弓网摩擦力影响因素试验研究

doi:10.16265/j.cnki.issn1003-3033.2025.S1.0025

摘要/Abstract

摘要：

为保障电气化铁路中接触网与受电弓之间的有效接触,进而保障列车运行的安全与稳定,提出在载流条件下对弓网摩擦接触特性开展系统性研究的思路与方法。首先,基于滑动电接触试验平台,开展不同工况下(涵盖压力波动幅度、压力波动频率、接触电流和滑动速度)弓网滑动电接触摩擦力试验;然后,结合试验数据,筛选出能够分别表征压力波动幅度、接触电流和滑动速度影响的单因素数学模型,模型构建方法采用曲线估计,具备较高的拟合精度;最后,通过多元回归分析,建立一个综合考虑压力波动载荷与接触电流共同作用的弓网摩擦力预测模型,并通过对比试验数据验证模型的可靠性与适用性。试验结果表明:弓网间滑动摩擦力随接触电流的增大呈递减趋势;而压力波动幅度和滑行速度的提高,会造成摩擦力增大;相比之下,压力波动频率对弓网摩擦力的影响较为微弱。

关键词: 压力波动, 接触电流, 曲线估计, 多元回归, 弓网摩擦力

Abstract:

To ensure the effective contact between the contact line and the pantograph in electrified railways and thereby guarantee the safety and stability of train operation, the ideas and methods for conducting a systematic study on the frictional contact characteristics of the contact line and the pantograph under current-carrying conditions were proposed. Firstly, based on the sliding electrical contact test platform, experiments on the sliding electrical contact friction force between the pantograph and the contact line were conducted under different working conditions (covering pressure fluctuation amplitude, pressure fluctuation frequency, contact current, and sliding speed). Then, based on the experimental data, single-factor mathematical models that could respectively represent the influence of pressure fluctuation amplitude, contact current, and sliding speed were selected. The model construction method adopted curve estimation, and it had a relatively high fitting accuracy. Finally, through multiple regression analysis, a prediction model for contract line-pantograph friction force that comprehensively considered the combined effect of pressure fluctuation loads and contact current was established. The reliability and applicability of the model were verified through comparative test data. The test results show that the sliding friction force between the pantograph and the contact line decreases as the contact current increases, while the increase in pressure fluctuation amplitude and sliding speed will lead to an increase in friction force. In contrast, the influence of pressure fluctuation frequency on the contract line-pantograph friction force is relatively weak.

Key words: pressure fluctuation, contact current, curve estimation, multiple regression, contract line-pantograph friction force

中图分类号:

X936

杨泽斌. 弓网摩擦力影响因素试验研究[J]. 中国安全科学学报, 2025, 35(S1): 166-172.

YANG Zebin. Experimental study on influencing factors of contract line-pantograph friction force[J]. China Safety Science Journal, 2025, 35(S1): 166-172.

