整体式墙面加筋土桥台承载特性模型试验研究
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作者:
作者单位:

1.防灾科技学院,地质工程学院,河北 廊坊 065201;2.防灾科技学院,廊坊市加筋土结构研发与应用重点实验室,河北 廊坊 065201;3.中国地震灾害防御中心,北京 100029;4.河北工业大学 土木与交通学院,天津 300401;5.盐亭县自然资源局,四川 绵阳 621600

作者简介:

许浩哲(1999- ),男,主要从事岩土地震工程研究,E-mail: xhz19990412@163.com。
XU Haozhe (1999- ), main research interest: geotechnical earthquake engineering, E-mail: xhz19990412@163.com.

通讯作者:

蔡晓光(通信作者),男,教授,博士,E-mail: caixiaoguang123@163.com。

中图分类号:

U443.21

基金项目:

地震科技星火计划(XH204402)


Model experimental study on bearing characteristics of integral-wall geosynthetic reinforced soil abutments
Author:
Affiliation:

1.College of Geological Engineering;2.Langfang Key Laboratory of Research and Application of Geosynthetic Reinforced Soil Structure, Institute of Disaster Prevention, Langfang 065201, Hebei, P. R. China;3.China Earthquake Disaster Prevention Center, Beijing 100029, P. R. China;4.School of Civil and Transportation Engineering, Hebei University of Technology, Tianjin 300401, P. R. China;5.Yanting County Natural Resources Bureau, Mianyang 621600, Sichuan, P. R. China

Fund Project:

The Earthquake Technology Spark Program of China (No. XH204402)

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    摘要:

    整体式墙面加筋土桥台作为一种新的桥台形式,在小跨径桥涵工程中具有较高的推广应用价值。目前对其工作机理的研究尚不深入,特别对桥台承载力特性鲜有研究。以斯洛文尼亚北部Zverovinci桥为原型,基于桥台静载试验技术,开展整体式面板加筋土桥台模型静载试验,分析桥台顶部沉降、面板位移、土体位移、土工格栅应变规律和潜在破裂面形式,并将桥台筋材应力实测值与3种规范推荐的方法计算值进行对比,结果表明:在大荷载作用下,前墙与两翼墙面交界处为结构薄弱环节;最大荷载作用下,桥台的沉降值未超出规范推荐的使用极限及强度极限;桥台中部面板水平位移最大,墙面整体呈中部鼓胀;前、翼墙面板后土体最大位移均发生在模型顶部;筋材最大应变始终在0.50~0.65 m之间,随着面板距离的增大,筋材应变呈线性衰减;在特定荷载作用下,顺桥向筋材应变最大值小于规范值;桥台潜在破裂面呈折线形,下部接近朗肯破裂面,上部为非承载区后沿的破裂面;刚度法计算值与实测筋材应力最大值吻合良好。

    Abstract:

    The geosynthetic reinforced soil integral bridge, as a novel type of abutment, demonstrates significant application value in small-span bridges and culvert engineering. At present, the research on its operational mechanisms is limited, particularly with regard to the bearing capacity characteristics of abutments, which have seldom been studied. Taking the ?erovinci Bridge in northern Slovenia as the prototype and based on abutment static load test technology, this paper carries out static load tests on an integral-wall geosynthetic reinforced soil abutment model. The analysis encompasses the settlement at the top of the abutment, the displacement of the facing panel, the horizontal displacement of the soil behind the facing panel, the distribution of reinforcement strain, and the pattern of the potential failure surface. The measured tensile force of the abutment reinforcement is compared with the calculated values recommended by three codes. The results indicate that under the action of large load, the junction of the front wall and the two wing walls is the weak link of the structure; under the maximum load, the top settlement of the abutment does not exceed the serviceability limit and strength limit recommended by the code. The horizontal displacement of the middle panel of the abutment is the largest, and the wall surface is bulging in the middle as a whole; the maximum soil displacement behind the front and wing wall panels occurs at the top of the model; the maximum strain of the reinforcement is always between 0.5 m and 0.65 m, and the reinforcement strain decreases linearly with the increase of distance away from the panel. Under specific loading conditions, the maximum strain of longitudinal reinforcement remains below the specified limit; the potential failure surface of the abutment develops, with the lower part close to the Rankine failure surface, and the upper part being the failure surface of the back edge of the non-bearing area; the calculated stiffness values agree well with the measured maximum tensile force of the reinforcement.

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许浩哲,蔡晓光,朱晨,李思汉,张黎.整体式墙面加筋土桥台承载特性模型试验研究[J].土木与环境工程学报(中英文),2026,48(4):188-197. XU Haozhe, CAI Xiaoguang, ZHU Chen, LI Sihan, ZHANG Li. Model experimental study on bearing characteristics of integral-wall geosynthetic reinforced soil abutments[J]. JOURNAL OF CIVIL AND ENVIRONMENTAL ENGINEERING,2026,48(4):188-197.10.11835/j. issn.2096-6717.2024.098

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  • 收稿日期:2024-07-01
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  • 在线发布日期: 2026-07-08
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