Your search keyword '"Triaxial test"' showing total 2,073 results

1. Breakage Mechanism of Artificial Granular Materials

Author

Fan, Longjiang, Liu, Enlong, Tang, Shijia, Qin, Yanlin, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Lu, Xinzheng, Series Editor, Xiang, Ping, editor, Yang, Haifeng, editor, and Yan, Jianwei, editor

Published

2025

2. Behavior of Normal Strength Concrete Subjected to Triaxial Compression Loading

Author

Titu, Rokibul Hossain, Rashid, Muhammad Harunur, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Lu, Xinzheng, Series Editor, Goel, Manmohan Dass, editor, Biswas, Rahul, editor, and Dhanvijay, Sonal, editor

Published

2025

3. Analysis of the Deformability of Railroad Ballast Based on the Concept of the Shakedown Limit

Author

Gomes, Maelckson Bruno Barros, Guimarães, Antonio Carlos Rodrigues, dos Santos, Juliana Tanabe Assad, do Nascimento, Filipe Almeida Corrêa, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Lu, Xinzheng, Series Editor, Rujikiatkamjorn, Cholachat, editor, Xue, Jianfeng, editor, and Indraratna, Buddhima, editor

Published

2025

4. Smart Pebbles to Monitor Aggregate Response Under Repeated Loading

Author

Husain, Syed Faizan, Abbas, Mohammad Shoaib, Wang, Han, Qamhia, Issam I. A., Tutumluer, Erol, Wallace, John, Hammond, Matthew, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Lu, Xinzheng, Series Editor, Rujikiatkamjorn, Cholachat, editor, Xue, Jianfeng, editor, and Indraratna, Buddhima, editor

Published

2025

5. Effects of fine content on the mechanical properties and breakage behavior of gap-graded coral sand.

Author

Jiang, Jigang, Yang, Yang, and Mao, Wuwei

Abstract

Hydraulically filled coral sand foundations are susceptible to various challenges within intricate marine environment. The friability of coral sand results in the production of large amounts of sub-graded fine particles under external stress. Meanwhile, the continual influence of oceanic forces leads to a gradual erosion of these fine particles from soil. The interaction between these two long-term effects plays a crucial role in particle breakage and soil mechanics of coral sand. To address this issue, consolidated drained triaxial tests and sieving analysis were conducted on the gap-graded coral sand with various fine contents. Three unique test methodologies are devised to alter the fine content, including hydraulic scouring, particle removal and particle replacement. The experimental results revealed that a specific amount of fine particle loss can significantly deteriorate the mechanical properties of dense coral sand. By replacing coarse particles with fine particles, larger strength parameters and less dilation were observed, yet there existed a critical threshold of 60% fine content, beyond which further substitution did not yield additional improvement in soil strength. Particle crushing was primarily concentrated in the middle layer of the specimen, influenced by the development of the shear band. Furthermore, the amount of newly generated finer particles exhibited a positive correlation with the increase in fine content in the initial gap-graded soil. These findings could enhance the understanding of the role that fines plays in determining the mechanical characteristics and particle breakage behavior of coral sand, and thus aid in more accurate assessments and designs of engineering applications involving coral sand. [ABSTRACT FROM AUTHOR]

Published

2024

6. Modeling of Drain Consolidation in the Quick Triaxial Test and Its Analytical Solution.

Author

Chen, Zhibo, Zhu, Jungao, Zheng, Xinjiang, and Wang, Lei

Subjects

*COLUMNS, *ANALYTICAL solutions, *RESEARCH personnel, *SAND, *DRAINAGE

Abstract

Sand columns have been widely used to accelerate drainage and then improving the mechanical properties of soft soil foundations. The sand column has also been introduced into the triaxial test by researchers, in the center of the cylindrical specimen, to greatly accelerate drainage and consolidation process. The objective of this paper is to evaluate the consolidation properties of the triaxial cylindrical specimen considering the presence of a sand column, and then to propose a consolidation model that simulates the consolidation process of the triaxial test. The consolidation equations were derived considering the drainage of the specimen with a sand column composed of both vertical and double‐radial flows. Then the analytical solution of the model was obtained based on specific initial and boundary conditions. The comparison between the consolidation model and the laboratory tests yielded highly consistent. The case study demonstrated that the proposed consolidation model accurately simulates the evolution of average pore pressure and degree of consolidation in triaxial specimens containing a sand column. The studies on the consolidation parameters showed that there were different effects on the drainage rate for the diameter of specimen, the permeability coefficients of specimen and sand column, as well as the radius of the sand column. [ABSTRACT FROM AUTHOR]

Published

2024

7. Failure envelope and strength of dispersive clay/sewage sludge ash/lime.

Author

Shabanzadeh, Hamid and Àtrchian, Mohammad Reza

Abstract

Several methods have been used over time to improve the mechanical properties of fine-grained soils. One of the recently introduced materials for soil stabilization is incinerated sewage sludge ash (ISSA). This material is a by-product of the wastewater treatment process that is usually disposed of during the treatment cycle. This paper investigated the effects of adding the optimum amount of ISSA and a mixture of ISSA with hydrated lime (IL) on the mechanical properties of dispersive fine-grained soil. The effects of curing time on the UCS was also evaluated. The Mohr-Coulomb failure envelope parameters of the mixtures were subsequently estimated based on the performed test results using the Consoli et al (J Mater Civ Eng 27(5):04014174, 2015) method which eliminates the need to perform triaxial tests. The results indicated that ISSA and IL can improve the mechanical characteristics of the dispersive soil effectively and that curing time was substantial for better performance of the treated soil. Finally, the application of the Consoli and others method to predict the failure envelope parameters of the treated soil was evaluated using triaxial tests. The comparison of the results proved the suitability of the proposed method to estimate the failure envelope parameters of the ISSA and IL-treated dispersive soil. [ABSTRACT FROM AUTHOR]

Published

2024

8. Effect of Soil Structure on Penetration Response of Jacked Piles: Model Tests in Structured Clays.

Author

Zhou, Pan, Dai, Feng, and Li, Jingpei

Subjects

*RADIAL stresses, *SCANNING electron microscopes, *CLAY soils, *SOIL structure, *SOIL particles

Abstract

Laboratory model tests were conducted on artificially structured clays using self-developed equipment to better understand the penetration mechanism of jacked piles in structured clays. Two artificially structured clays with the same initial void ratio but different structured strengths, along with one unstructured clay, served as foundation soils for model tests. Cement and salt were selected to simulate the bonding force and macroporous fabric between soil particles in artificially structured clays. The microstructure and mechanical behavior of artificially structured clay samples were analyzed using a scanning electron microscope and a triaxial apparatus. This analysis aimed to evaluate the efficacy of the current method utilized in preparing structured clays and elucidate the evolution mechanism of pile response in structured clays in relation to soil cells. The findings showed that increased confining pressures lead to a more pronounced impact of soil structure on pile jacking force. Unlike the pile shaft, soil structure played a more crucial role in influencing the pile end during jacking, primarily due to the shear-induced structure degradation of clays close to the pile shaft. The axial force and shaft resistance of piles significantly increased with higher cement content. Simultaneously, the mobilization of the increased pile shaft resistance enhanced the nonlinearity in the distribution of axial force along the pile shaft. The pore-water pressure and total radial stress at the pile–soil interface, located 150 mm from the pile toe, experienced respective increases of 1.27 and 1.38 times as the cement content of model soils increased from 0% to 4%. [ABSTRACT FROM AUTHOR]

Published

2024

9. Analysis of the mechanical properties and micro-reinforcement mechanisms of loose accumulated sandy soil improved with polyvinyl alcohol and sisal fiber.

