{"title":"Framework for Thaw Consolidation of Fine-Grained Soils","authors":"S. Dumais, J. Konrad","doi":"10.1139/cgj-2022-0502","DOIUrl":null,"url":null,"abstract":"A framework for thaw consolidation of fine-grained soils is proposed. The development of the framework is based on the general definition of large-strain consolidation and on the general behaviour of soils upon thawing. The residual stress and the residual stress curve are used in the framework to define the initial thawed state. The concept of the residual stress is generalized to ice-rich soils by specifying that the residual stress is the effective stress within the soil elements upon thawing rather than the effective stress in the bulk soil. The framework is formulated in terms of σ'_v - e - k_v relationships. The volume change behaviour of ice-poor soils is described by a semi-logarithmic linear relationship. The slope of the relationship is given by the compression index of the thawed soil. For ice-rich soils, a bilinear relationship is adopted. First, drainage of the excess water occurs with no compression of the soil skeleton. Then, water is drained out of the soil upon compression of the soil skeleton in an ice-poor equivalent manner. The hydraulic conductivity relationship of thawed fine-grained soils is defined by a semi-logarithmic linear curve with a slope defined by the hydraulic conductivity change index of the thawed soil.","PeriodicalId":9382,"journal":{"name":"Canadian Geotechnical Journal","volume":"33 1","pages":""},"PeriodicalIF":3.0000,"publicationDate":"2023-08-23","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"1","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Canadian Geotechnical Journal","FirstCategoryId":"89","ListUrlMain":"https://doi.org/10.1139/cgj-2022-0502","RegionNum":3,"RegionCategory":"工程技术","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"ENGINEERING, GEOLOGICAL","Score":null,"Total":0}
引用次数: 1
Abstract
A framework for thaw consolidation of fine-grained soils is proposed. The development of the framework is based on the general definition of large-strain consolidation and on the general behaviour of soils upon thawing. The residual stress and the residual stress curve are used in the framework to define the initial thawed state. The concept of the residual stress is generalized to ice-rich soils by specifying that the residual stress is the effective stress within the soil elements upon thawing rather than the effective stress in the bulk soil. The framework is formulated in terms of σ'_v - e - k_v relationships. The volume change behaviour of ice-poor soils is described by a semi-logarithmic linear relationship. The slope of the relationship is given by the compression index of the thawed soil. For ice-rich soils, a bilinear relationship is adopted. First, drainage of the excess water occurs with no compression of the soil skeleton. Then, water is drained out of the soil upon compression of the soil skeleton in an ice-poor equivalent manner. The hydraulic conductivity relationship of thawed fine-grained soils is defined by a semi-logarithmic linear curve with a slope defined by the hydraulic conductivity change index of the thawed soil.
提出了细粒土解冻固结的框架。框架的发展是基于大应变固结的一般定义和土壤在融化时的一般行为。在框架中使用残余应力和残余应力曲线来定义初始解冻状态。将残余应力的概念推广到富冰土壤中,指出残余应力是融化时土体单元内的有效应力,而不是土体中的有效应力。该框架是用σ'_v - e - k_v关系表示的。贫冰土壤的体积变化行为用半对数线性关系来描述。关系的斜率由解冻土壤的压缩指数给出。对于富冰土壤,采用双线性关系。首先,在不压缩土壤骨架的情况下排水多余的水。然后,在压缩土壤骨架时,水以一种贫冰等效的方式从土壤中排出。细粒土融化后的导电性关系由一条半对数线性曲线定义,其斜率由融化后土壤的导电性变化指数定义。
期刊介绍:
The Canadian Geotechnical Journal features articles, notes, reviews, and discussions related to new developments in geotechnical and geoenvironmental engineering, and applied sciences. The topics of papers written by researchers and engineers/scientists active in industry include soil and rock mechanics, material properties and fundamental behaviour, site characterization, foundations, excavations, tunnels, dams and embankments, slopes, landslides, geological and rock engineering, ground improvement, hydrogeology and contaminant hydrogeology, geochemistry, waste management, geosynthetics, offshore engineering, ice, frozen ground and northern engineering, risk and reliability applications, and physical and numerical modelling.
Contributions that have practical relevance are preferred, including case records. Purely theoretical contributions are not generally published unless they are on a topic of special interest (like unsaturated soil mechanics or cold regions geotechnics) or they have direct practical value.