Dynamic Response of Full-Section Asphalt Concrete Waterproof Layer on Ballastless Tracks Employing Fractional-Order Modeling

IF 11.6 1区工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY

Engineering Pub Date : 2025-10-15 DOI:10.1016/j.eng.2025.10.001

Gang Xu, You Wu, Wei Huang, Yuefeng Shi, Tianling Wang, Degou Cai, Jinghong Tan, Xianhua Chen

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引用次数: 0

Abstract

The full-section asphalt concrete waterproof layer (FACWL) has garnered significant attention for its outstanding ability to reduce frost heave and thaw-related weakening in railway track beds, particularly in seasonally frozen regions. To explore the dynamic properties of the FACWL, a fractional-order constitutive model was utilized to characterize the viscoelastic behavior of asphalt concrete. Additionally, a vehicle–track coupled finite element (FE) model and the numerical approach incorporating the fractional-order constitutive model were developed and validated via experimental and field testing. Simulation results indicate that applying the FACWL reduces the vertical dynamic response of each structural layer, vertical peak accelerations across the subgrade surface layer exhibited reductions exceeding 30% in both positive and negative directions. Moreover, the tensile strain at the bottom of the FACWL remained relatively low, less than 100 με. Compared with conventional waterproof sealing layers, the viscoelastic nature of the FACWL facilitates energy dissipation, effectively decreasing the overall vibrational amplitude and vertical deformation within the track structure by more than 20%. Consequently, the FACWL plays a crucial role in ensuring the long-term stability of the subgrade and minimizing vibrations in the track system.

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无砟轨道全截面沥青混凝土防水层动力响应的分数阶建模

全截面沥青混凝土防水层（FACWL）因其在减少铁路路基冻胀和融化相关弱化方面的突出能力而受到广泛关注，特别是在季节性冻结地区。为了探讨FACWL的动力特性，采用分数阶本构模型表征沥青混凝土的粘弹性行为。此外，建立了车辆-轨道耦合有限元模型和包含分数阶本构模型的数值方法，并通过试验和现场测试进行了验证。模拟结果表明，应用FACWL降低了各结构层的垂直动力响应，路基表面层垂直峰值加速度在正负方向上都降低了30%以上。此外，FACWL底部的拉伸应变相对较低，小于100 με。与常规防水密封层相比，FACWL的粘弹性有利于消能，有效降低轨道结构整体振动幅值和垂直变形20%以上。因此，FACWL在确保路基的长期稳定性和减少轨道系统的振动方面起着至关重要的作用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Engineering Environmental Science-Environmental Engineering

自引率

1.60%

发文量

335

审稿时长

35 days

期刊介绍： Engineering, an international open-access journal initiated by the Chinese Academy of Engineering (CAE) in 2015, serves as a distinguished platform for disseminating cutting-edge advancements in engineering R&D, sharing major research outputs, and highlighting key achievements worldwide. The journal's objectives encompass reporting progress in engineering science, fostering discussions on hot topics, addressing areas of interest, challenges, and prospects in engineering development, while considering human and environmental well-being and ethics in engineering. It aims to inspire breakthroughs and innovations with profound economic and social significance, propelling them to advanced international standards and transforming them into a new productive force. Ultimately, this endeavor seeks to bring about positive changes globally, benefit humanity, and shape a new future.