Author

Sang, Ding, Wang, Peiqing, Chen, Liang, Zhang, Wengang, Liu, Zhen, and Wang, Qi

Subjects

SOIL particles, STRESS-strain curves, POLYVINYL alcohol, DEFORMATIONS (Mechanics), ECOLOGICAL regions, SISAL (Fiber), SANDY soils

Abstract

As one of the world's most fragile and sensitive ecological regions, Xizang risks significant environmental damage from using traditional materials, including cement and lime, to improve and reinforce loose accumulated sandy soil slopes. To address this issue, this study utilized a low-concentration biodegradable polyvinyl alcohol (PVA) solution combined with sisal fibers (SFs) to stabilize loose accumulated sand in southeastern Xizang. A series of physical, mechanical, and microscopic analyses was conducted to evaluate the properties of the treated sand. The results indicated the following. 1) The stress-strain curves of the improved samples exhibited an elastic-plastic relationship. Failure was observed in two stages. At a strain of 3% or less, the samples demonstrated elastic deformation with a linear increase in stress, whereas the deviator stress increased rapidly and linearly with an increase in axial strain. Once the strain exceeded 3%, the deformation became plastic with a nonlinear increase in the stress-strain relationship, and the growth rate of the deviator stress gradually decreased and leveled off. 2) Under varying confining pressure conditions, the relationship curve between the maximum (σ1-σ3)max∼σ3 for both untreated loose accumulated sandy soil and soil improved with the PVA solution, and the sisal fiber was approximately linear. 3) The SFs created a skeletal-like network that encased the soil particles, and the hydroxyl functional groups in the PVA molecules bonded with both the soil particles and the fiber surface, thereby enhancing the interfacial properties. This interaction resulted in a tighter connection between the soil particles and SFs, which improved the stability of the structure. 4) The incorporation of a PVA solution and SFs significantly enhanced the mechanical strength and deformation resistance of the loose accumulated sandy soil. The optimal ratio for the improved soil was SP = 3% and SL = 15 mm, which increased the cohesion from 24.54 kPa in untreated loose accumulated sandy soil to 196.03 kPa. These findings could be applied in engineering practices to improve and reinforce loose accumulated sandy soil slopes in southeastern Xizang and provide a theoretical basis for such applications. [ABSTRACT FROM AUTHOR]

Published

2024

10. Triaxial testing and model study on lime modified dispersive soil considering age effects.

Author

He, Jianxin, Gao, Pengzhan, Yang, Haihua, Tian, Weiheng, and Ding, Jinhua

Abstract

This study investigates the influence of age on the mechanical properties of lime-modified dispersed soils through consolidation undrained triaxial tests conducted at various age (t) and lime content (a). Empirical equations for Duncan-Chang model parameters K, n, c, and φ incorporating the age factor were established based on experimental results, focusing on lime modification at 2% content. The stress-strain curves of dispersed soils exhibit strain-hardening characteristics, with stress levels increasing notably with age, displaying significant variation between short and long durations. Conversely, the stress-strain curve for lime-modified dispersed soil at 2% content shows strain-softening behavior. Age exerts a substantial influence on model parameters K, n, c, and φ of the Duncan-Chang model, with a minor impact on Rf. The modified model demonstrates a strong fit to stress-strain curves of lime-modified dispersed soil before reaching failure, validated against experimental data at age of 14 days and 90 days. Importantly, the modified model accurately predicts stress-strain relationships for modified soils over extended age beyond 28 days, providing meaningful insights for the long-term stability assessment of soil-modified structures. [ABSTRACT FROM AUTHOR]

Published

2024

11. Assessment of Anisotropic Elastic Parameters Using Laboratory Triaxial and In-Situ Pressuremeter Tests in Opalinus Clay.

Author

Liu, Lang, Martin, Derek, Giger, Silvio B., and Chalaturnyk, Rick

Subjects

*POISSON'S ratio, *STRAINS & stresses (Mechanics), *YOUNG'S modulus, *MODULUS of rigidity, *ELASTIC modulus

Abstract

Opalinus Clay is a stratified shale that exhibits anisotropic deformation properties. In this work, the transversely isotropic deformation parameters of Opalinus Clay are summarized from recent undrained triaxial test campaigns. Relatively consistent values are found for Poisson's ratios representing different orientations, regardless of the lithofacies and the effective confining stresses used in the tests. Pressuremeter tests were performed at the Mont Terri Rock Laboratory in two boreholes perpendicular and parallel to bedding, respectively. The elastic moduli normal to the borehole wall (borehole moduli) are determined using unloading data obtained at multiple diametric caliper axes and exhibit strong anisotropy for the tests in the borehole parallel to bedding. The anisotropic borehole moduli are predicted based on Amadei and Savage's (Int J Rock Mech Min Sci 28:383–396, 1991. https://doi.org/10.1016/0148-9062(91)90077-Y) analytical solution using the laboratory-derived Poisson's ratios and the shear modulus derived from pressuremeter tests in the borehole perpendicular to bedding. The prediction overestimates the magnitude of the borehole moduli but underestimates their anisotropic ratio compared to that from pressuremeter measurement. Drilling a borehole parallel to the bedding of Opalinus Clay is known to induce a local borehole damage zone preferentially developed normal to bedding. The results from a finite element analysis that incorporates this local damage are in better agreement with the pressuremeter measurement. Highlights: The elastic parameters of Opalinus Clay assessed from laboratory triaxial tests show transversely isotropic (TI) properties with reasonably consistent Poisson's ratios but large scatters of Young's moduli. The elastic moduli determined from pressuremeter tests in boreholes with orientations perpendicular and parallel to the bedding of Opalinus Clay also indicate the TI properties. The anisotropic elastic response observed from the pressuremeter tests can be explained using Amadei and Savage's (1991) solution with laboratory-derived Poisson's ratios. A numerical solution further incorporating the local borehole damage better predicts the anisotropic elastic response from the pressuremeter tests. [ABSTRACT FROM AUTHOR]

Published

2024

12. Study of triaxial loading of segregated granular assemblies through experiments and DEM simulations.

Author

Pola, Venkata Rama Manoj and Annabattula, Ratna Kumar

Abstract

A novel position-dependent body force-based confinement for simulating triaxial tests using the Discrete Element Method is presented. The said method is used to perform triaxial simulations on mono-disperse and segregated assemblies of glass spheres. The macroscopic load response obtained in simulations is validated with the experimental load response. A mesh construction algorithm is presented to check whether the confinement applied in the triaxial simulations is accurate. The particle displacement data obtained from triaxial simulations are used to obtain a particle-wise average strain tensor. This is further used to compare the strain localisation between the mono-disperse and segregated assemblies. It is observed that, in the segregated assembly, the interface between the two particle phases acts as a barrier for strain localisation, and the smaller particles preferentially undergo a higher degree of shear strain on average. [ABSTRACT FROM AUTHOR]

Published

2024

13. Cyclic Behavior and Liquefaction Resistance of Loose Ground Improved by Granular Columns.

Author

Yazdandoust, Majid and Bastami, Amin

Subjects

*CYCLIC loads, *EARTHQUAKE magnitude, *ENERGY dissipation, *SOIL liquefaction, *SAND, *POSSIBILITY

Abstract

A series of undrained cyclic triaxial tests were carried out on loose sand specimens, including encased and non-encased granular columns, to evaluate the cyclic behavior and liquefaction resistance of the ground improved by granular columns. It was found that using geogrid encasements could effectively reduce cumulative settlements and mitigate the liquefaction potential when its tensile stiffness was high enough. Another finding was the inefficiency of flexible geosynthetic encasements to delay and mitigate the liquefaction in granular columns with the possibility of clogging. Findings indicated that the improvement of a loose ground with encased granular columns not only decreased the liquefaction-induced ground deformation but also significantly reduced the effect of earthquake magnitude on the ground deformation. It was also found that using the granular column and encasing it with a high-stiffness encasement not only slowed down the rate of ground softening during the cyclic loading experience but also decreased the dissipation of energy. [ABSTRACT FROM AUTHOR]

Published

2024

14. 非饱和花岗岩残积土的剪切特性与抗剪强度分析.

