粗粒土力学特性大型平面应变试验研究

doi:10.11988/ckyyb.20230974

新澳门游戏网站入口院报 ›› 2025, Vol. 42 ›› Issue (1): 129-135.DOI: 10.11988/ckyyb.20230974

粗粒土力学特性大型平面应变试验研究

姜景山¹^,²(), 左永振², 程展林², 黄鑫³, 张超¹, 王志华⁴

¹ 南京工程学院建筑工程学院,南京 211167
² 新澳门游戏网站入口水利部岩土力学与工程重点实验室,武汉 430010
³ 河海大学岩土工程澳门网络游戏网站官网首所,南京 210098
⁴ 南京吉欧地下空间科技有限公司,南京 211816

收稿日期:2023-09-08 修回日期:2023-11-01 出版日期:2025-01-01 发布日期:2025-01-01
作者简介:
姜景山(1978-),男,安徽青阳人,教授,博士,主要从事粗粒土力学性质、地基和路基处理等方面的研究工作。E-mail: j.s.jiang@163.com
基金资助:
国家自然科学基金-联合基金重点项目(U21A20158); 国家自然科学基金面上项目(51979010); 中央级公益性科研院所基本科研业务费项目(CKSK2023137/YT); 江苏省产学研合作项目(BY2021044)

Mechanical Properties of Coarse-grained Soil in Large-scale Plane Strain Tests

JIANG Jing-shan¹^,²(), ZUO Yong-zhen², CHENG Zhan-lin², HUANG Xin³, ZHANG Chao¹, WANG Zhi-hua⁴

¹ School of Civil Engineering and Architecture, Nanjing Institute of Technology, Nanjing 211167, China
² Key Laboratory of Geotechnical Mechanics and Engineering of Ministry of Water Resources, Changjiang River Scientific Research Institute, Wuhan 430010, China
³ Geotechnical Research Institute, Hohai University, Nanjing 210098, China
⁴ Nanjing Geo Underground Space Technology Co., Ltd., Nanjing 211816, China

Received:2023-09-08 Revised:2023-11-01 Published:2025-01-01 Online:2025-01-01

摘要/Abstract

摘要：

土石坝填料一般处于平面应变状态,目前填料力学特性研究基本采用大型三轴试验。由于三轴应力状态下中主应力等于小主应力,平面应变状态下大坝填料的力学性能会被低估。为充分认识填料潜能,科学设计和合理评估土石坝,有必要对填料开展平面应变试验研究。应用大型真三轴仪对填料进行了大型平面应变试验,共开展了4种不同初始干密度的粗粒土平面应变各向等压固结排水剪切试验。结果表明:应力-应变关系主要为应变硬化型,应力曲线呈爬升型,体变表现为剪缩。某一小主应力下,大小主应力之差的最大值随初始干密度的增大呈线性增大;初始干密度一定时,大小主应力之差的最大值与小主应力呈线性关系增大。初始剪切阶段,小主应力一定时,偏应力与球应力之比曲线斜率随初始干密度的增大而增大,随剪切变形的发展,不同初始干密度的应力比曲线逐渐趋于接近。偏应力随球应力的增大单调增加则对应应变硬化型,若偏应力随球应力的增大先增加后减小则对应应变软化型。相同小主应力时,初始弹性模量随初始干密度的增大而增大,近似呈线性关系;某一初始干密度下,初始弹性模量随小主应力的增大基本呈线性关系增大。中主应力系数随大主应力方向应变的增大而增大,曲线形态呈三折线形,初始剪切阶段增长较为缓慢,随剪切变形的增大增长相对加快并呈线性关系增大,如曲线末端下弯为应变硬化型,曲线末端上翘为应变软化型。

关键词: 粗粒土, 大型平面应变试验, 力学特性, 主应力, 偏应力, 球应力, 大型真三轴仪

Abstract:

