弹药包装铁路高速运输力学环境仿真分析

杨清熙; 王博; 陈星洲; 姚恺; 戚壮; 李渤

doi:10.7643/issn.1672-9242.2025.06.002

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装备环境工程 ›› 2025, Vol. 22 ›› Issue (6) : 12-19. DOI: 10.7643/issn.1672-9242.2025.06.002

武器装备

弹药包装铁路高速运输力学环境仿真分析

杨清熙¹, 王博^1,*, 陈星洲¹, 姚恺¹, 戚壮², 李渤²

作者信息 +

Simulation Analysis of Mechanical Environment for High-speed Transportation of Ammunition Packing Railway

YANG Qingxi¹, WANG Bo^1,*, CHEN Xingzhou¹, YAO Kai¹, QI Zhuang², LI Bo²

Author information +

文章历史 +

摘要

目的分析弹药在铁路高速运输力学环境中的安全问题。方法构建动车、典型弹药包装箱装载模型,对不同位置典型弹药包装在高速铁路运输时的振动、加减速、离心力等力学环境进行仿真分析。结果在京津谱轨道不平顺激励下,满载高速列车在350 km/h匀速、加速、减速、通过曲线时,车厢内部典型弹药的横向、垂向、纵向振动加速度均小于2.1 m/s²,包装箱位移均小于0.057 mm。结论弹药在铁路高速运输力学环境下,弹药包装堆码稳固,不会出现摔箱倒垛问题,加速度小于弹药敏感元件加速度阈值,运输安全。

Abstract

The work aims to analyze the mechanical environmental safety of ammunition in high-speed railway transportation. By constructing the loading model of bullet train and typical ammunition packing box, the vibration, acceleration and deceleration, centrifugal force and other mechanical environment of typical ammunition packing in different locations during high-speed railway transportation were simulated and analyzed. The transverse/vertical/longitudinal vibration acceleration of typical ammunition was less than 2.1 m/s² and the displacement of packing box was less than 0.057 mm when the high-speed train was fully loaded at 350 km/h at constant speed, accelerating, decelerating and passing the curve. In the mechanical environment of high-speed railway transportation, the ammunition packing and stacking are stable, and the problem of falling boxes and stacking will not occur, and the acceleration is less than the acceleration threshold of ammunition sensitive elements, so the transportation is safe.

导出引用

杨清熙, 王博, 陈星洲, 姚恺, 戚壮, 李渤. 弹药包装铁路高速运输力学环境仿真分析[J]. 装备环境工程. 2025, 22(6): 12-19 https://doi.org/10.7643/issn.1672-9242.2025.06.002

YANG Qingxi, WANG Bo, CHEN Xingzhou, YAO Kai, QI Zhuang, LI Bo. Simulation Analysis of Mechanical Environment for High-speed Transportation of Ammunition Packing Railway[J]. Equipment Environmental Engineering. 2025, 22(6): 12-19 https://doi.org/10.7643/issn.1672-9242.2025.06.002