Author

马勤国, 郭皓公, and 罗晓晓

Abstract

Copyright of Journal of South China University of Technology (Natural Science Edition) is the property of South China University of Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

15. 细粒土体及加载速率对土石混合体力学行为的影响.

Author

王洪兵, 任 禾, 张学杰, 孙文超, 许 凡, 罗安静, and 徐文杰

Subjects

IMPACT (Mechanics), INDUSTRIAL safety, STRUCTURAL engineering, SOIL classification, MIXTURES

Abstract

Copyright of Hydrogeology & Engineering Geology / Shuiwendizhi Gongchengdizhi is the property of Hydrogeology & Engineering Geology Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

16. Effect of High-Stress Levels on the Shear Behavior of Geosynthetic-Reinforced Marine Coral Sands.

Author

Liu, Lixing, Chen, Zhixiong, Ding, Xuanming, and Ou, Qiang

Subjects

DISCRETE element method, DEFORMATIONS (Mechanics), STRAINS & stresses (Mechanics), SHEAR strain, BUILDING design & construction, GEOSYNTHETICS

Abstract

As an important construction material, the mechanical and deformation properties of marine coral sand determine the safety and stability of related island and coastal engineering construction. The porous and easily broken characteristics of coral sand often make it difficult to meet engineering construction needs. In particular, coral sand undergoes a large amount of particle breakage under high-stress conditions, which in turn negatively affects its mechanical and deformation properties. In this study, the macro- and micro-mechanical behavior of geosynthetic-reinforced coral sand under high confining pressure was investigated and compared with unreinforced cases using the three-dimensional discrete element method (DEM), which was verified by indoor triaxial tests. The results showed that the stress–strain responses of unreinforced and reinforced coral sand under high confining pressure showed completely different trends, i.e., the hardening tendency shown in the reinforced case. Geosynthetic reinforcement can significantly inhibit the stress–strain softening and bulging deformation of coral sand under high confining pressure, thus improving the shear mechanical performance of the reinforced sample. At the microscopic scale, high confining pressure and reinforcement affected the contact force distribution pattern and stress level between particles, determining the macroscopic mechanical and deformation performance. In addition, the breakage of particles under high confining pressure was mainly affected by shear strain and reinforcement. The particle fragment distribution, particle gradation, and relative breakage index exhibited different trends at different confining pressure levels. These breakage characteristics were closely related to the deformation and stress levels of unreinforced and reinforced samples. [ABSTRACT FROM AUTHOR]

Published

2024

17. Impact of Non-Linear Contact Models on DEM Simulations of Cemented Angular Limestone Behavior.

Author

Eshraghi, Hamidreza, Pak, Ali, and Motlagh, Nazanin Mahbubi

Subjects

DISCRETE element method, ROLLING contact, SURFACE roughness, SHEAR strength, TENSILE strength

Abstract

Simulation of the mechanical behavior of non-cemented and cemented angular limestone material using the discrete element method (DEM) is carried out in the present study and validated by comparison with the experimental triaxial test results. A rolling resistance contact model with spherical particles has been utilized to simulate non-cemented limestone aggregates. Subsequently, relations have been developed to modify two microparameters, the friction coefficient and rolling friction coefficient, representing the surface roughness and the effect of angular corners of aggregates under various confining pressures as a new approach for high-quality simulations. DEM simulations of triaxial tests were then carried out on crushed limestone samples with 1% and 2% cement contents. Flexible lateral boundaries were used in DEM simulations. The increase in cement content usually causes the augmentation of two parameters: cohesion and tensile strength at the contact areas. This paper demonstrates that combining flat joint and newly enhanced rolling resistance contact models provides an effective approach for simulating angular cemented aggregates with spherical shapes. The numerical results agreed well with the experimental results. An increase in cement content in the samples did not alter the distribution of force chains. However, it did increase the intensity of contact forces, resulting in increased shear strength. Moreover, the rise in cement content delayed the rupture of bonds under tension and shear. With increasing the confining pressure, the number of broken cement bonds under tension reduced, while the number of broken bonds under shear increased. [ABSTRACT FROM AUTHOR]

Published

2024

18. 石灰-沸石粉改良膨胀土强度特性及微观机理研究.

Author

张玉国, 赵春豪, 张兆彬, and 张自来

Abstract

Copyright of Bulletin of the Chinese Ceramic Society is the property of Bulletin of the Chinese Ceramic Society Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

19. 不同应力路径下天然沉积软土的应力应变特性.

Author

朱楠, 吕海军, 刘天韵, and 张晓晓

Subjects

*AXIAL stresses, *STRAIN hardening, *SHEAR strength, *STRAINS & stresses (Mechanics), *CLAY

Abstract

In order to reveal the influence of stress paths on the stress-strain characteristics of natural sedimentary soft soil, physical and mechanical properties, conventional triaxial and stress path tests were carried out on the undisturbed soft soils of Tianjin and Hengshui Lake. The systematical investigation was conducted on the stress-strain characteristics and influencing factors of natural sedimentary soft soil under different stress paths. The main conclusions are as follows: stress-strain characteristics of soft soil are changed by the variation of the structural and bonding characteristics. Under the drainage shear, Tianjin soft soil with weaker structural and bonding characteristics reveals the strain hardening characteristics similar to remolded soil, while Hengshui Lake soft soil with stronger structural and bonding characteristics exhibits the strain softening characteristics of undisturbed soil. Due to the presence of structural and bonding characteristics, natural sedimentary soft soil can hear tensile stress and show expansion deformation. The content of clay particles and colloidal particles of Hengshui Lake soft soil are higher than Tianjin soft soil, exhibiting obvious bonding characteristics, higher shear strength and more significant expansion deformation under the axial unloading stress paths. The conclusions can provide reference for the design calculation and constitutive model of natural sedimentary soft soil. [ABSTRACT FROM AUTHOR]

Published

2024

20. Elastic–Plastic Constitutive Relationship of Polymer Fiber–Reinforced Clay Considering the Effect of Anisotropic Distribution.

Author

Yang, Zhongnian, Sun, Zhenxing, Cai, Guojun, Wang, Chu, Ling, Xianzhang, and Wang, Rongchang

Subjects

*POLYMER clay, *FIBER orientation, *FIBER-reinforced plastics, *FIBER testing, *NUMERICAL calculations

Abstract

Due to their advantages of high rupture strength and long service life, polymer fibers are often used for soil improvement. However, there is no consensus on how the mixing of discrete polymer fibers affects the stress–strain relationship of clays. In this study, a constitutive relationship of polymer fiber‒reinforced clay was established on the basis of the stress–strain relationship between clay and polymer fibers. The elastic–plastic unified hardening (UH) model was employed, and the fiber contribution was introduced based on the UH model. The constitutive relationship of polymer fiber‒reinforced clay considers the anisotropic distribution of the discrete fiber orientation and the relative sliding between the fibers and clay matrix. The model was verified by referring to the results of consolidated undrained (CU) and consolidated drained tests of typical polymer fiber‒reinforced clays in previous studies. A series of CU tests on rubber fiber‒reinforced clay were conducted to validate the model further. The ratio of the simulated results to the experimental results gradually approached 1 with increasing axial strain. The constitutive relationship of polymer fiber‒reinforced clay could provide satisfactory results. Practical Applications: Polymer fiber mixing increases soil strength and enhances the properties of problematic soils, which makes the problematic soils more valuable for engineering applications. Studies have shown that the fibers in the soil tend to be distributed horizontally after the compaction process. With the anisotropic distribution of fiber orientation considered, the authors established a numerical calculation method for the stress–strain relationship of polymer fiber‒reinforced clay. A major objective of this work was to allow the use of computerized numerical analysis methods when performing mechanical analyses of polymer fiber‒reinforced clay, which avoids the need to conduct a large number of shear tests. In this study, a series of consolidated undrained tests of rubber fiber‒reinforced expansive clay were conducted. With the data collected, the numerical calculation method for the stress–strain relationship of polymer fiber‒reinforced clay was verified, and the numerical results agreed with the test results better. [ABSTRACT FROM AUTHOR]

Published

2024

21. Discrete-Element Analysis for Compaction-Induced Stiffness Variation of Ballast Aggregate in Large-Scale Triaxial Testing.

