循环效应下原状膨胀土的土–水特征和收缩特性

doi:10.3724/1000-6915.jrme.2025.0584

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摘要为研究干湿、冻融和干湿–冻融循环对膨胀土土–水特征和收缩特性影响的差异，对原状膨胀土设计多次干湿、冻融和干湿–冻融循环试验，再对各循环下饱和样开展常规收缩试验和控制吸力脱湿试验。研究结果表明：屈服吸力sy和缩限吸力sSL将饱和膨胀土的脱湿过程划分为3个区域，即s＜sy时，膨胀土处于弹性区域，sy≤ s≤sSL时，膨胀土处于弹塑性区域，s＞sSL时，膨胀土处于缩限区域；干湿循环后膨胀土的临界吸力、持水能力、进气值、屈服吸力和缩限吸力均最大，冻融循环后次之，干湿–冻融循环后最小；不同循环类型下，脱湿过程中e-Sr曲线皆近似由平缓段、陡降段和垂线段3个部分组成，陡降段结束后干缩变形基本完成；饱和度（或孔隙比）皆随着循环次数的增大而减小（或增大）并最终趋于稳定，其中，首次循环降低（或上升）的幅度较大，3次循环后饱和度（或孔隙比）趋于稳定；干湿循环后饱和膨胀土的干缩程度最大，干湿–冻融循环后次之，冻融循环后干缩程度最小；提出了考虑干湿、冻融和干湿冻融循环影响的饱和膨胀土的SSCC和SWCC曲线模型，且模型拟合效果较好。

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	方瑾瑾1*
	冯以鑫2
	王立平1
	闫芙蓉1
	张敏霞1

关键词 ：土力学, 屈服吸力, 缩限吸力, 干湿&ndash, 冻融循环, 收缩特性, 干缩

Abstract：Multiple drying-wetting, freeze-thaw, and drying-wetting-freeze-thaw cycle tests were conducted on intact expansive soil. This was followed by conventional shrinkage tests and controlled suction desorption tests on saturated samples under each cycle condition to investigate the differences in the effects of drying-wetting, freeze-thaw, and combined drying-wetting-freeze-thaw cycles on the soil-water characteristics and shrinkage behavior of expansive soil. The results indicate that the yield suction (sy) and shrinkage limit suction (sSL) divide the desorption process of saturated expansive soil into three zones: (1) when s＜sy, the soil is in the elastic zone, (2) when sy≤s≤sSL, the soil is in the elastoplastic zone and (3) when s＞sSL, the soil is in the shrinkage limit zone. Following drying-wetting (DW) cycles, the expansive soil exhibited the highest critical suction, water retention capacity, air entry value, yield suction, and shrinkage limit suction, with freeze-thaw (FT) cycles yielding intermediate values, while drying-wetting-freeze-thaw (DW-FT) cycles resulted in the lowest values. Under various cycling conditions, the e-Sr curves during desorption can be approximately divided into three segments: a gentle segment, a steep descending segment, and a vertical segment. The shrinkage deformation was essentially completed after the steep descending segment. The degree of saturation (or void ratio) decreased (or increased) with the number of cycles and eventually stabilized. Notably, the first cycle caused the most significant reduction (or increase), with the degree of saturation (or void ratio) stabilizing after three cycles. The dry shrinkage degree of saturated expansive soil was greatest after DW cycles, followed by DW-FT cycles, and smallest after FT cycles. A model for the Soil Shrinkage Characteristic Curve (SSCC) and Soil-Water Characteristic Curve (SWCC) of saturated expansive soil, incorporating the effects of DW, FT, and DW-FT cycles, was proposed, and the fitting results demonstrated good agreement with the experimental data.

Key words： soil mechanics yield suction shrinkage limit suction drying-wetting-freeze-thaw cycles shrinkage behavior dry shrinkage

引用本文:

方瑾瑾1*，冯以鑫2，王立平1，闫芙蓉1，张敏霞1. 循环效应下原状膨胀土的土–水特征和收缩特性[J]. 岩石力学与工程学报, 2026, 45(2): 626-638.
FANG Jinjin1*, FENG Yixin2, WANG Liping1, YAN Furong1, ZHANG Minxia1. Cyclic effects on soil-water characteristics and shrinkage behavior of intact expansive soils. , 2026, 45(2): 626-638.

