Assessment of the Simultaneous Use of Asphalt Concrete and Foam Concrete as a Full Cross-Section Layer in the Substructure of the China Railway Track System (CRTS) III Slab Ballastless Tracks

IF 1.6 4区工程技术 Q3 ENGINEERING, CIVIL

Transportation Research Record Pub Date : 2023-10-27 DOI:10.1177/03611981231200204

Thanut Klomranok, Qian Su

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引用次数: 0

Abstract

This paper proposes the simultaneous application of asphalt concrete (AC) and foam concrete (FC) as a full cross-section layer in the substructure of the high-speed railway ballastless track. AC is designed as a waterproof layer and is placed as part of the top surface layer of the subgrade bed where the mixture is made from three types of performance grade (PG) binders (normal, high, and modified grade binders) named PG64-22, PG70-22, and PG76-22, respectively. FC is designed as a subgrade material to replace the traditional material in the bottom layer of the subgrade bed. It has a target density of 500–700 kg/m 3 and polypropylene (PP) fiber is added at a ratio of 0.25% and 0.40% by volume. The mechanical properties of both materials are reviewed from the authors’ previous research, in which they were assessed through laboratory testing in accordance with ASTM standards. In addition, the numerical model analyzed the dynamic response of the whole structure when AC and FC were applied as full cross-section layers under different thicknesses of FC and then compared with traditional track structures. Laboratory test results indicate that PG76-22, or modified asphalt binder and FC at a density of 600 kg/m 3 with the addition of 0.25% PP fiber, is suitable for use in slab ballastless tracks. In addition, the prediction of the model shows that AC at a thickness of 0.12 m and FC at a thickness of 1.00 m can reduce the stress and vibration of the track structure better than the traditional structure, resulting in stabilization and long-term service life.

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沥青混凝土和泡沫混凝土同时作为全截面层在中国铁路轨道系统(CRTS) III板无碴轨道下部结构中的应用评价

提出了沥青混凝土与泡沫混凝土同时作为全截面层应用于高速铁路无砟轨道下部结构的方案。AC被设计为防水层，放置在路基床的上表层，其中混合料由三种性能等级(PG)粘结剂(分别为PG64-22、PG70-22和PG76-22)制成。FC被设计为一种路基材料，以取代传统材料在路基床的底层。它的目标密度为500-700 kg/ m3，聚丙烯纤维的添加比例为0.25%和0.40%(体积比)。这两种材料的机械性能从作者以前的研究中进行了回顾，根据ASTM标准通过实验室测试对它们进行了评估。此外，该数值模型还分析了在不同FC厚度下，AC和FC作为全截面层时整个结构的动力响应，并与传统轨道结构进行了比较。室内试验结果表明，PG76-22，即添加0.25% PP纤维，密度为600 kg/ m3的改性沥青粘结剂和FC，适用于板式无砟轨道。此外，模型预测表明，0.12 m厚度的AC和1.00 m厚度的FC比传统结构能更好地降低轨道结构的应力和振动，从而实现稳定和长期使用寿命。

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

Transportation Research Record 工程技术-工程：土木

CiteScore

3.20

自引率

11.80%

发文量

918

审稿时长

4.2 months

期刊介绍： Transportation Research Record: Journal of the Transportation Research Board is one of the most cited and prolific transportation journals in the world, offering unparalleled depth and breadth in the coverage of transportation-related topics. The TRR publishes approximately 70 issues annually of outstanding, peer-reviewed papers presenting research findings in policy, planning, administration, economics and financing, operations, construction, design, maintenance, safety, and more, for all modes of transportation. This site provides electronic access to a full compilation of papers since the 1996 series.