Author

Huang, Shihao and Qian, Yu

Subjects

*COMPACTING, *DENSITY, *BALLAST (Railroads)

Abstract

Large-scale triaxial tests are popular for evaluating the mechanical properties of railroad ballast. The literature shows that different compaction methods have been used to prepare the samples. This research investigates the potential variation caused by different compaction methods, even when the samples are compacted to the same density. A series of triaxial tests are conducted, and the results confirm that the way in which ballast is compacted significantly affects its stiffness, but not its peak strength, as long as the density is consistent. Discrete-element method simulations are performed to explore this phenomenon and discover that stiffness variations are caused by different ways in which particles interlock and arrange themselves during compaction. Based on the findings from this study, it is recommended to consider the influence of compaction methods when conducting large-scale triaxial testing on railroad ballast or when evaluating the test results. [ABSTRACT FROM AUTHOR]

Published

2024

22. Investigation of the particle crushing characteristics of stacked stone materials under different stress path conditions

Author

Guoshen Zhou, Qunwei Wu, Shuai Li, Dongbo Wan, Jieyong You, Danqing Song, Jun Zhao, Xiangcheng Zhang, Pan Shi, and Pengfei Chu

Subjects

Crushed stone aggregates, Particle crushing, Stress path, Plastic work, Triaxial test, Geophysics. Cosmic physics, QC801-809

Abstract

Abstract Stone fill materials are widely used in engineering projects such as earth-rock dams, railways, and highway embankments. Nevertheless, they are susceptible to particle breakage, which can lead to a decline in engineering performance. A complete set of studies on crushed stone aggregates was carried out to investigate particle crushing characteristics under various stress path conditions. To quantify the amount of particle crushing, the relative particle crushing rate was utilized as an indicator. The plastic work performed during the trials was compared across different stress routes, and the relationships between particle crushing and average stress p and generalized shear stress q were investigated. In triaxial testing, the differences in particle crushing behavior under different stress routes were thoroughly examined. The results show that particle crushing is substantially lower in the modelling of a rockfill dam constructed with a core wall and subjected to reservoir water pressure pathways than in conventional triaxial tests. A clear relationship was discovered. Across several stress routes, a clear link between plastic work and the relative particle crushing rate was detected, which was successfully characterized by a power function. Notably, the contributions of different stress components to the overall plastic work varied significantly. The plastic work exerted by the generalized shear stress q accounted for a large percentage of traditional triaxial testing, although the proportion of plastic work given by p and q changed significantly in complex stress path tests. This research enhances the understanding of the particle breakage characteristics of stone fill materials under complex stress paths.

Published

2024

23. Use of Advanced Constitutive Models for the Mechanical Behavior of Soft Soils With Diatoms From Bogotá (Colombia).

Author

Mendoza, Cristhian and de Farias, Márcio Muniz

Abstract

Most constitutive models did not initially consider special behaviors in some soils with singular characteristics (e.g., soft soils with diatom content). For example, at first, these models did not consider the effect of soil structure and viscosity. However, in the last decades, these variables have been incorporated into several constitutive models to describe the mechanical behavior of the soil in its natural state. Structure and viscosity laws that adequately reproduce the soil behavior had to be developed to include these variables. This paper compares the mechanical behavior of soft soils in Bogotá with different constitutive models. Bogotá's soft soils are lacustrine deposits with a high content of diatoms in their structure. Natural soil samples with intact structures show a high‐water content, which can be higher than 300%, liquid limits of up to 400%, void ratios higher than five, and friction angles of almost 40°. In addition, the model validations were made through the simulations of triaxial tests in compression and shear paths. Modified Cam Clay (MCC), hypoplastic (HP), and subloading Cam Clay (SCC) were the constitutive models used. Two models are based on an elastoplastic framework, and the third uses a HP framework. Several lessons were learned from the simulations regarding the strengths and weaknesses of the models compared to the tests carried out. Finally, the extensive discussion revolves around determining the most suitable model for simulating the mechanical behavior of soft soils containing diatoms in Bogotá. [ABSTRACT FROM AUTHOR]

Published

2025

24. The Mineralogical Composition and Mechanical Characteristics of Selected European Coal Mining Waste Samples and Their Experimental Correlation.

Author

Vo, Thanh, Hillier, Stephen, and Rezania, Mohammad

Subjects

*COAL mine waste, *COAL mining, *SPOIL banks, *CLAY minerals, *SPECIFIC gravity

Abstract

Globally, there is a vast amount of coal mining waste (CMW) currently stored in spoil tips and tailing dams, presenting a significant source of potentially recoverable geomaterial for construction and geotechnical applications. In the literature, the heterogeneity in compositional and mechanical properties of CMW has often been mentioned, but their shared characteristics have not been much explored. A research program was carried out to collect seven CMWs from different locations across Europe to estimate their mineralogical make-ups quantitatively using powder characterization tests and to determine their mechanical parameters using triaxial tests. It was found that all the seven European CMWs collected share several compositional patterns with each other and with non-European CMWs reported the literature, including the abundance of SiO2 and Al2O3 , quartz and clay minerals, and varying levels of organic carbon content. The results of triaxial compression tests on five of the seven European CMWs collected show them possessing a reasonably high triaxial-estimated friction angle when sheared to a large strain. Some authors previously reached similar conclusion, but the experimental data from this study show a much smaller spread, indicating that the tested CMW particles had not been greatly affected by in situ weathering. Moreover, the specific gravity of the collected CMWs correlates strongly with their organic carbon content. Their triaxial-estimated friction angles at large strain correlate poorly with their alumina contents but correlate positively with the ratio of quartz mineral to the sum of clay minerals and amorphous (organic) fraction in them. Implications of these test results on their possible practical applications are also examined and discussed. [ABSTRACT FROM AUTHOR]

Published

2025

25. Strength and deformation characteristics of waste mud–solidified soil

Author

Yan Tang, Han Jiang, Zide Yang, Shiyao Xiong, Gaofeng Xu, Junhao Chen, and Shi Shu

Subjects

Waste mud, Solidification, Unconfined compressive strength, Compression coefficient, Triaxial test, Resonant column test, Medicine, Science

Abstract

Abstract The treatment, disposal, and resource utilization of waste mud are challenges for engineering construction. This study investigates the road performance of waste mud–solidified soil and explains how solidifying materials influence the strength and deformation characteristics of waste mud. Unconfined compressive strength tests, consolidated undrained triaxial shear tests, resonant column tests, and consolidation compression tests were conducted to evaluate the solidification effect. The test results show that with an increase in cement content from 5 to 9%, the unconfined compressive strength of the waste mud–solidified soil increased by over 100%, the curing time was extended from 3 to 28 days, and the unconfined compressive strength increased by approximately 70%. However, an increase in initial water content from 40 to 60% reduced the unconfined compressive strength by 50%. With the increase of cement content from 5 to 9%, the cohesion and friction angles increased by approximately 78% and 24%, respectively. The initial shear modulus under dynamic shear increased by approximately 38% and the shear strain corresponding to a damping ratio decay to 70% of the initial shear modulus decreased by nearly 11%. The compression coefficient decreased by approximately 55%. Scanning electron microscopy and X-ray diffraction tests showed that a higher cement content led to the formation of more hydration reaction products, especially an increase in the content of AlPO4, which can effectively fill the pores between soil particles, enhance the bonding between soil particles, and form a skeleton with soil particles to improve compactness. Consequently, the strength of the waste mud–solidified soil increased significantly while its compressibility decreased. This study can provide data support for dynamic characteristics of waste mud solidified soil subgrade.

