大型三轴循环试验下砾石土材料力学行为的试验和构造模型研究

IF 1.8 4区 工程技术 Q3 ENGINEERING, CIVIL
Jiu-Chang Zhang, Jun Du, Dong Li, Cheng-Jiang Qiu, Biao Li, Ru-Bin Wang
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引用次数: 0

摘要

本研究采用大尺寸三轴循环试验和新型构成模型,研究了砾质土在各种约束压力下的力学行为。分析的主要特性包括应力相关扩张、非线性强度、累积塑性应变、循环滞后、硬化和颗粒破碎。实验结果表明,约束压力会显著影响体积变形、强度和破坏模式。具体来说,随着压力的增加,体积变形从扩张转变为收缩,破坏模式从鼓形过渡到压缩剪切。所开发的模型在临界状态土壤力学框架内集成了应力-膨胀方程、塑性流动方向和塑性模量,可有效捕捉循环加载和卸载行为。模型中还包括颗粒破碎指数和空隙率演变微分方程,以反映相对密度的变化。该构成模型的材料常数来自大尺寸三轴循环试验。该模型的材料常数来自大尺寸三轴循环试验。与实验数据的比较证实了该模型的准确性以及在应力路径分析和复杂工程项目中的潜在应用,证明了其对不同机械应力条件的适应性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Experimental and Constitutive Modeling Investigations of the Mechanical Behaviors of a Gravelly Soil Material Under Large-Size Triaxial Cyclic Tests

Experimental and Constitutive Modeling Investigations of the Mechanical Behaviors of a Gravelly Soil Material Under Large-Size Triaxial Cyclic Tests

This study investigates the mechanical behavior of gravelly soil under various confining pressures using large-size triaxial cyclic tests and a novel constitutive model. Key properties analyzed include stress-dependent dilatation, nonlinear strength, cumulative plastic strain, cyclic hysteresis, hardening, and particle breakage. Experimental results show that confining pressure significantly affects volume deformation, strength, and failure modes. Specifically, volume deformation shifts from dilatation to contraction with increasing pressure, and failure modes transition from drum-shaped to compressive shear. The developed model integrates stress-dilatancy equations, plastic flow directions, and plastic moduli within the critical state soil mechanics framework, effectively capturing cyclic loading and unloading behaviors. A particle breakage index and a differential equation for void ratio evolution are included to reflect relative density changes. The material constants of this constitutive model are derived from large-size triaxial cyclic tests. The model's material constants are derived from large-size triaxial cyclic tests. Comparison with experimental data confirms the model's accuracy and potential applications in stress path analysis and complex engineering projects, demonstrating its adaptability to varying mechanical stress conditions.

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来源期刊
CiteScore
3.90
自引率
5.90%
发文量
83
审稿时长
15 months
期刊介绍: International Journal of Civil Engineering, The official publication of Iranian Society of Civil Engineering and Iran University of Science and Technology is devoted to original and interdisciplinary, peer-reviewed papers on research related to the broad spectrum of civil engineering with similar emphasis on all topics.The journal provides a forum for the International Civil Engineering Community to present and discuss matters of major interest e.g. new developments in civil regulations, The topics are included but are not necessarily restricted to :- Structures- Geotechnics- Transportation- Environment- Earthquakes- Water Resources- Construction Engineering and Management, and New Materials.
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