利用空心圆筒扭剪仪分析冻结前后黄土的强度特性

Pub Date : 2024-04-01 DOI:10.1016/j.rcar.2024.04.003
Peng Shen , QingZhi Wang , JianHong Fang , ChenWei Wang , Kui Zhang
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引用次数: 0

摘要

本文旨在全面分析主应力角旋转和中间主应力对黄土强度和变形特性的影响。利用空心圆柱体扭剪仪对正常和冻结条件下的重塑样品进行试验,研究复杂应力条件下黄土的力学性质和变形行为。结果表明,在正常和冻结条件下,土样中土壤颗粒、解冻水和相对位置的内部变化存在显著差异,导致强度和应变发展出现明显变化。在冻结状态下,黄土主要经历压缩破坏,裂缝增长缓慢,而在常温下,黄土主要表现为剪切破坏。随着主应力角的增大,土样在不同条件下的变形模式基本一致,从压缩逐渐过渡到扩展,同时轴向强度降低。主应力轴角(α)的逐渐增大降低了广义剪应力和剪应变曲线的强度。在 α 不断增大的情况下,冻土表现出应变硬化特征,最大剪切强度出现在 α = 45° 时。中间主应力系数(b)对冻土的强度也有显著影响,随着 b 的增大,广义剪应力强度逐渐减小。这项研究为全面探讨交通荷载下土壤的力学性能提供了参考,也为路基的设计和维护提供了可靠的理论依据。
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Analysis of strength characteristics of loess before and after freezing using a hollow cylinder torsional shear apparatus

This paper aims to comprehensively analyze the influence of the principal stress angle rotation and intermediate principal stress on loess's strength and deformation characteristics. A hollow cylinder torsional shear apparatus was utilized to conduct tests on remolded samples under both normal and frozen conditions to investigate the mechanical properties and deformation behavior of loess under complex stress conditions. The results indicate significant differences in the internal changes of soil particles, unfrozen water, and relative positions in soil samples under normal and frozen conditions, leading to noticeable variations in strength and strain development. In frozen state, loess experiences primarily compressive failure with a slow growth of cracks, while at normal temperature, it predominantly exhibits shear failure. With the increase in the principal stress angle, the deformation patterns of the soil samples under different conditions become essentially consistent, gradually transitioning from compression to extension, accompanied by a reduction in axial strength. The gradual increase in the principal stress axis angle (α) reduces the strength of the generalized shear stress and shear strain curves. Under an increasing α, frozen soil exhibits strain-hardening characteristics, with the maximum shear strength occurring at α = 45°. The intermediate principal stress coefficient (b) also significantly impacts the strength of frozen soil, with an increasing b resulting in a gradual decrease in generalized shear stress strength. This study provides a reference for comprehensively exploring the mechanical properties of soil under traffic load and a reliable theoretical basis for the design and maintenance of roadbeds.

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