At present, large-scale triaxial tests are used to investigate the mechanical properties of the filling of earth-rockfill dams, which are generally under plane strain state. Because the intermediate principal stress is equal to the minor principal stress in triaxial stress state, the mechanical properties of the filling under plane strain state will be underestimated. To fully comprehend the potential of the fill material for scientific design and rational evaluation of earth-rockfill dams, it is necessary to conduct plane strain test of the filling material. Large-scale plane strain tests were performed on the filling material using a large-scale true triaxial apparatus. A series of plane strain isotropic consolidation and drainage shear tests were carried out on coarse-grained soils with four different initial dry densities. Test results indicate that the stress-strain relationship predominantly exhibits strain hardening, with a rising stress curve and shear shrinkage-induced volumetric changes. Under a given minor principal stress, the maximal difference between the major and minor principal stresses increases linearly with the initial dry density. Similarly, when the initial dry density remains constant, this difference also increases linearly with minor principal stress. During the initial shear stage, the slope of the stress ratio curve between deviatoric and spherical stresses rises with increasing initial dry density. As shear deformation progresses, the stress ratio curves for different initial dry densities converge. A monotonically increasing deviatoric stress with spherical stress denotes strain hardening, whereas a deviatoric stress that first rises and then falls indicates strain softening. The initial elastic modulus under the same minor principal stress rises linearly with the initial dry density. At a specific initial dry density, the initial modulus increases linearly with the minor principal stress. The intermediate principal stress coefficient grows with the strain in the major principal stress direction, forming a three-segment broken line curve. Initially, the growth is slow during shear stage, but it accelerates linearly with increasing shear deformation. A slightly downward-bent curve end correlates with strain hardening, while a slightly upward-bent end corresponds to strain softening.

Key words: coarse-grained soil, large-scale plane strain test, mechanical property, principal stress, deviatoric stress, spherical stress, large-scale true triaxial apparatus

中图分类号:

TU411实验室试验(室内土工试验)

姜景山, 左永振, 程展林, 黄鑫, 张超, 王志华. 粗粒土力学特性大型平面应变试验研究[J]. 新澳门游戏网站入口院报, 2025, 42(1): 129-135.

JIANG Jing-shan, ZUO Yong-zhen, CHENG Zhan-lin, HUANG Xin, ZHANG Chao, WANG Zhi-hua. Mechanical Properties of Coarse-grained Soil in Large-scale Plane Strain Tests[J]. Journal of Changjiang River Scientific Research Institute, 2025, 42(1): 129-135.

图/表 11

图1 大型真三轴仪、平面应变试验原理示意图和微摩阻侧向加载板

Fig.1 Large-scale true triaxial apparatus,schematic diagram of plane strain test and low-friction lateral loading plate

图2 试验材料和颗粒试验级配曲线

Fig.2 Test material and particle size distribution curve

图3 不同初始干密度平面应变试验的应力-应变曲线

Fig.3 Stress-strain curves of plane strain tests at different initial dry densities

图4 强度与初始干密度、小主应力的关系

Fig.4 Relationship between strength and initial dry density,minor principal stress

图5 平面应变试验相对于三轴试验强度增加百分比

Fig.5 Percentage increase of strength for plane strain tests compared with triaxial tests

表1 强度包线参数

Table 1 Parameters of the strength envelopes

初始干密度 ρ_d0/(g·cm^-3)	摩尔-库伦强度包线		非线性强度包线
初始干密度 ρ_d0/(g·cm^-3)	c / kPa	φ/ (°)	A	B
2.00	136	38.4	1.370	0.834
2.04	166	38.7	1.460	0.824
2.08	183	40.5	1.638	0.803
2.12	198	41.6	1.793	0.788

图6 偏应力与球应力之比与大主应力方向应变的关系

Fig.6 Relationship between ratio of deviatoric stress to spherical stress and strain in direction of major principal stress

图7 应力路径曲线

Fig.7 Stress path curves

图8 初始弹性模量与小主应力的关系

Fig.8 Relationship between initial elastic modulus and minor principal stress

图9 初始弹性模量与初始干密度的关系

Fig.9 Relationship between initial elastic modulus and initial dry density

图10 中主应力系数与大主应力方向应变的关系

Fig.10 Relationship between coefficients of interme-diate principal stress and strain in direction of major principal stress

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粗粒土力学特性大型平面应变试验研究

Mechanical Properties of Coarse-grained Soil in Large-scale Plane Strain Tests

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