考虑冻融循环的GRS墙体性能数值模拟

IF 2.8 2区工程技术 Q2 ENGINEERING, GEOLOGICAL

Geosynthetics International Pub Date : 2023-01-30 DOI:10.1680/jgein.22.00368

Lu-qiang Ding, F. Cui, C. Xiao

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引用次数: 1

摘要

在实践中，由于缺乏相关文献，在土工格栅加筋土(GRS)墙体的设计和分析中，很少直接关注冻融循环。考虑5年环境温度(TR)的变化，采用基于abaqus的数值模型研究了现场GRS墙体的路面垂直变形(s)、面板侧向变形(d)、侧土压力(σh)和土工格栅应变(ε)。数值计算结果表明，在FT循环后，s分布由初始凹形变为凸形，并可分为高变形区、过渡变形区和稳定变形区。FT作用改变了前两个周期内最大d的位置和幅值，使d的分布由j型曲线演变为s型曲线。在冻结过程中，s和d的发展是协调的，可以用统一的模型来描述;σh大于朗肯主动土压力;ε状态取决于d和冻胀力两个因素的相互作用。此外，还讨论了s、d、σh和ε随TR的滞后性，并提出了一些有益的建议，以避免这种FT破坏。

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Numerical simulation on the performance of GRS walls with freeze-thaw cycles consideration

In practice, little attention has been paid directly to freeze-thaw (FT) cycles during the design and analysis of geogrid-reinforced soil (GRS) walls due to lacking relevant literature. This study investigates the pavement vertical deformation (s), panel lateral deformation (d), lateral earth pressure (σh), and geogrid strain (ε) of a field GRS wall using an ABAQUS-based numerical model considering variations of the recorded five-year ambient temperature (TR). Numerical results show that the s distribution follows a convex shape instead of the initial concave shape after FT cycles and can be divided into high, transition, and stable deformation zones. FT action alters both location and amplitude of the maximum d within the first two cycles, making the d distribution evolve from a J-shaped curve into an S-shaped one. During freezing, the developments of s and d are coordinated and can be described using a unified model; σh is larger than the Rankine active earth pressure; ε state depends on the interplay of two factors resulting from d and frost heave force. Furthermore, the hysteresis of s, d,σh, and ε with TR was discussed and several beneficial suggestions were proposed for GRS walls to avoid such FT destruction.

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来源期刊

Geosynthetics International ENGINEERING, GEOLOGICAL-GEOSCIENCES, MULTIDISCIPLINARY

CiteScore

6.90

自引率

20.00%

发文量

审稿时长

>12 weeks

期刊介绍： An online only, rapid publication journal, Geosynthetics International – an official journal of the International Geosynthetics Society (IGS) – publishes the best information on current geosynthetics technology in research, design innovation, new materials and construction practice. Topics covered The whole of geosynthetic materials (including natural fibre products) such as research, behaviour, performance analysis, testing, design, construction methods, case histories and field experience. Geosynthetics International is received by all members of the IGS as part of their membership, and is published in e-only format six times a year.