岩土力学 ›› 2026, Vol. 47 ›› Issue (6): 2141-2156.doi: 10.16285/j.rsm.2025.00349CSTR: 32223.14.j.rsm.2025.00349

• 岩土工程研究 • 上一篇    下一篇

动态CO2溶蚀作用下节理灰岩剪切力学性能及工程应用研究

董武书1,雍睿2,杜时贵2,李泽1,张小艳3,宋佳敏4   

  1. 1. 昆明理工大学 建筑工程学院,云南 昆明 650500;2. 宁波大学 岩石力学研究所,浙江 宁波 315211; 3. 昆明理工大学 电力工程学院,云南 昆明 650500;4. 绍兴大学 深部金属矿智能开采与装备全国重点实验室,浙江 绍兴312000
  • 收稿日期:2025-06-16 接受日期:2025-09-28 出版日期:2026-06-11 发布日期:2026-06-08
  • 通讯作者: 李泽,男,1981年生,博士,教授,主要从事岩土力学方面的研究工作。E-mail: lize@kust.edu.cn
  • 作者简介:董武书,男,1994年生,博士,主要从事岩土工程方面的研究工作。E-mail: 20221110001@stu.kust.edu.cn
  • 基金资助:
    国家自然科学基金(No.12262016,No.12462037,No.42407210,No.42530704)。

Shear mechanical characteristics of jointed limestone under dynamic CO2 aqueous solution corrosion and its engineering application

DONG Wu-shu1, YONG Rui2, DU Shi-gui2, LI Ze1, ZHANG Xiao-yan3, SONG Jia-min4   

  1. 1. Faculty of Civil Engineering and Mechanics, Kunming University of Science and Technology, Kunming, Yunnan 650500, China; 2. Institute of Rock Mechanics, Ningbo University, Ningbo, Zhejiang 315211, China; 3. Faculty of Electric Power Engineering, Kunming University of Science and Technology, Kunming, Yunnan 650500, China; 4. State Key Laboratory of Intelligent Deep Metal Mining and Equipment, Shaoxing University, Shaoxing, Zhejiang 312000, China
  • Received:2025-06-16 Accepted:2025-09-28 Online:2026-06-11 Published:2026-06-08
  • Supported by:
    This work was supported by the National Natural Science Foundation of China (12262016, 12462037, 42407210, 42530704).

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摘要: 水溶液侵蚀作用下,节理岩体剪切力学性能的持续劣化是影响边坡稳定性的重要因素。为此,以气−液循环的方式提出了气−液−固三相耦合作用下的动态溶蚀试验方法,开展了CO2溶液环境下节理试样的动态溶蚀试验及直剪试验,阐明了节理试样剪切力学参数的劣化规律。同时,结合三维激光扫描和微观结构测试技术,揭示了CO2溶液动态溶蚀作用下节理试样剪切力学性能的劣化机制。结果表明:节理试样的剪切−位移曲线呈现初期锁固、中期破坏、后期剪摩擦阻滑的三阶段特征。随溶蚀周期的增加,试样的剪切硬化特征及应力减小,其内摩擦角和黏聚力经30次动态溶蚀作用后分别降低了37.78%和29.73%。溶蚀作用引起的试样内部微观结构渐进损伤及孔隙发育造成的岩体抗压强度减小,以及节理面粗糙程度降低,削弱了节理之间的摩擦咬合作用,从而导致节理试样剪切力学性能的劣化。最后,针对节理边坡建立了考虑节理岩体剪切力学参数劣化的时变稳定性分析模型,发现节理边坡安全系数的衰减主要受控于节理剪切力学参数的劣化,并且由于应力状态的空间差异,随溶蚀周期的增加,边坡的潜在滑移路径由浅层逐步向深部节理迁移。研究成果可为边坡的长期稳定性评估提供可靠的理论依据。

关键词: 岩质边坡, 节理面, 动态溶蚀, 剪切力学性能, 劣化机制, 时变稳定性

Abstract: Continuous degradation of the shear properties of joint rock masses caused by aqueous solution erosion is a critical factor affecting slope stability. Therefore, we proposed a dynamic dissolution testing method based on gas-liquid circulation under gas-liquid-solid three-phase coupling conditions. Dynamic dissolution tests and direct shear tests were conducted on joint samples in CO₂ solution environment. The deterioration law of the shear mechanical parameters of the joint samples was characterized. Meanwhile, by combining three-dimensional morphology and microstructure scanning technology, the deterioration mechanism of the joint samples under the dynamic dissolution effect of CO2 solution was revealed. Results show that the shear-displacement curves of the joint samples can be divided into three stages: initial locking, intermediate failure, and late-stage shear-friction-resistance sliding. As the number of dissolution cycles increased, the shear hardening characteristics and stress levels of the samples decreased. After 30 dynamic dissolution cycles, the internal friction angle and cohesion decreased by 37.78% and 29.73%, respectively. Concurrently, progressive microstructural damage and pore development reduced the joint surface roughness and the compressive strength of joint rock masses, weakened frictional interlocking between joint surfaces, and thereby degraded shear mechanical performance. Finally, a numerical stability model incorporating dissolution-induced degradation of shear parameters was established. Analyses indicate that the decline in the safety factor of jointed slopes is primarily governed by the deterioration of joint shear parameters. Owing to spatial variations in stress states, the potential slip path dynamically migrates from shallow to deeper joints. The methods and findings provide a theoretical basis for long-term stability assessment of joint slopes.

Key words: rock slope, joint surface, dynamic dissolution, shear mechanical characteristics, deterioration mechanism, time-varying stability

中图分类号: TU45
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