链接本文:

https://rockmech.whrsm.ac.cn/CN/10.3724/1000-6915.jrme.2025.0584 或 https://rockmech.whrsm.ac.cn/CN/Y2026/V45/I2/626

[1] 刘特洪. 工程建设中的膨胀土问题[M]. 北京：中国建筑工业出版社，1997：1–2.(LIU Tehong. Expansive soil problems in engineering construction[M]. Beijing：China Architecture and Building Press，1997：1–2.(in Chinese))
[2] 韩仲，邹维列，裴秋阳，等. 湿度和冻融循环影响下膨胀土的压缩特性及孔隙结构特征[J]. 岩土工程学报，2025，47(3)：495–505. (HAN Zhong，ZOU Weilie，PEI Qiuyang，et al. Effects of humidity and freeze-thaw cycles on compression and pore structure characteristics of expansive soils[J]. Chinese Journal of Geotechnical Engineering，2025，47(3)：495–505.(in Chinese))
[3] 陈永，黄英豪，王硕，等. 冻融循环对不同压实度下膨胀土力学特性影响的试验研究[J]. 岩石力学与工程学报，2023，42(增2)：4 299–4 309.(CHEN Yong，HUANG Yinghao，WANG Shuo，et al. Effects of freeze-thaw cycles on mechanical properties of expansive soils at different compaction degrees[J]. Chinese Journal of Rock Mechanics and Engineering，2023，42(Supp.2)：4 299–4 309.(in Chinese))
[4] 张凌凯，崔子晏. 干湿–冻融循环条件下膨胀土的压缩及渗透特性变化规律[J]. 岩土力学，2023，44(3)：728–740.(ZHANG Lingkai，CUI Ziyan. Compression and permeability characteristics of expansive soil under drying-wetting-freezing-thawing cycles[J]. Rock and Soil Mechanics，2023，44(3)：728–740.(in Chinese))
[5] 赵茜，杨金熹，赵晋萍. 冻融和干湿循环对原状黄土渗透系数的影响[J]. 中国地质灾害与防治学报，2020，31(2)：119–126.(ZHAO Qian，YANG Jinxi，ZHAO Jinping. Experimental study on permeability of undisturbed loess under freezing-thawing and drying-wetting cycling conditions[J]. The Chinese Journal of Geological Hazard and Control，2020，31(2)：119–126.(in Chinese))
[6] 程培峰，王佳康. 冻融循环对原状过湿土固结变形特性的影响[J]. 冰川冻土，2019，41(4)：858–864.(CHENG Peifeng，WANG Jiakang. Effect of freezing-thawing cycles on consolidation deformation characteristics of natural over-wet soil[J]. Journal of Glaciology and Geocryology，2019，41(4)：858–864.(in Chinese))
[7] 时伟，张亮，杨忠年，等. 冻融循环条件下膨胀土力学特性试验研究[J]. 西安建筑科技大学学报：自然科学版，2019，51(4)：480–485.(SHI Wei，ZHANG Liang，YANG Zhongnian，et al. Experimental study on mechanical properties of expansive soil of artificial preparation under freeze-thaw cycle conditions[J]. Journal of Xi?an University of Architecture and Technology：Natural Science，2019，51(4)：480–485.(in Chinese))
[8] 赵凌峰，张凌凯. 北疆供水一期工程膨胀性渠坡滑动破坏机制与稳定分析[J]. 工程力学，2023，40(3)：129–140.(ZHAO Lingfeng，ZHANG Lingkai. Sliding failure mechanism and stability analysis of expansive canal slope in North Xinjiang water supply phase I project[J]. Engineering Mechanics，2023，40(3)：129–140.(in Chinese))
[9] 陈善雄，赵旻，冷星火. 强膨胀土渠坡破坏机理及处理技术[M]. 北京：科学出版社，2016：7–8.(CHEN Shanxiong，ZHAO Min，LENG Xinghuo. Strong expansive soil slope failure mechanism and treatment technology[M]. Beijing：Science Press，2016：7–8.(in Chinese))
[10] 陈正汉，郭楠. 非饱和土与特殊土力学及工程应用研究的新进展[J]. 岩土力学，2019，40(1)：1–54.(CHEN Zhenghan，GUO Nan. New developments of mechanics and application for unsaturated soils and special soils[J]. Rock and Soil Mechanics，2019，40(1)：1–54.(in Chinese))
[11] LIU G S，TOLL D G，KONG L W，et al. Matric suction and volume characteristics of compacted clay soil under drying and wetting cycles[J]. Geotechnical Testing Journal，2020，43(2)：464–479.
[12] DING L Q，HAN Z，ZOU W L，et al. Characterizing hydro- mechanical behaviours of compacted subgrade soils considering effects of freeze-thaw cycles[J]. Transportation Geotechnics，2020，24：100392.