中图分类号： TJ410.89

参考文献

[1] 朱曦, 姚恺, 郭爱强, 等. 基于多目标的弹药储备与调运联合优化[J]. 陆军工程大学学报, 2024, 3(6): 46-53.
ZHU X, YAO K, GUO A Q, et al.Mult I-Objective Joint Optimization of Ammunition Reserve and Scheduling[J]. Journal of Army Engineering University of PLA, 2024, 3(6): 46-53.
[2] 冯芊力, 史宪铭, 邱雄飞, 等. 基于系统动力学模型的战时弹药储备量优化分析[J]. 现代防御技术, 2024, 52(5): 173-181.
FENG Q L, SHI X M, QIU X F, et al.Optimization Analysis of Ammunition Reserve Quantity in Wartime Based on System Dynamics Model[J]. Modern Defence Technology, 2024, 52(5): 173-181.
[3] 刘昊邦, 史宪铭, 华斌, 等. 基于DoDAF的弹药供应保障体系构建与效能评估[J]. 兵器装备工程学报, 2023, 44(1): 80-85.
LIU H B, SHI X M, HUA B, et al.Construction and Effectiveness Evaluation of the Ammunition Supply Guarantee System Based on DoDAF[J]. Journal of Ordnance Equipment Engineering, 2023, 44(1): 80-85.
[4] 帅元, 徐辉, 孙奇龙. 陆军合成部队战时弹药供应保障效能评估分析[J]. 装甲兵学报, 2022, 1(5): 70-73.
SHUAI Y, XU H, SUN Q L.Effectiveness Evaluation and Analysis of Ammunition Supply Support for Army Combined Forces in Wartime[J]. Journal of Armored Forces, 2022, 1(5): 70-73.
[5] 杨永伟, 张静, 王清晨. 弹药包装箱铁路运输试验问题及对策[J]. 包装工程, 2019, 40(7): 246-249.
YANG Y W, ZHANG J, WANG Q C.Problems and Countermeasures of Railway Transport Test for Ammunition Packing Boxes[J]. Packaging Engineering, 2019, 40(7): 246-249.
[6] 於崇铭, 任风云, 田丰. 航空弹药铁路运输振动响应模型及影响因素分析[J]. 兵器装备工程学报, 2017, 38(11): 151-154.
YU C M, REN F Y, TIAN F.Aviation Ammunition Vibration Response Model and Influence Factors Analysis of Railway Transportation[J]. Journal of Ordnance Equipment Engineering, 2017, 38(11): 151-154.
[7] 鲍平鑫. 铁路军事运输[M]. 北京: 解放军出版社, 2007.
BAO P X.Railway Military Transport[M]. Beijing: People's Liberation Army Publishing Hous, 2007.
[8] 伍杰源, 马波涛, 杨华峰, 等. 400km/h高速铁路发展模式及影响因素研究[J]. 铁道经济研究, 2024(6): 42-46.
WU J Y, MA B T, YANG H F, et al.Development Mode and Influencing Factors of 400km/h High Speed Railway[J]. Railway Economics Research, 2024(6): 42-46.
[9] 王梦漪, 封宁. 高速铁路发展及标准体系浅析[J]. 轨道交通装备与技术, 2024(6): 61-64.
WANG M Y, FENG N.Analysis of High-Speed Railway Development and Standard System[J]. Rail Transportation Equipment and Technology, 2024(6): 61-64.
[10] 陈晔, 钱勇生, 曾俊伟, 等. 高速铁路网络协同发展对城市群空间重构的分形研究[J]. 铁道运输与经济, 2024, 46(4): 119-127.
CHEN Y, QIAN Y S, ZENG J W, et al.Fractal Study on Spatial Reconstruction of Urban Agglomerations under the Coordinated Development of High Speed Railway Networks[J]. Railway Transport and Economy, 2024, 46(4): 119-127.
[11] 赵云豪, 王清晨, 周佳佳. 大尺寸弹药铁路快速投送仿真实验[J]. 军事交通学院学报, 2018(6): 1-4.
ZHAO Y H, WANG Q C, ZHOU J J.Simulation Experiment of Large-Size Ammunition Moved by Railway[J]. Journal of Military Transportation University, 2018(6): 1-4.
[12] 母东, 向聪, 刘勇, 等. 特种方舱铁路运输异常调车纵向冲击试验研究[J]. 装备环境工程, 2021, 18(5): 100-105.
MU D, XIANG C, LIU Y, et al.Experimental Research on the Longitudinal Impact of the Special Container under Shunting Accident[J]. Equipment Environmental Engineering, 2021, 18(5): 100-105.
[13] 杨永伟, 张瑞鹏, 吴东广. 弹药铁路棚车运输装载加固方案[J]. 军事交通学院学报, 2016(3): 19-22.
