宽饱和度范围下考虑盐溶液影响的非饱和黏土抗剪强度模型研究

doi:10.3724/1000-6915.jrme.2025.0591

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摘要黏土矿物颗粒与孔隙盐溶液间的相互作用对颗粒间毛细作用和吸附效应有着显著的影响，这种影响会改变非饱和黏土的剪切强度，从而对盐渍土地区基础设施的稳定性产生一系列影响。为更好地反映盐溶液对非饱和黏土物理化学作用的影响，在广义土骨架理论的基础上，将饱和度分为毛细水饱和度和吸附水饱和度，然后提出考虑渗透吸力影响的有效应力方程和土水特征曲线（SWCC）模型。有效应力方程通过考虑引起广义三相系统体积变化的虚功与毛细水状态能量变化的关系获得，主要由净应力、毛细应力和渗透应力3项组成。SWCC模型综合考虑渗透吸力对吸附水赋存形式与含量的影响，以及进气值与渗透压力的线性相关性，可很好地刻画非饱和盐渍黏土的持水性能。在此基础上，提出非饱和盐渍黏土的抗剪强度模型，并借助不同含盐条件下非饱和黏土的试验结果验证模型的预测能力。结果指出，提出的抗剪强度公式不仅能够准确地捕捉不同基质吸力和渗透吸力条件下非饱和盐渍黏土抗剪强度的变化规律，而且也可反映盐溶液影响非饱和黏土抗剪强度的物理力学机制。

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	王立业1
	牛宇博1
	李宏波1
	马强2
	周凤玺3*

关键词 ：土力学, 非饱和盐渍黏土, 渗透吸力, 有效应力, 土水特征曲线, 抗剪强度

Abstract：The interaction between clay mineral particles and pore salt solutions significantly influences intergranular capillarity and adsorption effects, thereby altering the shear strength of unsaturated clay and impacting the stability of infrastructure in saline soil regions. To elucidate the influence of salt solutions on the physicochemical interactions of unsaturated clay, total saturation is categorized into capillary water saturation and adsorbed water saturation, based on generalized soil skeleton theory. Subsequently, an effective stress equation and a soil-water characteristic curve (SWCC) model that incorporate osmotic suction are proposed. The effective stress equation is derived by examining the relationship between the virtual work responsible for volume changes in the generalized three-phase system and energy changes in the capillary water state, which primarily comprises net stress, capillary stress, and osmotic stress. The SWCC model integrates the impact of osmotic suction on adsorbed water content, as well as the linear relationship between the air entry value and osmotic pressure, effectively characterizing the water-holding properties of unsaturated saline clay. Building on this foundation, a shear strength model for unsaturated saline clay is proposed, and its predictive capability is validated using experimental results from unsaturated clay subjected to varying saline conditions. The findings demonstrate that the proposed shear strength formula not only accurately captures variations in the shear strength of unsaturated saline clay under different matric suction and osmotic suction conditions but also reflects the physical and mechanical mechanisms by which salt solutions affect shear strength.

Key words： soil mechanics unsaturated saline clay osmotic suction effective stress soil-water characteristic curve shear strength

引用本文:

王立业1，牛宇博1，李宏波1，马强2，周凤玺3*. 宽饱和度范围下考虑盐溶液影响的非饱和黏土抗剪强度模型研究[J]. 岩石力学与工程学报, 2026, 45(5): 1571-1583.
WANG Liye1, NIU Yubo1, LI Hongbo1, MA Qiang2, ZHOU Fengxi3*. A shear strength model for unsaturated clay considering the influence of salt solution under a wide saturation range. , 2026, 45(5): 1571-1583.

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https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2025.0591 或 https://rockmech.whrsm.ac.cn/CN/Y2026/V45/I5/1571

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