Published

2024

26. Experimentelle Untersuchungen zum Einfluss von Geogittern in ungebundenen Tragschichten.

Author

Bräunig, Claudia, Herle, Ivo, and Weisemann, Ulrike

Subjects

*RAILROAD design & construction, *CYCLIC loads, *FAILED states, *GEOGRIDS, *SUBSOILS

Abstract

Experimental studies on the influence of geogrids in unbound base layers In railroad construction, base layers of unbound coarse‐grained material are usually installed between the existing subsoil and the rail track. Geosynthetics, in particular geogrids, are used to improve the system behaviour. The reduction of the base layer thickness by the geogrid is based on empirical approaches. The influence of the geogrid on the load‐bearing behavior of a base course is to be quantified by experimental investigations. The investigation is performed using a downscaled base course material and geogrid. For this purpose, monotonic and cyclic triaxial tests were performed to demonstrate the failure and the cyclic loading behaviour. In the monotonic triaxial tests the specimens were sheared to failure. The positive influence of the geogrids compared to the unreinforced specimens could be quantified. Since the in‐situ stresses are mainly in the service load range and thus the failure state is not reached, but the stress follows a high number of load cycles, cyclic triaxial tests were performed. The test specimens were loaded cyclically in order to investigate the influence of the geogrid on the deformation accumulation. The cyclically loaded specimens thus show the influence of the geogrid on deformation accumulation. As a result, a reduction in deformation accumulation due to the geogrid could be demonstrated. [ABSTRACT FROM AUTHOR]

Published

2024

27. Crushing and mechanical characteristics of coral sands under various stress paths.

Author

Peng, Weike and Zhang, Jiru

Subjects

*CORALS, *SAND, *STRAINS & stresses (Mechanics), *EQUATIONS, *FORECASTING

Abstract

Coral sand is known to have stress path dependence and fragility. In this research, a series of drained triaxial tests were conducted to explore stress path effects on the mechanical and particle breakage characteristics of coral sands. Several mechanical characteristics, such as critical state, strength, and dilatancy characteristics were studied. The results revealed that the dilatancy behaviors, stress-strain responses, and crushing of coral sands were strongly affected by consolidation stress and stress path. The critical state lines of coral sands were straight in p'-q space and e-(p'/Pa)0.44 plane regardless of stress path. Based on these characteristics, a dilatancy equation was derived and validated through test results. The developed dilatancy equation could predict the dilatancy relationships of coral sands under various stress paths. [ABSTRACT FROM AUTHOR]

Published

2024

28. A Simplified Calculation Method for the Shear Strength of Unsaturated Silt.

Author

Yang, Jiawang, Meng, Weixu, Li, Yonghui, Sun, Liqin, and Li, Xin

Subjects

*SHEAR strength, *SILT

Abstract

The matric suction must be measured when calculating the shear strength of unsaturated silt, but the measurement method is cumbersome and time-consuming. The saturation degree of silt is easily measured; therefore, a simplified calculation method for the shear strength of unsaturated silt using the saturation degree instead of matric suction is valuable in practical engineering. A new calculation method based on the saturation degree of silt is proposed to determine the smooth transition from a saturated to an unsaturated state. Suitable parameters for unsaturated Zhengzhou silt are determined, and the results of an unsaturated triaxial test and the soil–water characteristic curve are used to establish the proposed calculation method. A comparison of the results of Vanapalli's method and the simplified calculation method indicates high consistency and a low error. Therefore, the simplified method is more suitable for practical applications than Vanapalli's method. [ABSTRACT FROM AUTHOR]

Published

2024

29. Analysis of the Stability of a High Fill Slope under Different Gradients and Precipitation Conditions.

Author

Zhang, Hongda, Zhang, Chengda, Zheng, Weiqiang, Wang, Xiaoquan, and Zhang, Jiangwei

Subjects

SLOPES (Soil mechanics), SLOPE stability, SAFETY factor in engineering, FAILURE mode & effects analysis, RAINFALL

Abstract

The stability problem of high fill slopes has always been a research hotspot. Its failure mechanism is complex and prominent, featuring strong concealment, a short occurrence time and great harmfulness. In this paper, the stability of a high fill slope under rainfall conditions will be studied by using indoor tests, numerical simulations, etc. The study is based on a high fill slope in Yichang City. The evolution law of high fill slope stability under the maximum rainfall condition is revealed. The results show the following: The influence of moisture content on stress–strain curves is reflected in both the curve's shape and the peak value of deviatoric stress. Under the constraint of confining pressure, the curve decreases and the peak value of deviatoric stress decreases with the increase of moisture content at the same confining pressure. The safety factor obtained by a rigid body limit equilibrium analysis and numerical calculation indicates that the safety factor for a 30° slope meets the requirements for slope stability evaluation and remains in a fundamentally stable state. An on-site investigation suggests that surface failure and shallow failure may be primary failure modes for this slope; therefore, it is recommended to implement slope protection measures. This study provides valuable references for similar high fill slopes. [ABSTRACT FROM AUTHOR]

Published

2024

30. Experimental Study on Static and Dynamic Characteristics of Sand–Clay Mixtures with Different Mass Ratios.

Author

Cheng, Ye and Yang, Jinghu

Abstract

The alteration of soil static and dynamic characteristics induced by clay content constitutes a crucial issue in the realm of disaster prevention and mitigation within geotechnical engineering. The static and dynamic characteristics of mixed soils with varying sand–clay contents were investigated through the design and implementation of static and dynamic triaxial tests. The relationship between clay content and soil resistance to liquefaction was investigated, with an analysis of the influence of clay content on soil strength and static liquefaction performance. Furthermore, the study examined the soil's resistance to liquefaction under dynamic constitutive and cyclic loading conditions for soils with varying clay content. Results indicate that stress–strain curves for samples with varying clay content exhibit a consistent trend, with the lowest tangent modulus and peak strength observed in samples containing 30% clay. Increasing clay content diminishes soil's resistance to liquefaction under static loading conditions. Higher confining pressures correspond to larger tangent moduli and peak deviating stresses in triaxial shear tests. Dynamic shear modulus decreases as clay content increases, whereas damping ratio decreases accordingly. Soil gradation significantly affects liquefaction-induced deformation, with the sample containing 30% clay experiencing the fastest increase in pore water pressure during testing failure, accompanied by fewer cyclic loading cycles until failure occurs. Improving soil gradation and adjusting the sand–clay ratio are beneficial for enhancing both soil strength and its resistance to liquefaction. [ABSTRACT FROM AUTHOR]

Published

2024

31. Engineering Properties of Tertiary Semi-Diagenetic Rock and Risk Analysis of Water Inrush Disaster in Wangjiazhai Tunnel.

