港口区域软土地基中箱筒型基础防波堤横向承载特性

doi:10.11988/ckyyb.20240346

摘要/Abstract

摘要：

箱筒型基础防波堤是港口区域软土地基中较优的防波堤结构形式,为了探究其承载特性,通过大比尺的模型试验和数值仿真,研究了箱筒型基础防波堤的横向承载特性,分析了其受荷响应、失效模式、转动特性及与地基的相互作用。研究发现:横向荷载作用下,箱筒型基础整体失效模式为一般剪切破坏;准弹性阶段防波堤向荷载方向转动,转角与横向位移线性相关;塑性阶段临界位移约为基础长度的1.0%,变位模式由滑移为主向转动为主转变;失效阶段临界位移约为基础长度的3.0%,变位以转动为主;循环位移荷载作用下,正旋转发生循环硬化,负旋转发生循环退化。研究成果有助于完善箱筒型基础结构的计算理论。

关键词: 软弱地基, 箱筒型基础, 防波堤, 横向承载特性, 模型试验

Abstract:

[Objectives] This study aims to investigate the lateral bearing characteristics of bucket foundation breakwaters, focusing on their failure modes, ultimate bearing capacity, the relationship between rotation and displacement, soil-structure interaction, and cyclic bearing behaviors. The goal is to improve computational theories of bucket foundation breakwaters and support their engineering design and applications. [Methods] Based on the actual structural configurations, a 1∶20 large-scale test model was designed, along with a foundation bed model simulating the sandy soil conditions of port areas, to simulate the service performance of bucket foundation breakwaters. The loading process covered the entire phase from post-installation to failure. While validating the test conditions using the finite element analysis, supplementary finite element analysis was conducted for different structural configurations and soil conditions, enabling a systematic study of the bearing characteristics and load response of bucket foundation breakwaters. [Results] (1) In the early stage of installation, the sidewall friction increased linearly, with the average friction measured in the test being 41.23 kPa and the average friction coefficient 0.405. (2) The failure mode was general shear failure. The displacement pattern at the limit state obtained from numerical analysis was consistent with the test results. When the displacement reached 150.3 mm, the maximum displacement of the soil on the rear side was 54.2 mm. (3) The ultimate bearing capacity obtained from the model test was 14.26 kN, while the finite element analysis calculated 15.07 kN, with a relative error of 5.68%. The deformation process of bucket foundation breakwaters could be divided into three stages: quasi-elastic stage, plastic stage, and failure stage. In the quasi-elastic stage, the displacement increased linearly, with an elastic limit displacement of about 1.0%L and a plastic limit displacement of about 3.0%L. (4) Before failure, earth pressure in the passive zone increased with displacement, reaching a maximum increment of 74.2 kPa. Earth pressure in the active zone was significantly smaller, with a maximum increment of 10.2 kPa. The variation trends of earth pressure on the connecting wall and the cylinder wall were consistent, and the deformation coordination between the foundation and the internal soil was relatively good. (5) The bearing capacity of bucket foundation breakwaters in sandy soil was better than in silty clay, which was better than in silt. Under the same displacement, rotation was more pronounced in sandy soil, while under identical loading conditions, the most significant rotation occurred in silt. (6) The ultimate bearing capacity of the bucket foundation breakwaters was negatively correlated with both the length-to-height ratio and width-to-height ratio, but positively correlated with the length-to-height ratio. (7) Under lateral cyclic loading, the bucket foundation breakwaters showed cyclic hardening during positive rotation and cyclic degradation during negative rotation. The stiffness reduction was more pronounced during positive rotation. [Conclusions] The deformation of bucket foundation breakwaters has three stages: quasi-elastic, plastic, and failure stages. The overall failure mode is general shear failure, and there is a high degree of deformation coordination between the foundation and the soil. Soil type significantly affects bearing capacity, with sandy soil performing the best and silt the worst. In addition, the geometry layout greatly influences performance. Under cyclic loading conditions, the bucket foundation breakwaters exhibit enhanced plastic deformation capacity, good energy dissipation, and excellent seismic performance.

Key words: soft foundation, bucket foundation, breakwater, lateral bearing characteristics, model test

中图分类号:

TV331混凝土结构

王帅, 张佳林, 胡少伟, 游建华, 杨煜明. 港口区域软土地基中箱筒型基础防波堤横向承载特性[J]. raybet体育在线院报, 2025, 42(7): 174-180.

WANG Shuai, ZHANG Jia-lin, HU Shao-wei, YOU Jian-hua, YANG Yu-ming. Lateral Bearing Characteristics of Bucket Foundation Breakwaters in Soft Soil of Port Areas[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(7): 174-180.

图/表 13

图1 模型试验装置

Fig.1 Model test setup

图2 土压力计布置

Fig.2 Layout of earth pressure gauges

表1 淤泥、粉质黏土和砂土的模型参数

Table 1 Model parameters of silt, silty clay, and sandy soil

土的种类	密度ρ/ (kg·m^-3)	内摩擦角φ/ (°)	内聚力c/ kPa	弹性模量E₀/ MPa	泊松比υ	压缩模量E_s/ MPa	摩擦系数 f
淤泥	1 680	2.30	3.00	2.30	0.400	5	0.15
粉质黏土	1 870	11.50	5.00	5.00	0.300	8	0.30
砂土	2 047	33.67	0.08	21.73	0.225	25	0.42

表2 模型组几何尺寸

Table 2 Geometric dimensions of model groups

计算模型	基础宽度/ mm	基础长度/ mm	筒体高度/ mm	宽高比	长宽比	长高比
M1	1 200	1 200	500	2.4	1.00	2.400
M2	1 200	1 200	1 000	1.2	1.00	1.200
M3	1 200	1 200	1 500	0.8	1.00	0.800
M4	1 200	1 800	500	2.4	1.50	3.600
M5	1 200	1 800	1 000	1.2	1.50	1.800
M6	1 200	1 500	800	1.5	1.25	1.875
M7	1 500	1 200	1 000	1.5	0.80	1.200

图3 有限元模型与位移测点

Fig.3 Finite element model and displacement measurement points

图4 下沉安装过程中的基础侧壁摩擦力

Fig.4 Sidewall friction of foundation during sinking installation

图5 极限状态的防波堤及土体变形

Fig.5 Breakwater and soil deformation at limit state

图6 防波堤的横向荷载-水平位移曲线注:图中FEM表示有限元法,下同。

Fig.6 Lateral load versus horizontal displacement curves of breakwater

图7 防波堤的横向荷载-转角曲线

Fig.7 Lateral load-rotation angle curves of breakwater

图8 被动区筒壁、主动区筒壁、基础顶板的土压力

Fig.8 Earth pressures on cylinder walls in passive zone and active zone and on top slab of foundation

图9 不同土质中防波堤M1的横向荷载-位移曲线

Fig.9 Lateral load-displacement curves of breakwater M1 in different soil types

图10 砂土中M1—M7模型的荷载-位移曲线

Fig.10 Load-displacement curves of M1-M7 in sandy soil

图11 防波堤的滞回曲线

Fig.11 Hysteretic curves of breakwater

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