冻融循环下固化盐渍土强度增长规律及损伤模型验证

孔元元; 谢柏涵; 王清; 张学飞; 孙东彦; 王智慧

doi:10.11988/ckyyb.20240926

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长江科学院院报 ›› 2025, Vol. 42 ›› Issue (11) : 126-132. DOI: 10.11988/ckyyb.20240926

岩土工程

冻融循环下固化盐渍土强度增长规律及损伤模型验证

孔元元 ¹ ,
谢柏涵 ¹ ,
王清 ² ,
张学飞 ³ ,
孙东彦 ⁴ ,
王智慧 ¹

作者信息 +

Strength Growth Mechanism and Damage Model Verification of Solidified Saline Soil under Freeze-Thaw Cycles

Author information +

文章历史 +

摘要

为探究冻融循环条件下石灰固化盐渍土的力学性能与损伤演化规律,重点分析了石灰掺量、养护龄期和冻融循环次数对其无侧限抗压强度的影响,并建立基于统计分布的损伤本构模型,预测冻融环境下固化盐渍土的应力-应变响应与性能退化。以吉林西部镇赉县盐渍土为研究对象,分别添加3%、6%和9%的石灰作为固化剂,在最优含水率(20%)和压实度(90%)下制备试样,分别养护7 d和28 d并进行0~60次冻融循环。通过无侧限抗压试验和扫描电镜(SEM)测试分析宏观力学性能和微观结构变化。基于Weibull分布函数,利用试验数据建立损伤演化模型。结果表明:最优石灰掺量为6%,养护28 d时无侧限抗压强度达835.01 kPa,是未处理土的4倍以上;未经处理与固化盐渍土在冻融后均表现为应变软化型和脆性破坏;随冻融次数增加,固化土强度逐渐下降,但仍显著高于素土;SEM图像显示,石灰处理有效减少裂隙发育,改善微观结构完整性;所建立的Weibull损伤模型可准确模拟不同冻融次数下的应力-应变全过程,冻融次数越多,拟合效果越好。综上,石灰固化可显著提升盐渍土的强度和抗冻融性能,在6%掺量和28 d养护条件下效果最优。基于Weibull分布函数的损伤模型能够有效表征固化盐渍土在冻融过程中的力学行为与损伤演化。研究成果为寒区盐渍土固化处理提供了理论与技术支持,创新点在于将微观结构变化与宏观力学响应相关联,并建立了适用于冻融条件的统计损伤预测模型。

Abstract

[Objective] This paper aims to investigate the mechanical properties and damage evolution law of lime-solidified saline soil under freeze-thaw cycles, with a focus on analyzing the effects of lime content, curing age, and the number of freeze-thaw cycles on its unconfined compressive strength (UCS). In addition, a damage constitutive model based on statistical distribution is established to predict the stress-strain response and performance degradation of solidified saline soil under freeze-thaw conditions. [Methods] Saline soil from Zhenlai County in western Jilin Province was selected as the research object. Lime was added at proportions of 3%, 6%, and 9% as the curing agent, and specimens were prepared under the optimum moisture content (20%) and a degree of compaction of 90%. The specimens were cured for 7 days and 28 days and subjected to 0-60 freeze-thaw cycles. Unconfined compressive strength (UCS) tests and scanning electron microscopy (SEM) analyses were conducted to examine the macroscopic mechanical properties and microstructural changes. Based on the Weibull distribution function, a damage evolution model was established using the experimental data. [Results] The optimum lime content was 6%, and the unconfined compressive strength reached 835.01 kPa after 28 days of curing, which was more than four times that of the untreated soil. Both untreated and solidified saline soils exhibited strain-softening behavior and brittle failure after freeze-thaw cycles. With the increase in freeze-thaw cycles, the strength of the solidified soil gradually decreased but still remained significantly higher than that of the untreated soil. SEM images showed that lime treatment effectively reduced crack development and improved the integrity of the microstructure. The established Weibull damage model accurately simulated the entire stress-strain process under different numbers of freeze-thaw cycles, and the fitting accuracy improved with an increasing number of cycles. [Conclusion] Lime solidification significantly enhances the strength and freeze-thaw resistance of saline soil, with the optimum effect achieved at a 6% lime content and 28 days of curing. The damage model based on the Weibull distribution can effectively characterize the mechanical behavior and damage evolution of solidified saline soil during freeze-thaw processes. The research findings provide theoretical and technical support for the solidification treatment of saline soil in cold regions. The innovation lies in correlating microstructural changes with macroscopic mechanical responses and establishing a statistical damage prediction model suitable for freeze-thaw conditions.