Author

XU Hua, LIU Yushi, WEI Meng, WANG Qiuyi, and ZHANG Haitao

Abstract

Tertiary semi-diagenetic rocks were sampled from the water-rich section of the Wangjiazhai tunnel for particle screening, X-ray diffraction, and scanning electron microscopy tests. Based on the dry density of the field samples, remolded samples were prepared for triaxial compression tests to examine their mineral composition, microstructure, and mechanical properties. Finally, a construction disaster analysis of the tunnel was conducted using Mod-Flow simulation of groundwater levels. The research findings reveal the following: (1) The grading of tertiary semi-diagenetic rocks from the Wangjiazhai tunnel is uneven, with weak cementation characteristics leading to notable water sensitivity and water softening under low moisture content. As moisture content increases, the shear strength of the samples first rises and then declines, peaking at 459.03 kPa when the moisture content is 11%. When the moisture content is below 12%, clay minerals form cements that fill particle gaps, enhancing sample cohesion. However, with further moisture increase, a large volume of free water accumulates in the particle gaps, disrupting the cementation structure and significantly reducing shear strength. (2) The water inflow simulation results for the Wangjiazhai tunnel indicate that water inflows in two typical water-rich sections are 2 805 and 5 025 m³/d, respectively, suggesting a high likelihood of water inflow disasters during tunnel excavation, with substantial water volumes involved. (3) The physico-mechanical properties of tertiary semi-diagenetic rocks show strong water sensitivity and a tendency to soften in water. The high-pressure, waterrich environment, coupled with engineering disturbances, are the primary factors inducing geological disasters during the Wangjiazhai tunnel excavation. [ABSTRACT FROM AUTHOR]

Published

2024

32. Evaluation of Shear Strength and Stiffness of a Loess–Sand Mixture in Triaxial and Unconfined Compression Tests.

Author

Tankiewicz, Matylda, Kowalska, Magdalena, and Mońka, Jakub

Subjects

*POISSON'S ratio, *YOUNG'S modulus, *VALUE engineering, *SHEAR strength, *LOESS, *INTERNAL friction

Abstract

Mechanical soil parameters are not constants and can be defined in various ways. Therefore, determination of their values for engineering practice is difficult. This problem is discussed based on results of piezoceramic element tests and triaxial tests (unconfined and confined) on loess specimens improved by compaction and sand admixture (20% by weight). The study indicated also the effectiveness of this simple method of loess stabilization. The influence of specimen size, draining conditions, stress and strain state, and different calculation methods on the evaluation of basic mechanical parameters were analyzed. The initial shear and Young's moduli, the degradation of secant moduli with strain, tangent moduli, and Poisson' ratio were determined. The results showed that the shear strength parameters are much less sensitive to the test variables than the stiffness parameters are. In triaxial tests, the strength criterion adopted, the sample size, and the drainage conditions influenced the measured value of cohesion, with a much smaller impact on the angle of internal friction. On the other hand, the adopted definition of the parameter and the range of strains had the greatest influence on the value of the stiffness modulus. Moreover, larger specimens were usually found to be stiffer. [ABSTRACT FROM AUTHOR]

Published

2024

33. A method to evaluate the capillary stress tensor at failure in unsaturated soils.

Author

Prunier, Florent, Branque, Denis, Duriez, Jérôme, and Darve, Félix

Subjects

*STRAINS & stresses (Mechanics), *DISCRETE element method, *CAPILLARIES, *STRAIN tensors, *SOILS

Abstract

This paper aims to provide a better understanding of the mechanisms that make it difficult to interpret the behavior of unsaturated soils using an effective stress principle. The main difficulty is that some deformed states of the unsaturated medium may not be statically admissible in saturated conditions. Therefore, we introduce the notions of total strain, which is measured at the boundary of the sample; effective strain, which is conjugated to the effective stress of the solid skeleton; and capillary strain, which results from the capillary forces. Recent results using the discrete element method prove that the effective strain can still be identified with the total strain in 'small' strains and at failure. Consequently, we propose to interpret the behavior of unsaturated soils on the basis of the principle of effective stress revisited with the theory of multiphase media and to identify the total and effective strain tensors in a first simplified approach. A conceptual experimental procedure is proposed to assess what we call the capillary tensor, using existing experimental devices. We propose certain hypotheses that allow engineers to numerically bound this capillary tensor at failure by knowing the total stress state measured at failure and the effective failure envelope in saturated conditions. [ABSTRACT FROM AUTHOR]

Published

2024

34. Internal erosion of a gap-graded soil and influences on the critical state.

Author

Li, Shijin, Russell, Adrian R., and Muir Wood, David

Subjects

*SOIL erosion, *STRAINS & stresses (Mechanics), *SPECIFIC gravity, *PARTICLE size distribution, *INFRASTRUCTURE (Economics)

Abstract

Water retaining structures are critical elements of civil infrastructure. Internal erosion of soils forming the containment structures may occur progressively and lead to expensive maintenance costs or failures. The strength, stress–strain behavior and critical state of soils which have eroded, as well as the characteristics of the erosion, may be affected by hydraulic gradient, confining stress and relative density of the soil at the start of the erosion. Here, erosion and triaxial tests have been conducted on gap-graded soil samples. The tests and results are novel as the samples were prepared to be homogenous post-erosion and prior to triaxial testing by adopting a new sample formation procedure. The post-erosion homogeneity was evaluated in terms of particle size distribution and void ratio along a sample's length. The erosion-induced mechanical property changes can then be linked to a measure of initial state, more reliably than when erosion causes samples to be heterogeneous. The results show that erosion causes the critical state line in the compression plane to move upwards. The movement is lesser than the increase in void ratio caused by erosion. The state parameter is therefore reduced, consistent with the soil's reduced peak strength and its less dilative response. Regarding the erosion characteristics, the flow rate decreases with the increase in initial relative density or effective stress, but increases with the increase in the hydraulic gradient being applied. The cumulative eroded soil mass increases with the increase in hydraulic gradient and decreases with the increase in initial density and effective confining stress. [ABSTRACT FROM AUTHOR]

Published

2024

35. Modeling a Flexible Membrane for Triaxial Tests with Coupled FDM–DEM: Considering Realistic Particle Shape Effects.

Author

Wu, Mengmeng, Fan, Yuanjing, Wang, Jianfeng, and Yin, Zhen-Yu

Subjects

*FINITE difference method, *DISCRETE element method, *MECHANICAL behavior of materials, *SOIL particles, *GRANULAR materials, *PARTICLE analysis, *MASS transfer

Abstract

Particle morphology plays a crucial role in determining the mechanical behavior of granular materials. This paper focused on investigating the effects of boundary conditions on the triaxial mechanical properties of soil samples, with particular consideration given to the influence of particle shape. To achieve this, a numerical model was proposed, which couples the finite difference method (FDM) and the discrete element method (DEM) to simulate the behavior of a rubber membrane and soil particles, respectively. The particle morphology was accurately reconstructed using spherical harmonics (SH) analysis, and the shell cells in the FDM were utilized to construct the boundary modeling. Through a series of simulations, the macroscopic and microscopic mechanical responses of soil particles, both within and outside the shear band, were investigated. The obtained simulation results were then compared with those derived from the DEM simulation using a particle-based membrane. The research findings pertaining to the influence of boundary conditions and particle shape provide significant contributions to our understanding of granular material behavior. These findings offer valuable insights that can be applied in the design and analysis of geotechnical structures. [ABSTRACT FROM AUTHOR]

Published

2024

36. 基于PFC 模拟的饱和粉砂强度折减范围研究.

