考虑颗粒形态的轻生物胶结砂各向异性小应变刚度

IF 4.2 1区 工程技术 Q1 ENGINEERING, GEOLOGICAL Geotechnique Pub Date : 2023-10-12 DOI:10.1680/jgeot.22.00350
Jinquan Shi, Yang Xiao, J. Antonio H. Carraro, Haoyu Li, Hanlong Liu, Jian Chu
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引用次数: 1

摘要

砂土的小应变刚度和刚度各向异性对砂土结构非常敏感,受颗粒形状和胶结程度的影响较大。在本研究中,对不同颗粒形状和生物胶结水平的玻璃砂进行了多向弯曲单元和各向同性压缩试验。系统研究了未处理砂和生物处理砂的小应变刚度和刚度各向异性。采用自然胶结法研究胶结砂的小应变刚度;这可能是一种潜在的方法来复制未受干扰的弱胶结砂的力学行为。试验结果表明,小应变刚度随砂角的增大而增大。提出了非胶结砂剪切波速对颗粒形状参数的不同敏感性。在相同孔隙比状态下,刚度各向异性随砂角的增大而增大,随应力水平的增大而减小。对于轻度生物胶结砂,通过与颗粒间方解石键的生物处理作用,可显著提高砂体的小应变刚度。不同胶结程度的试样,小应变刚度随应力的发展是不同的。刚度各向异性比随着生物胶结水平的增加先增大后减小,即使采用哈丁方程参数A进行归一化也无法改变。
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Anisotropic small-strain stiffness of lightly biocemented sand considering grain morphology
Small-strain stiffness and stiffness anisotropy of a sand are sensitive to the sand fabric, which can be significantly affected by particle shape and cementation. In this study, multidirectional bender element and isotropic compression tests were performed on glass sands with different particle shapes and biocementation levels. The small-strain stiffness and stiffness anisotropy of the untreated and biotreated sands were systematically investigated. A natural cementation process is used to investigate the small-strain stiffness of cemented sand; this might be a potential way to replicate the mechanical behaviour of undisturbed sand with weak cementation. Test results showed that the small-strain stiffness increases with increasing sand angularity. It is proposed that shear wave velocity has different sensitivities to particle shape parameters for uncemented sands. The stiffness anisotropy increases with the increase in sand angularity and decreases with increasing stress levels at an identical void ratio state. For the lightly biocemented sands, the small-strain stiffness can be improved significantly after the biotreatment reaction with the calcite bonds among grains. The development of small-strain stiffness with stress is different for specimens with different cementation levels. The stiffness anisotropy ratio first increases and then decreases with the increase of the biocementation level, which cannot be changed even with normalisation using the parameter A in the Hardin equation.
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来源期刊
Geotechnique
Geotechnique 工程技术-地球科学综合
CiteScore
9.80
自引率
10.30%
发文量
168
审稿时长
7 months
期刊介绍: Established in 1948, Géotechnique is the world''s premier geotechnics journal, publishing research of the highest quality on all aspects of geotechnical engineering. Géotechnique provides access to rigorously refereed, current, innovative and authoritative research and practical papers, across the fields of soil and rock mechanics, engineering geology and environmental geotechnics.
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