Particle breakage of granular soils: changing critical state line and constitutive modelling

When soil particles break, the particle size distribution (PSD) becomes a variable in the same way as other variables like void ratio, soil structure and anisotropy, etc. To consider particle breakage in a constitutive model, we need three key components: (i) quantification of PSD in a realistically...

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Veröffentlicht in:	Acta geotechnica 2022-03, Vol.17 (3), p.755-768
Hauptverfasser:	Tong, Chen-Xi, Zhai, Ming-Yue, Li, Hai-Chao, Zhang, Sheng, Sheng, Daichao
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Sprache:	eng
Schlagworte:	Anisotropy Complex Fluids and Microfluidics Components Constitutive models Deformation Engineering Evolution Foundations Geoengineering Geotechnical Engineering & Applied Earth Sciences Hydraulics Influence Mathematical models Particle size Particle size distribution Pore size Research Paper Size distribution Soft and Granular Matter Soil properties Soil Science & Conservation Soil strength Soil structure Solid Mechanics Stiffness Stresses Void ratio
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creator	Tong, Chen-Xi Zhai, Ming-Yue Li, Hai-Chao Zhang, Sheng Sheng, Daichao
description	When soil particles break, the particle size distribution (PSD) becomes a variable in the same way as other variables like void ratio, soil structure and anisotropy, etc. To consider particle breakage in a constitutive model, we need three key components: (i) quantification of PSD in a realistically simple manner, (ii) evolution of PSD during particle breakage, and (iii) influences of PSD on other soil properties like strength and stiffness. This paper firstly summarizes the latest advances in the first two components, discusses new ways of quantifying PSD effects, and finally presents a new critical state model where the PSD is treated as a variable. In discussing the PSD effects, we focus on the movement of the critical state line (CSL) due to particle breakage. We introduce a new state parameter and a new evolution law of the CSL. We assume that the CSL shifts downwards in the v —ln p space with increasing particle breakage under relatively low stresses, but all the CSLs for different PSDs converge to a steady state at high stresses where particle breakage eventually stops and is no longer the main mechanism for soil deformation. The proposed model is compared with other constitutive model in the literature and validated against experimental data, which demonstrates its satisfactory performance.
doi_str_mv	10.1007/s11440-021-01231-8
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This paper firstly summarizes the latest advances in the first two components, discusses new ways of quantifying PSD effects, and finally presents a new critical state model where the PSD is treated as a variable. In discussing the PSD effects, we focus on the movement of the critical state line (CSL) due to particle breakage. We introduce a new state parameter and a new evolution law of the CSL. We assume that the CSL shifts downwards in the v —ln p space with increasing particle breakage under relatively low stresses, but all the CSLs for different PSDs converge to a steady state at high stresses where particle breakage eventually stops and is no longer the main mechanism for soil deformation. 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This paper firstly summarizes the latest advances in the first two components, discusses new ways of quantifying PSD effects, and finally presents a new critical state model where the PSD is treated as a variable. In discussing the PSD effects, we focus on the movement of the critical state line (CSL) due to particle breakage. We introduce a new state parameter and a new evolution law of the CSL. We assume that the CSL shifts downwards in the v —ln p space with increasing particle breakage under relatively low stresses, but all the CSLs for different PSDs converge to a steady state at high stresses where particle breakage eventually stops and is no longer the main mechanism for soil deformation. 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The proposed model is compared with other constitutive model in the literature and validated against experimental data, which demonstrates its satisfactory performance.</abstract><cop>Berlin/Heidelberg</cop><pub>Springer Berlin Heidelberg</pub><doi>10.1007/s11440-021-01231-8</doi><tpages>14</tpages></addata></record>
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subjects	Anisotropy Complex Fluids and Microfluidics Components Constitutive models Deformation Engineering Evolution Foundations Geoengineering Geotechnical Engineering & Applied Earth Sciences Hydraulics Influence Mathematical models Particle size Particle size distribution Pore size Research Paper Size distribution Soft and Granular Matter Soil properties Soil Science & Conservation Soil strength Soil structure Solid Mechanics Stiffness Stresses Void ratio
title	Particle breakage of granular soils: changing critical state line and constitutive modelling
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