Author

闫景晨, 马苗苗, and 陈秀楠

Subjects

DISCRETE element method, GRANULAR flow, WATERLOGGING (Soils), FUNCTIONAL equations, SOIL particles

Abstract

Copyright of China Sciencepaper is the property of China Sciencepaper and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

37. Mechanical Response Characteristics and Tangent Modulus Calculation Model of Expansive-Clay Unloading Stress Path.

Author

Peng, Shilong, Li, Zhijun, Cheng, Hua, Xu, Yuhao, Zhang, Ting, and Cao, Guangyong

Subjects

INTERNAL friction, SOIL particles, FAILURE mode & effects analysis, GEOTECHNICAL engineering, LOADING & unloading

Abstract

As a special type of clay, expansive clay is widely distributed in China. Its characteristics of swelling and softening when meeting water and shrinking and cracking when losing water bring many hidden dangers to engineering construction. Expansive clay is known as "engineering cancer", and in-depth research on the unloading mechanical response characteristics and the unloading constitutive relationships of expansive clay is a prerequisite for conducting geotechnical engineering design and safety analysis in expansive-soil areas. In order to obtain the unloading mechanical response characteristics and the expression of the unloading tangent modulus of expansive clay, typical expansive clay in the Hefei area was taken as the research object, and triaxial unloading stress path tests were conducted. The stress–strain properties, microstructures, macro failure modes, and strength indexes of the expansive clay were analyzed under unloading stress paths. Through an applicability analysis of several classical soil strength criteria, an unloading constitutive model and the unloading tangent modulus expression of the expansive clay were constructed based on the Mohr–Coulomb (hereinafter referred to as "M-C") criterion, the Drucker–Prager (hereinafter referred to as "D-P") criterion, and the extended Spatial Mobilized Plane (hereinafter referred to as "SMP") criterion theoretical frameworks. The following research results were obtained: (1) The stress–strain curves of the three stress paths of the expansive clay were hyperbolic. The expansive clay showed typical strain-hardening characteristics and belonged to work-hardening soil. (2) Under the unloading stress paths, the soil particles were involved in the unloading process of stress release, and the failure samples showed obvious stretching, curling, and slipping phenomena in their soil sheet elements. (3) Under both unloading stress paths, the strength of the expansive clay was significantly weakened and reduced. Under the lateral unloading paths, the cohesive force (c) of the expansive clay was reduced by 32.7% and the internal friction angle (φ) was increased by 19% compared with those under conventional loading, while under the axial unloading path, c was reduced by 63.5% and φ was reduced by 28.7%. (4) For typical expansive clay in Hefei, the conventional triaxial compression (hereinafter referred to as "CTC") test, the reduced triaxial compression (hereinafter referred to as "RTC") test, and the reduced triaxial extension (hereinafter referred to as "RTE") test stress paths were suitable for characterization and deformation prediction using the M-C strength criterion, D-P strength criterion, and extended SMP strength criterion, respectively. (5) The derived unloading constitutive model and the unified tangent modulus formula of the expansive clay could accurately predict the deformation characteristics of the unloading stress path of the expansive clay. These research results will provide an important reference for future engineering construction in expansive-clay areas. [ABSTRACT FROM AUTHOR]

Published

2024

38. 三轴试验橡皮膜与滤纸修正比较分析.

Author

杨兴文, 代云霞, and 马峰

Abstract

Copyright of Guangdong Architecture Civil Engineering is the property of Guangdong Architecture Civil Engineering Editorial Office and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

39. Strength and deformation characteristics of waste mud–solidified soil.

Author

Tang, Yan, Jiang, Han, Yang, Zide, Xiong, Shiyao, Xu, Gaofeng, Chen, Junhao, and Shu, Shi

Subjects

*MODULUS of rigidity, *DEFORMATIONS (Mechanics), *SOIL particles, *SHEAR strain, *SOILS

Abstract

The treatment, disposal, and resource utilization of waste mud are challenges for engineering construction. This study investigates the road performance of waste mud–solidified soil and explains how solidifying materials influence the strength and deformation characteristics of waste mud. Unconfined compressive strength tests, consolidated undrained triaxial shear tests, resonant column tests, and consolidation compression tests were conducted to evaluate the solidification effect. The test results show that with an increase in cement content from 5 to 9%, the unconfined compressive strength of the waste mud–solidified soil increased by over 100%, the curing time was extended from 3 to 28 days, and the unconfined compressive strength increased by approximately 70%. However, an increase in initial water content from 40 to 60% reduced the unconfined compressive strength by 50%. With the increase of cement content from 5 to 9%, the cohesion and friction angles increased by approximately 78% and 24%, respectively. The initial shear modulus under dynamic shear increased by approximately 38% and the shear strain corresponding to a damping ratio decay to 70% of the initial shear modulus decreased by nearly 11%. The compression coefficient decreased by approximately 55%. Scanning electron microscopy and X-ray diffraction tests showed that a higher cement content led to the formation of more hydration reaction products, especially an increase in the content of AlPO4, which can effectively fill the pores between soil particles, enhance the bonding between soil particles, and form a skeleton with soil particles to improve compactness. Consequently, the strength of the waste mud–solidified soil increased significantly while its compressibility decreased. This study can provide data support for dynamic characteristics of waste mud solidified soil subgrade. [ABSTRACT FROM AUTHOR]

Published

2024

40. Shear behavior of undisturbed expansive soil under plane strain condition subjected to medium strain rate.

Author

Gao, Zhiao, Kong, Lingwei, Wang, Shuangjiao, and Li, Tianguo

Abstract

Rapid dynamic loads, such as those caused by earthquakes or traffic, induce medium strain rates in expansive soil, impacting its mechanical properties, which are vital for geotechnical engineering design. This study aims to deepen understanding of the rate effect on expansive clay under plane strain conditions. It conducts various isotropic triaxial and plane strain shearing tests at different medium strain rates. Post-testing, the microstructures of the clay, affected by varying shearing rates, are examined using scanning electron microscope and nuclear magnetic resonance. The experimental findings revealed that the strength at higher strain rates surpasses that at lower ones. In addition, the strength under plane strain at the same consolidation stress level exceeds that under triaxial loading. The strain rate effect is more pronounced in the clay studied under low consolidation pressure, which is more significant in the triaxial state than under plane strain. Excess pore water pressure initially peaks at low strain rates before decreasing but increases at higher strain rates. The specimen’s intermediate principal stress coefficient (b) rises with the increase in consolidation pressure and strain rate. In addition, the expansion of fissures and changes in internal structure account for the strain rate effect in undisturbed expansive soil under specific loading rates. These new insights aid in better understanding the behavior of expansive clay under medium strain rates, enabling engineers to establish appropriate design parameters and criteria. This ensures the safety and stability of structures under dynamic loading. [ABSTRACT FROM AUTHOR]

Published

2024

41. 高温高含冰量冻结砂土的三轴压缩力学特性.

Author

马付龙, 刘恩龙, 王 丹, 康 建, and 宋丙堂

Abstract

Copyright of Journal of Harbin Institute of Technology. Social Sciences Edition / Haerbin Gongye Daxue Xuebao. Shehui Kexue Ban is the property of Harbin Institute of Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

42. COHESIVE SOIL BEHAVIOR UNDER CYCLIC LOADING IN UNDRAINED CONDITIONS.

Author

Głuchowski, Andrzej, Šadzevičius, Raimondas, Varnas, Nerijus, and Sas, Wojciech

Subjects

CYCLIC loads, SOIL creep, PLASTICS, SOILS

Abstract

In this paper, a study of the cyclic plastic creep phenomenon during cyclic loading was performed. The plastic creep phenomena in the field of soil cyclic loading are defined as a process that occurs under a medium stress state and leads to excessive accumulation of plastic strains. Recent literature shows the existence of plastic creep, which is a part of the shakedown theory for cohesive soils. Nevertheless, when the soil is subjected to a relatively small stress state, the axial plastic strain may occur as a phenomenon called abation, where plastic strain increment occurs in a constant decreasing manner. Cyclic triaxial tests were performed to understand the abation. The results indicate a specific phase in soil response, such as pre-failure stages marked by pore pressure increase and subsequent effective stress reduction, indicating a steady state during repeating loading. In this paper, the proposition of a cyclic plastic creep mechanism based on test results is presented. The soil response was divided into three phases based on the pore pressure, stress paths, resilient modulus, and plastic strain change analysis. [ABSTRACT FROM AUTHOR]

