长江科学院院报 ›› 2016, Vol. 33 ›› Issue (7): 105-109.DOI: 10.11988/ckyyb.20150332

• 岩土工程 • 上一篇    下一篇

砂卵石填料加筋土挡墙筋土荷载传递规律研究

王多银, 高超, 汪承志, 韩超, 仝亚   

  1. 重庆交通大学 河海学院,重庆 400074
  • 收稿日期:2015-04-20 出版日期:2016-07-01 发布日期:2016-07-11
  • 作者简介:王多银(1965-),男,四川遂宁人,教授,博士生导师,长期从事港口码头水工建筑物科研及教学工作,(电话)023-62652716(电子信箱)wdy@cqjtu.edu.cn。
  • 基金资助:
    国家自然科学基金项目(51209242)

Rules of Load Transfer between Soil and Reinforcement in Reinforced Earth Retaining Wall with Sandy Cobble

WANG Duo-yin, GAO Chao, WANG Cheng-zhi, HAN Chao, TONG Ya   

  1. College of River and Ocean Engineering,Chongqing Jiaotong University,Chongqing 400074,China
  • Received:2015-04-20 Online:2016-07-01 Published:2016-07-11

摘要: 为了研究砂卵石填料加筋土挡墙筋土间荷载传递规律,将加筋土视作以土体为基体,筋带为增强的复合材料,在轴向受力情况下,将拉筋周围土体分为界面层和加筋有效影响层。基于加筋有效影响层内由筋带产生的附加剪应力沿法向呈线性衰减的假设,修正了传统剪力滞后模型,建立起加筋带平衡微分方程,解得加筋土挡墙筋带轴向应力分布规律解析解。通过与拉拔试验数据对比,发现理论推导与试验结果比较吻合。研究结果表明:砂卵石填料加筋土挡墙拉筋应力沿长度l方向呈先增大后减小的类抛物线形状,且峰值出现在<l/2处;紧邻拉筋部分土体出现带状加筋有效影响层,且附加剪应力在该土层内沿法向线性衰减。

关键词: 砂卵石, 加筋土挡墙, 有效影响层, 剪滞理论, 荷载传递规律

Abstract: In order to study the rules of load transfer between reinforcement and soil in reinforced earth retaining wall with sandy cobble, the reinforced soil was considered as composite materials in which soil and reinforced belt was regarded as matrix and reinforcing material, respectively. The soil around the reinforcement was separated into the interface layer and the effective influence layer under axial load. Based on the hypothesis that the additional shear stress produced by the reinforcement turned to linear attenuation in the effective influence layer, we modified the traditional shear-lag model and established the stress equilibrium differential equation for the reinforcement, from which attained the axial stress analytical solution of the reinforcement. After comparing with the drawing test data, we found that the theoretical derivation was in accordance with the test results. According to the research, the axial stress of reinforcement increases firstly, and then decreases along the reinforcement length l, which shows parabolic-shaped distribution; and a maximum value appeared at a distance less than l/2 from the wall. The soil close to the reinforcement appeared banded effective influence layer, and the additional shear stress caused by the reinforcement in the effective influence layer turned to attenuate linearly along the normal direction.

Key words: sandy cobble, reinforced earth retaining wall, effective influence layer, shear-lag theory, load transfer rules

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