计[J]. 真空科学与技术学报，2014，34(1)：10-15. LIU Jiali，ZHANG Jiye，ZHANG Weihua. Impacts of pressure，blockage-ratio and speed on aerodynamic drag-force of high-speed trains[J]. Journal of Vacuum Science and Technology，2014，34(1)：10-15.
[13] 黄尊地，梁习锋，常宁．真空管道交通列车气动阻力数值分析[J]. 机械工程学报，2019，55(8)：165-172. HUANG Zundi，LIANG Xifeng，CHANG Ning. Numerical analysis of train aerodynamic drag of vacuum tube traffic[J]. Journal of Mechanical Engineering，2019，55(8)：165-172.
[14] KIM T K，KIM K H，KWON H B. Aerodynamic characteristics of a tube train[J]. Journal of Wind Engineering and Industrial Aerodynamics，2011，99：1187-1196.
[15] DONG-WOOK K，TAE-HO K，HEUY-DONG K. A study on characteristics of shock train inside a shock tube[J]. Theoretical and Applied Mechanics Letters，2017，7：366-371.
[16] ZHOU Peng，ZHANG Jiye，LI Tian，et al. Numerical study on wave phenomena produced by the super high-speed evacuated tube maglev train[J]. Journal of Wind Engineering and Industrial Aerodynamics，2019，190：61-70.
[17] ZHOU Peng，ZHANG Jiye. Aerothermal mechanisms induced by the super high-speed evacuated tube maglev train[J]. Vacuum，2020，173：1-9.
[18] NIU Jiqiang，SUI Yang，YU Qiujun，et al. Numerical study on the impact of Mach number on the coupling effect of aerodynamic heating and aerodynamic pressure caused by a tube train[J]. Journal of Wind Engineering and Industrial Aerodynamics，2019，190：100-111.
[19] 黄尊地，伊严严，常宁. 超声速运行时管道列车激波特性分析[J]. 真空，2022，59(5)：55-62. HUANG Zundi，YI Yanyan，CHANG Ning. Analysis on shock wave characteristics of supersonic train running in tube[J]. Vacuum，2022，59(5)：55-62.