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参考文献 16

[1]	肇晓楠, 谢新连, 赵瑞嘉. 基于滑动窗口动态输入LSTM网络的铁路运输系统碳排放量预测方法[J]. 交通信息与安全, 2023, 41(1):169-178.
	ZHAO Xiaonan, XIE Xinlian, ZHAO Ruijia. A method for predicting carbon emission of railway transportation system based on an LSTM network with dynamic input via sliding window[J]. Journal of Transport Information and Safety, 2023, 41(1):169-178.
[2]	祁云, 薛凯隆, 汪伟, 等. 矿井煤与瓦斯突出事故应急救援能力评估模型[J]. 中国安全科学学报, 2024, 34(2):225-230. doi: 10.16265/j.cnki.issn1003-3033.2024.02.0983
	QI Yun, XUE Kailong, WANG Wei, et al. Assessment model of emergency response capability for coal and gas outburst accidents in mines[J]. China Safety Science Journal, 2024, 34(2):225-230. doi: 10.16265/j.cnki.issn1003-3033.2024.02.0983
[3]	祁云, 薛凯隆, 李绪萍, 等. 多策略改进SSA优化KELM的边坡稳定性预测模型[J]. 中国安全科学学报, 2025, 35(3):92-98. doi: 10.16265/j.cnki.issn1003-3033.2025.03.0134
	QI Yun, XUE Kailong, LI Xuping, et al. Slope stability prediction model based on multi-strategy improved SSA for optimizing KELM[J]. China Safety Science Journal, 2025, 35(3):92-98. doi: 10.16265/j.cnki.issn1003-3033.2025.03.0134
[4]	邹士涛. 电力机车受电弓冻雨天气下行车保障措施研究[J]. 铁道机车车辆, 2024, 44(6):131-135.
	ZOU Shitao. Research on safeguard measures for electric locomotive pantograph driving in freezing rain[J]. Railway Locomotive and Car, 2024, 44(6):131-135.
[5]	谢东, 柴铭, 张强, 等. 面向城轨列车智能视觉定位的安全测试方法[J]. 科技导报, 2023, 41(10):73-81. doi: 10.3981/j.issn.1000-7857.2023.10.006
	XIE Dong, CHAI Ming, ZHANG Qiang, et al. Safety testing method for intelligent visual train positioning of urban rail transit[J]. Science and Technology Review, 2023, 41(10):73-81.
[6]	李睿, 王军. 基于接触电阻的GFET高频等效噪声表征与建模[J]. 四川大学学报:自然科学版, 2024, 61(2):133-141.
	LI Rui, WANG Jun. Characterization and modeling of high frequency equivalent noise in GFET based on contact resistance[J]. Journal of Sichuan University:Natural Science Edition, 2024, 61(2):133-141.
[7]	陈忠华, 李铎, 陈明阳, 等. 弓网滑动电接触多目标条件下最优压力载荷决策研究[J]. 高压电器, 2024, 60(12):206-212.
	CHEN Zhonghua, LI Duo, CHEN Mingyang, et al. Study on optimal load decision of sliding contact in the pantograph-catenary system under multi-objective condition[J]. High Voltage Apparatus, 2024, 60(12):206-212.
[8]	任志玲, 郭超, 徐丽霞. QGA-SVM在弓网滑动电接触下的最优载荷研究[J]. 高压电器, 2015, 51(4):133-138.
	REN Zhiling, GUO Chao, XU Lixia. Application of QGA-SVM to load optimization for pantograph-catenary system sliding electrical contact[J]. High Voltage Apparatus, 2015, 51(4): 133-138.
[9]	尹恒虎, 聂宝鑫, 周细应, 等. Te含量对Ag/SnO₂ 尹恒虎, 聂宝鑫, 周细应, 等. Te含量对Ag/SnO₂In₂O₃电接触材料组织及电接触性能的影响[J]. 材料热处理学报, 2024, 45(1):42-52.
	YIN Henghu, NIE Baoxin, ZHOU Xiying, et al. Effect of Te content on microstructure and electrical contact properties of Ag/SnO₂In₂O₃electrical contact materials[J]. Transactions of Materials and Heat Treatment, 2024, 45(1):42-52.
[10]	孙安元, 吴亚平, 陈坤, 等. 瞬时滑动状态下轮轨摩擦系数试验研究[J]. 铁道标准设计, 2018, 62(2):48-52.
	SUN Anyuan, WU Yaping, CHEN Kun, et al. Experimental research on wheel/rail friction coefficient under transient sliding condition[J]. Railway Standard Design, 2018, 62(2):48-52.
[11]	回立川, 昝丽智, 李瑶, 等. 基于IDBO-DELM的滑动电接触失效诊断[J/OL]. 控制工程,1-13[2025-03-15].https://doi.org/10.14107/j.cnki.kzgc.20240020.
	HUI Lichuan, ZAN Lizhi, LI Yao, et al. Sliding electrical contact failure diagnosis based on IDBO-DELM[J/OL]. Control Engineering of Chine,1-13[2025-03-15].https://doi.org/10.14107/j.cnki.kzgc.20240020.
[12]	康丽, 王兴, 刘梓屹, 等. 超高速滑动电接触CuCrZr合金轨道表面磨损机制及电接触性能[J]. 润滑与密封, 2024, 49(5):8-14.
	KANG Li, WANG Xing, LIU Ziyi, et al. Investigation on wear mechanism and electrical contact performance of CuCrZr alloy rail surfaces for high-speed sliding electrical contact[J]. Lubrication Engineering, 2024, 49(5):8-14.
[13]	桂文龙, 续彦芳, 刘汉涛, 等. 基于格子玻尔兹曼方法的共轨系统压力波动抑制研究[J]. 机床与液压, 2021, 49(6):104-107. doi: 10.3969/j.issn.1001-3881.2021.06.022
	GUI Wenlong, XU Yanfang, LIU Hantao, et al. Research on pressure fluctuation suppression of common rail system based on lattice boltzmann method[J]. Machine Tool and Hydraulics, 2021, 49(6):104-107.
[14]	赖奇暐, 巫世晶, 张增磊, 等. 基于AMESim的特高压断路器管道系统压力波动[J]. 中国机械工程, 2015, 26(7):859-863.
	LAI Qiwei, WU Shijing, ZHANG Zenglei, et al. Analysis of pressure fluctuation in UHA breaker hydraulic pipeline based on AMESim[J]. Chine Mechanical Engineering, 2015, 26(7):859-863.
[15]	李炯, 李明广, 陈锦剑, 等. 单井回灌中回灌堵塞与回灌压力波动对渗流场影响的理论研究[J]. 岩土工程学报, 2019, 41(增2):226-229,234.
	LI Jiong, LI Mingguang, CHEN Jinjian, et al. Theoretical study on influence of well clogging and variable injection pressure on seepage field induced by single-well recharge[J]. Chinese Journal of Geotechnical Engineering, 2019, 41(S2):226-229,234.
[16]	刘鑫屏, 孟令虎. 大型煤粉锅炉炉膛压力波动特性分析[J]. 热力发电, 2019, 48(4):77-83.
	LIU Xinping, MENG Linghu. Fluctuation characteristics of furnace pressure in large-scale pulverized coal boiler[J]. Thermal Power Generation, 2019, 48(4):77-83.

模型名称	模型表达式	R	R²	显著性
一次线性函数型	y=b₀+b₁t	0.979 5	0.959 4	47.298 6
二次曲线函数型	y=b₀+b₁t+b₂t²	0.996 0	0.992 0	248.290 4
倒幂函数型	y=b₀+(b₁/t)	0.836 5	0.699 7	4.660 5
对数曲线型	y=b₀+b₁lnt	0.921 7	0.849 5	11.290 4
增长函数型	y=exp(b₀+b₁t)	0.993 9	0.987 9	57.268 4
幂函数曲线型	y=b₀ ${t}^{{b}_{1}}$	0.937 2	0.878 4	12.908 9
指数曲线型	y=b₀exp(b₁t)	0.986 8	0.973 8	58.755 6

Q/N	试验值/N	模型值/N	R	F
70±10	6.482	6.333	0.965 8	112.475
70±20	6.802	6.950
70±30	7.195	7.299
70±40	7.321	7.381

I/A	试验值/N	模型值/N	R	F
100	5.721	5.779	0.952 5	242.876
150	5.623	5.674
200	5.431	5.485
250	4.976	4.612