饱和冻土统一硬化（UH）模型

IF 3.8 2区工程技术 Q1 ENGINEERING, CIVIL

Cold Regions Science and Technology Pub Date : 2024-11-20 DOI:10.1016/j.coldregions.2024.104371

Kesong Tang, Yangping Yao

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引用次数: 0

摘要

冻土由于其复杂的微观机制，其力学行为对温度变化非常敏感。在有季节性冻融循环的地区，冻土与非冻土之间的过渡对其力学特性有显著影响。本研究综合现有理论和数据，对低温对冻土性质的影响进行分类。通过引入温度和未冻水饱和度，将与应力解耦的孔隙比的相变分量与实际孔隙区区分开来，从而实现等效孔隙比的定义。建立了温度与弹塑性变形、低温黏聚和冰偏析等力学性能之间的非线性关系。通过对载荷-温度屈服方程的推导，建立了有效应力和温度双应力变量框架下的弹塑性本构模型。该模型捕获了冻土行为的关键方面，包括由于冰分离和温度引起的强度变化而导致的强度减弱。适用于孔隙水熔点或低于孔隙水熔点的条件，该模型的预测与实验观测结果很好地吻合。

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Unified hardening (UH) model for saturated frozen soils

The mechanical behavior of frozen soils is highly sensitive to temperature variations due to their complex micro-mechanisms. In regions with seasonal freeze-thaw cycles, the transition of soils between frozen and unfrozen states is significantly influencing their mechanical properties. This study synthesizes existing theories and data to categorize the effects of subzero temperatures on the properties of frozen soils. By introducing temperature and unfrozen water saturation, the phase change component of void ratio—decoupled from stress—is distinguished from actual voids, enabling the definition of the equivalent void ratio. Nonlinear relationships between temperature and other mechanical properties including elastoplastic deformation, cryogenic cohesion and ice segregation are established. Through the derivation of a loading-temperature yield equation, an elastoplastic constitutive model within a dual stress-variable framework of effective stress and temperature is established. This model captures key aspects of the behavior of frozen soils, including strength weakening due to ice segregation and temperature-induced strength changes. Applicable to conditions at or below the pore water melting point, the model's predictions align well with experimental observations.

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来源期刊

Cold Regions Science and Technology 工程技术-地球科学综合

CiteScore

7.40

自引率

12.20%

发文量

209

审稿时长

4.9 months

期刊介绍： Cold Regions Science and Technology is an international journal dealing with the science and technical problems of cold environments in both the polar regions and more temperate locations. It includes fundamental aspects of cryospheric sciences which have applications for cold regions problems as well as engineering topics which relate to the cryosphere. Emphasis is given to applied science with broad coverage of the physical and mechanical aspects of ice (including glaciers and sea ice), snow and snow avalanches, ice-water systems, ice-bonded soils and permafrost. Relevant aspects of Earth science, materials science, offshore and river ice engineering are also of primary interest. These include icing of ships and structures as well as trafficability in cold environments. Technological advances for cold regions in research, development, and engineering practice are relevant to the journal. Theoretical papers must include a detailed discussion of the potential application of the theory to address cold regions problems. The journal serves a wide range of specialists, providing a medium for interdisciplinary communication and a convenient source of reference.