Research Progresses in Dilatancy of Coarse Granular Materials under Complex Stress Conditions

doi:10.11988/ckyyb.20231062

Abstract

Abstract:

Dilatancy is an important mechanical issue in the study on strength and deformation of coarse granular materials. It is governed by microscopic factors such as particle arrangement and inter-particle pressure, and hence is affected by macroscopic variables including relative density and stress state. In this article, research progresses in the dilatancy of coarse granular materials under complex stress conditions are reviewed from the aspects of mechanical properties, strength criteria, critical state, and dilatancy behavior. Future trends in research are outlined as follows: 1) Laboratory investigation via large-scale true triaxial tests and theoretical analysis on the dilatancy of coarse granular material would drive advancements in constitutive modeling. 2) Study on the stress-deformation facilitates the dilatancy equations under conventional triaxial condition developing into that under complex stress condition, thereby unifying strength and deformation issues. 3) Coupling stress state and void ratio with state parameters offers a systematic approach to assessing the compactness state of soils and their dilatancy behavior, potentially reducing the reliance on multiple material parameters. The integration of state parameters and stress paths indicates a more scientific and systematic approach in the research on the mechanical properties of coarse granular materials.

Key words: coarse granular material, dilatancy, true triaxial test, strength criterion, state parameter

CLC Number:

TU454变形测量

ZHOU Yue-feng, ZUO Yong-zhen, WAN Hang. Research Progresses in Dilatancy of Coarse Granular Materials under Complex Stress Conditions[J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(8): 104-112.

Figures/Tables 2

Table 1 Scales of reported true triaxial apparatus[21,24,26 -27,29⇓⇓ -32]

序号	研制机构	长×宽×高/(mm× mm×mm)
1	同济大学	120×70×70
2	河海大学	120×60×120
3	西安理工大学	70×70×70
4	上海交通大学	80×80×50
5	长江科学院	300×300×600
6	香港理工大学	70×70×140
7	瑞典皇家地质学院	62×62×62
8	伦敦大学	75×75×75
9	剑桥大学	70×70×35
10	Surrey大学	100×100×100
11	日本谷藤株式会社	25.6×88.9×88.9
12	日本诚研舍	100×100×100
13	美国Ko和Scott公司	90×90×90
14	韩国Choi公司	241×241×241
15	美国GCTS公司	75×75×150
16	英国GDS公司	75×75×150

Table 2 Several commonly adopted dilatancy equations in constitutive models

出处	关系式	说明
Drucker- Prager^[5]	$D = - 33 a$	a为试验常数
Rowe^[50]	D=9(M-η)/ (9+3M-2Mη)	η为应力比q/p',M为临界应力比
剑桥模型^[39]	D=M-η
修正剑桥模型^[39]	D= (M ²-η²)/2η
Nova等^[51]	D=(M -η)/μ	μ为试验常数
Li和 Dafalias^[40]	D=D₀(M $e m ψ$ -η)/M	D₀和m为试验常数,ψ为状态参量
迟明杰等^[52]	D= D₀( $e m ω$ -η/η_pt )	η_pt为相转化态应力比q/p',ω为当前孔隙比与相转化态孔隙比之比
孙海忠和黄茂松^[47]	D=A(η_ptg(θ)-η)	g(θ)为角隅函数,A为试验常数

Table 2 Several commonly adopted dilatancy equations in constitutive models

出处	关系式	说明
Drucker- Prager^[5]	$D = - 33 a$	a为试验常数
Rowe^[50]	D=9(M-η)/ (9+3M-2Mη)	η为应力比q/p',M为临界应力比
剑桥模型^[39]	D=M-η
修正剑桥模型^[39]	D= (M ²-η²)/2η
Nova等^[51]	D=(M -η)/μ	μ为试验常数
Li和 Dafalias^[40]	D=D₀(M $e m ψ$ -η)/M	D₀和m为试验常数,ψ为状态参量
迟明杰等^[52]	D= D₀( $e m ω$ -η/η_pt )	η_pt为相转化态应力比q/p',ω为当前孔隙比与相转化态孔隙比之比
孙海忠和黄茂松^[47]	D=A(η_ptg(θ)-η)	g(θ)为角隅函数,A为试验常数