Published

2024

43. Evaluation of the damping ratio of compacted sodium and calcium bentonites in unsaturated conditions

Author

X. Pintado, S. Kumpulainen, E. Romero, J. Suriol, A. Lloret, R.C. Weber, B.N. Madhusudhan, A. Ferrari, J. Kim, K. Koskinen, and V. Heino

Subjects

Resonant column test, Hollow cylinder test, Triaxial test, Engineered barrier system, Damping ratio, Engineering geology. Rock mechanics. Soil mechanics. Underground construction, TA703-712

Abstract

Bentonites are going to be part of the Engineered Barrier System (EBS) in deep geological disposal facilities for the safe disposal of spent nuclear fuel. Some of these repositories might be constructed in tectonically active locations, and some other repository locations might have seismic risks in future related to climate changes (e.g. glaciations).The damping ratio is one of the parameters considered in dynamic analysis, and it can be measured by different methods. In this work, the damping ratio was measured in two different bentonites with the resonant column device and in one of these bentonites, it was also measured with the hollow cylinder, simple shear and triaxial tests in unloading–reloading paths. The results are presented in Pintado et al. (2019; 2023). The tests were carried out at different laboratories.The samples were compacted at different dry densities and degrees of saturation and tested with different confinement pressures and strain levels to study the influence of the shear strain, degree of saturation, dry density and confinement pressure and also the influence of the test method. The two studied bentonites had different plasticity indices which was also considered in the analysis.The results showed a clear dependence of the damping ratio on the confinement pressure and the shear strain but not as clear on the degree of saturation, the dry density and the plasticity index. The damping ratio measured by the hollow cylinder test followed the tendency of the resonant column results. The triaxial test presented larger values of damping ratios than following the tendency of the hollow cylinder and resonant column tests. The simple shear test did not follow the tendency of the other tests, presenting lower damping ratio values. All tests presented large scatter.

Published

2024

44. Analysis of the mechanical properties and micro-reinforcement mechanisms of loose accumulated sandy soil improved with polyvinyl alcohol and sisal fiber

Author

Ding Sang, Peiqing Wang, Liang Chen, Wengang Zhang, Zhen Liu, and Qi Wang

Subjects

southeastern xizang, loose accumulated sandy soil, polyvinyl alcohol, sisal fiber, triaxial test, mechanism analysis, Physics, QC1-999

Abstract

As one of the world’s most fragile and sensitive ecological regions, Xizang risks significant environmental damage from using traditional materials, including cement and lime, to improve and reinforce loose accumulated sandy soil slopes. To address this issue, this study utilized a low-concentration biodegradable polyvinyl alcohol (PVA) solution combined with sisal fibers (SFs) to stabilize loose accumulated sand in southeastern Xizang. A series of physical, mechanical, and microscopic analyses was conducted to evaluate the properties of the treated sand. The results indicated the following. 1) The stress-strain curves of the improved samples exhibited an elastic-plastic relationship. Failure was observed in two stages. At a strain of 3% or less, the samples demonstrated elastic deformation with a linear increase in stress, whereas the deviator stress increased rapidly and linearly with an increase in axial strain. Once the strain exceeded 3%, the deformation became plastic with a nonlinear increase in the stress-strain relationship, and the growth rate of the deviator stress gradually decreased and leveled off. 2) Under varying confining pressure conditions, the relationship curve between the maximum (σ1-σ3)max∼σ3 for both untreated loose accumulated sandy soil and soil improved with the PVA solution, and the sisal fiber was approximately linear. 3) The SFs created a skeletal-like network that encased the soil particles, and the hydroxyl functional groups in the PVA molecules bonded with both the soil particles and the fiber surface, thereby enhancing the interfacial properties. This interaction resulted in a tighter connection between the soil particles and SFs, which improved the stability of the structure. 4) The incorporation of a PVA solution and SFs significantly enhanced the mechanical strength and deformation resistance of the loose accumulated sandy soil. The optimal ratio for the improved soil was SP = 3% and SL = 15 mm, which increased the cohesion from 24.54 kPa in untreated loose accumulated sandy soil to 196.03 kPa. These findings could be applied in engineering practices to improve and reinforce loose accumulated sandy soil slopes in southeastern Xizang and provide a theoretical basis for such applications.

Published

2024

45. Discussion of "A 3D image-based method to measure soil stiffness in triaxial tests" by Wang et al. 2024 (DOI: /10.1007/s11440-023-01977-3).

Author

Li, Lin

Subjects

*DIGITAL image correlation, *CAMERA calibration, *THREE-dimensional imaging, *STRAINS & stresses (Mechanics), *POINT cloud, *RAY tracing

Abstract

Wang et al. (2024) proposed a new method to measure soil stiffness through triaxial tests. This discussion illustrates some limitations of the proposed method and details several modifications on the post-image analysis process to enhance its capability. These modifications include the introduction of true stereophotogrammetry for camera and triaxial cell wall orientation, optical ray tracing technique for optical ray reconstruction, and three-dimensional digital image correlation (3D-DIC) for full-field two-dimensional (2D) point cloud generation. With these modifications, the capability of the new method can be significantly improved from only local strain to full-field deformation measurement at a higher accuracy and resolution. [ABSTRACT FROM AUTHOR]

Published

2024

46. Experimental Study on Parameters of Hardening Soil Model with Small Strain Stiffness for Muddy Silty Clay and Silty Sandy Soil in Yangtze Floodplain Area

Author

Wang, Yaning, Wei, Desheng, Zhai, Lei, Qin, Huilai, Chen, Zheng, Zhu, Yuxuan, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Lu, Xinzheng, Series Editor, and Feng, Guangliang, editor

Published

2024

47. Performance of Ganga Sand with Bentonite as a Landfill Liner Material

Author

Kumar, Rajiv, Kumari, Sunita, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Jose, Babu T., editor, Sahoo, Dipak Kumar, editor, Shukla, Sanjay Kumar, editor, Krishna, A. Murali, editor, Thomas, Jimmy, editor, and Veena, V., editor

Published

2024

48. Comparison of Reconstituted Normally Consolidated Kaolinite and Illite in CIU Triaxial Tests Showcasing the Influence of Pore Fluid’s Salinity

Author

Schröder, Maximilian, Grabe, Jürgen, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Duc Long, Phung, editor, and Dung, Nguyen Tien, editor

Published

2024

49. Undrained Shear Strength Increase of Clay Among SCPs Examined in the Triaxial Cell

Author

Watabe, Yoichi, Ohno, Aika, Togiya, Tomoka, di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Duc Long, Phung, editor, and Dung, Nguyen Tien, editor

Published

2024

50. Stress–Strain Behavior of Geogrid Reinforced Steel Slag in Triaxial Test Condition

Author

Sarkar, S., Hegde, A., di Prisco, Marco, Series Editor, Chen, Sheng-Hong, Series Editor, Vayas, Ioannis, Series Editor, Kumar Shukla, Sanjay, Series Editor, Sharma, Anuj, Series Editor, Kumar, Nagesh, Series Editor, Wang, Chien Ming, Series Editor, Cui, Zhen-Dong, Series Editor, Hazarika, Hemanta, editor, Haigh, Stuart Kenneth, editor, Chaudhary, Babloo, editor, Murai, Masanori, editor, and Manandhar, Suman, editor

Published

2024