Shaking table study on high-speed train seismic derailment mechanism and verification of spectrum intensity derailment index

IF 4.3 2区 工程技术 Q1 ENGINEERING, CIVIL Earthquake Engineering & Structural Dynamics Pub Date : 2024-06-10 DOI:10.1002/eqe.4174
Yang Wang, Wei Guo, Chen Zeng, Renqiang Huang, Shun Yang, Yutao Nie, Lizhong Jiang, Zhiwu Yu
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Abstract

The derailment of a high-speed train is a complex and uncertain dynamic process, especially under running conditions where the derailment index lacks comprehensive experimental validation. This research focuses on elucidating the mechanism of an earthquake-induced train derailment and validating the structural response-based spectrum intensity derailment index. To achieve this, a multi-array shaking table system was utilized to test the safety of a running train and to physically replicate train derailment process under severe earthquake impact. We investigated the vibration characteristics and derailment progression of trains operating at different speeds, exposed to earthquakes of varying frequencies and intensities. In stationary derailments, significant wheelset lift was observed due to lateral rolling vibrations. However, in running test cases, there was no separation between the wheels and rails. Instead, the wheels underwent a long period of climbing and descending on the rails, similar to damped single-degree-of-freedom oscillations. As the wheel climbed the rail and reached a critical potential energy point, the wheel flange of the wheel could potentially fall due to gravity or come off the rail due to external disturbances. The critical potential energy could be represented by the spectrum intensity threshold, and the prediction results aligned well with the derailment test results for both stationary and running trains. Furthermore, the method of determining train derailment based on structural responses was consistent with the test results. The spectrum intensity index shows strong positive correlations with other wheel-force-related indicators, albeit adopting a conservative perspective, reinforcing its efficacy in assessing train safety.

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高速列车地震脱轨机理振动台研究及频谱强度脱轨指数验证
高速列车脱轨是一个复杂且不确定的动态过程,尤其是在运行条件下,脱轨指数缺乏全面的实验验证。本研究的重点是阐明地震诱发列车脱轨的机理,并验证基于结构响应的频谱强度脱轨指数。为此,我们利用多阵列振动台系统对运行中的列车进行了安全测试,并实际复制了列车在强烈地震冲击下的脱轨过程。我们研究了在不同频率和强度的地震中,以不同速度运行的列车的振动特性和脱轨过程。在静止脱轨中,由于横向滚动振动,观察到明显的轮对抬升。然而,在运行测试案例中,车轮和钢轨之间没有发生分离。相反,车轮在轨道上经历了长时间的爬升和下降,类似于阻尼单自由度振荡。当车轮爬上轨道并达到临界势能点时,车轮的轮缘有可能因重力而下降,或因外部干扰而脱离轨道。临界势能可以用频谱强度阈值来表示,预测结果与静止和运行列车的脱轨测试结果非常吻合。此外,根据结构响应确定列车脱轨的方法也与测试结果一致。频谱强度指数与其他与车轮力相关的指标显示出很强的正相关性,尽管采用的是保守的观点,这加强了频谱强度指数在评估列车安全方面的功效。
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来源期刊
Earthquake Engineering & Structural Dynamics
Earthquake Engineering & Structural Dynamics 工程技术-工程:地质
CiteScore
7.20
自引率
13.30%
发文量
180
审稿时长
4.8 months
期刊介绍: Earthquake Engineering and Structural Dynamics provides a forum for the publication of papers on several aspects of engineering related to earthquakes. The problems in this field, and their solutions, are international in character and require knowledge of several traditional disciplines; the Journal will reflect this. Papers that may be relevant but do not emphasize earthquake engineering and related structural dynamics are not suitable for the Journal. Relevant topics include the following: ground motions for analysis and design geotechnical earthquake engineering probabilistic and deterministic methods of dynamic analysis experimental behaviour of structures seismic protective systems system identification risk assessment seismic code requirements methods for earthquake-resistant design and retrofit of structures.
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