导出引用

孔元元, 谢柏涵, 王清, 等. 冻融循环下固化盐渍土强度增长规律及损伤模型验证[J]. 长江科学院院报. 2025, 42(11): 126-132 https://doi.org/10.11988/ckyyb.20240926

KONG Yuan-yuan, XIE Bai-han, WANG Qing, et al. Strength Growth Mechanism and Damage Model Verification of Solidified Saline Soil under Freeze-Thaw Cycles[J]. Journal of Changjiang River Scientific Research Institute. 2025, 42(11): 126-132 https://doi.org/10.11988/ckyyb.20240926

中图分类号： TU448 (盐渍土与地基)

参考文献

列表( 原文顺序 | 文献年度倒序 | 文中引用次数倒序 ) 可视化分析

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摘要

为解决松嫩平原碳酸盐渍土对工程的不利影响,且削弱季节冻土区冻融循环对碳酸盐渍土带来的损伤,采用无机材料石灰和粉煤灰对碳酸盐渍土进行改良。研究了不同改良方案下碳酸盐渍土抗剪强度的变化及其抵抗冻融循环的能力;通过熵权-TOPSIS模型对各改良方案进行评价。结果表明:石灰和粉煤灰均会提升碳酸盐渍土的抗剪强度,但是石灰的改良效果远胜于粉煤灰,石灰会使得碳酸盐渍土的应力-应变曲线变成应变软化型;粉煤灰在提升碳酸盐渍土抵抗冻融损伤能力上表现得比较突出;而双掺石灰和粉煤灰明显兼顾了强度和抵抗冻融损伤能力这2个指标;在考虑力学性能、抗冻融能力以及经济等因素时,石灰和粉煤灰的掺量均为12%的方案最优。

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摘要

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本文引用 [1] 摘要

In Northeast China， the annual temperature difference is relatively large， and the subgrade soil presents freeze-thaw cycle with the change of temperature， belonging to seasonal frozen soil， which is easy to cause serious deformation of subgrade in Northeast China during service， the occurrence of subgrade diseases such as frost heave， frost heave and mud heave leads to the change of soil structure， the reduction of subgrade stiffness， and the deterioration of bearing capacity. The stress-strain relationship can effectively represent the law of stress and deformation of soil， and the establishment of a reasonable freeze-thaw damage model has guiding significance for the structural design of seasonally frozen soil subgrade. Consequence， in order to explore the stress strain relationship and damage mechanism of subgrade soil in seasonal frozen area under different water content under different freeze-thaw cycles and confining pressure，choosing a highway section in Fuxin City， Liaoning Province as the test section， using the ring knife method to select the subgrade soil sample of the test section and freeze-thaw cycle and triaxial compression test， the experiment obtained the relation of the stress-strain curves of subgrade soil under different freeze-thaw cycles and confining pressures. According to the damage mechanics and statistics principles， the Weibull distribution is combined with Lemaitre effective stress principle to establish a damage constitutive model of subgrade soil in the seasonal freezing zone. The results show that the optimum moisture content of subgrade soil in seasonally frozen area is the limit moisture content of its stress-strain curve from strain softening to strain hardening. When the moisture content is less than the optimum moisture content， the peak stress of the curve increases with the decrease of the moisture content， and decreases with the increase of the number of freeze-thaw cycles. When the moisture content of the test piece is greater than the optimum moisture content， the curve has no peak stress with the increase of the moisture content， showing obvious strain hardening characteristics. When the number of freeze-thaw cycles is small and the confining pressure is low， the stress-strain curve of the specimen shows a peak stress， and the curve shows a strain softening feature with the increase of confining pressure， the strength of the specimen increases. Strain hardening is easy to occur when there are many freeze-thaw cycles and large confining pressure. Through comparative analysis， the established damage constitutive model is in good agreement with the test stress-strain curve. It can reflect that the stress-strain curve of subgrade soil in the seasonally frozen area shows a change rule of first increasing and then tending to be stable. And the parameters required by the model can be obtained through triaxial tests， which shows that the model can better describe the stress-strain relationship of subgrade soil in seasonal frozen area， and is practical. In addition， it can be seen from the test results that in order to reduce the impact of freezing and thawing cycles on the subgrade strength in the seasonal freezing area in Northeast China， it is very important to do a good job in the waterproof and drainage of the subgrade in advance for the prevention and treatment of subgrade freezing and thawing diseases.

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