YANG Y W, ZHANG R P, WU D G.Loading Reinforcement Scheme for Ammunition Railway Transportation with Boxcar[J]. Journal of Military Transportation University, 2016(3): 19-22.
[14] 刘跃龙, 安振涛, 李天鹏, 等. 弹药包装运输动力学研究现状[J]. 包装工程, 2017, 38(23): 121-127.
LIU Y L, AN Z T, LI T P, et al.The Research Status of the Transportation Dynamics of Ammunition Packaging[J]. Packaging Engineering, 2017, 38(23): 121-127.
[15] 蒋超, 鲍平鑫, 辛海, 等. 铁路电磁环境对特种弹药运输安全的影响与对策[J]. 军事交通学院学报, 2015(10): 10-13.
JIANG C, BAO P X, XIN H, et al.Impact of Railway Electromagnetic Environment on Special Ammunition Transportation Safety and Countermeasures[J]. Journal of Military Transportation University, 2015(10): 10-13.
[16] 於崇铭, 任风云. 弹药铁路运输垂向振动特性研究[C]//OSEC首届兵器工程大会论文集. 重庆: 空军勤务学院, 2017.
YU C M, REN F Y.Research on Vertical Vibration Characteristics of Ammunition Railway Transportation[C]//Proceedings of the First OSEC Weapon Engineering Conference. Chongqing: Air Force Service Academy, 2017.
[17] 於崇铭, 任风云, 田丰. 基于振动传递率的弹药铁路运输模型建立方法[C]//OSEC首届兵器工程大会论文集. 重庆: 空军勤务学院, 2017.
YU C M, REN F Y, TIAN F.Method for Establishing a Railway Transportation Model for Ammunition Based on Vibration Transmission Rate[C]//Proceedings of the First OSEC Weapon Engineering Conference. Chongqing: Air Force Service Academy, 2017.
[18] 宋豪文, 贾红丽, 王亚彬, 等. 通用弹药铁路运输风险影响因素分析[J]. 军事交通学报, 2022, 1(12): 6-12.
SONG H W, JIA H L, WANG Y B, et al.Analysis on Risk Factors of Railway Transportation of General Ammunition[J]. Journal of Military Transportation, 2022, 1(12): 6-12.
[19] 姚恺, 高欣宝, 吴雪艳, 等. 高速铁路开展弹药快速运输研究的总体构想[J]. 军事交通学院学报, 2016(3): 15-18.
YAO K, GAO X B, WU X Y, et al.Overall Conception of Ammunition Rapid Transportation with High-Speed Railway[J]. Journal of Military Transportation University, 2016(3): 15-18.
[20] 孙辉艺, 戴焕云. 某动车转向架构架静强度分析[J]. 机械制造与自动化, 2023, 52(5): 96-99.
SUN H Y, DAI H Y.Static Strength Analysis of Bogie Frame of EMU[J]. Machine Building & Automation, 2023, 52(5): 96-99.
[21] 王东镇, 葛剑敏. 高速列车运行时不同转向架区噪声特性[J]. 交通运输工程学报, 2020, 20(4): 174-183.
WANG D Z, GE J M.Noise Characteristics in Different Bogie Areas during High-Speed Train Operation[J]. Journal of Traffic and Transportation Engineering, 2020, 20(4): 174-183.
[22] 单勇. 动力集中动车组动力车车体结构与强度设计[J]. 电力机车与城轨车辆, 2025, 48(1): 55-60.
SHAN Y.Design of Body Structure and Strength for the Power Vehicle of Power Concentrated EMUs[J]. Electric Locomotives & Mass Transit Vehicles, 2025, 48(1): 55-60.
[23] 段华东, 樊运新, 金希红, 等. 符合TSI标准的双层动车组耐撞安全仿真研究[J]. 电力机车与城轨车辆, 2024, 47(6): 79-85.
DUAN H D, FAN Y X, JIN X H, et al.Crashworthiness Safety Simulation Study on Double-Deck EMU Conforming to TSI Standard[J]. Electric Locomotives & Mass Transit Vehicles, 2024, 47(6): 79-85.
[24] 张奕婕, 殷梓健. CRH3型动车组牵引传动系统建模仿真研究[J]. 铁道机车与动车, 2024(8): 11-15.
ZHANG Y J, YIN Z J.Research on Modeling and Simulation of Traction Transmission System for CRH3 EMUs[J]. Railway Locomotive and Motor Car, 2024(8): 11-15.