[1]	CHEN Jing-yi, CHEN Xiao-qing, SONG Dong-ri, LÜ Ming, JIANG Hao. Effect of Shrub Root Morphology on Root-Soil Complex Strength: A Study Based on Large-scale Direct Shear Test [J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(8): 120-127.
[2]	LI Cheng, ZHANG Yong-jin, ZENG Ke, XU Xing-qian, QU Xin. A Chart-based Method of Rapidly Calculating Permanent Displacement of Rock Slope [J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(6): 130-135.
[3]	CIREN Yun-dan, WANG Liu-jiang, TASHI Dun-zhu, MAO Hang-yu, LI Rui-ping. Experimental Study on the Influence of Temperature on Strength and Dilatancy of Hydraulic Asphalt Concrete [J]. Journal of Yangtze River Scientific Research Institute, 2024, 41(1): 190-195.
[4]	DONG Jia-xing, ZHOU Zhi-qiang, WANG Zhi-rong, ZHAO Yi-ran, LI Jian-guo, MU Hong-yuan, ZUO Shu-qiong, ZHAO Yong-chuan. Estimation of Mechanical Parameters of Intensively Sandy Dolomite Based on Hoek-Brown Strength Criterion [J]. Journal of Yangtze River Scientific Research Institute, 2022, 39(12): 21-25.
[5]	YU Xu-guang, ZHENG Hong. Elastic-plastic Solution to Surrounding Rock of Circular Tunnel Based on Power Hardening-Ideal Plastic Model in Consideration of Seepage [J]. Journal of Yangtze River Scientific Research Institute, 2021, 38(7): 102-108.
[6]	JIANG Jing-shan, ZUO Yong-zhen, CHENG Zhan-lin, PAN Jia-jun, ZHANG Chao, WEI You-xin. Effects of Confining Pressure and Density on Mechanical Properties of Coarse Granular Material under Critical State [J]. Journal of Yangtze River Scientific Research Institute, 2021, 38(5): 94-102.
[7]	CHENG Zhan-lin, PAN Jia-jun. Some Innovations and Developments in the Field of Earth-Rock Dam Engineering [J]. Journal of Yangtze River Scientific Research Institute, 2021, 38(5): 1-10.
[8]	HU Qing-bo, LIANG Hai-an, YANG Ting, LIU Xiao-dong, WANG Yu, ZHANG Long-peng. Permeability and Strength Characteristics of Tamusu Deep Clay under Confining Pressure and Osmotic Pressure [J]. Journal of Yangtze River Scientific Research Institute, 2021, 38(2): 107-113.
[9]	ZHI Bin, LI Rui-ni, ZHANG Sheng-bo, WANG Yong-xin, REN Yi-long. Modification of Structural Loess Strength Criterion Considering the Effect of Moderately-soluble Salt Content [J]. Journal of Yangtze River Scientific Research Institute, 2021, 38(1): 124-128.
[10]	JIANG Jing-shan, ZUO Yong-zhen, CHENG Zhan-lin, PAN Jia-jun. Effects of Density on Mechanical Properties of Coarse Granular Material under Three-dimensional Stress [J]. Journal of Yangtze River Scientific Research Institute, 2021, 38(1): 89-94.
[11]	JIANG Jing-shan, ZUO Yong-zhen, CHENG Zhan-lin, GAO Pan, CHEN Jian. A Strength Criterion of Coarse Granular Materials under Three-dimensional Stress State [J]. JOURNAL OF YANGTZE RIVER SCIENTIFIC RESEARCH INSTI, 2020, 37(6): 100-107,114.
[12]	YU Ru-shan, YANG Yi, XU Dong-li. Study on the Application of Hoek-Brown Strength Criterion inEstimating Mechanics Parameters of Deep Rock Mass [J]. JOURNAL OF YANGTZE RIVER SCIENTIFIC RESEARCH INSTI, 2018, 35(1): 123-127.
[13]	KOU Tian, HU Bin, HE Da-zhao, MAO Yuan-jing, YAO Wen-min. Slope Stability Analysis Based on Non-proportional and Dynamic Double Strength Reduction Method [J]. JOURNAL OF YANGTZE RIVER SCIENTIFIC RESEARCH INSTI, 2017, 34(12): 84-88.
[14]	LI Xue-mei, RONG Chuan-xin, CHENG Hua. Analysis of Coal Mine Shaft Lining with Fluid-solid Coupling Theory Based on Three-parameter Strength Criterion [J]. JOURNAL OF YANGTZE RIVER SCIENTIFIC RESEARCH INSTI, 2016, 33(6): 83-87.
[15]	XIONG Liang-xiao, YU Li-jun. Comparative Study of Three Mohr Strength Criteria [J]. JOURNAL OF YANGTZE RIVER SCIENTIFIC RESEARCH INSTI, 2016, 33(4): 81-85.