Your search keyword '"Strength parameters"' showing total 228 results

1. Determination of dam concrete strength parameters considering the effects of ambient environment, member size and aggregate size: A case study of Baihetan Dam

Author

Gao, Xiaofeng, Ji, Mingli, Hu, Yu, Wu, Caichao, Ruan, Weidong, Tan, Yaosheng, and Zheng, Jiangnan

Published

2024

2. Strain Rate Sensitivity of Low Carbon Threaded Steel Rods of Grade 4.6.

Author

Trajkovski, Jovan and Kunc, Robert

Subjects

*MILD steel, *STRAIN rate, *GUARDRAILS on roads, *TENSILE tests, *IMAGE processing

Abstract

Bolt connections are widely used in construction and engineering to securely join structural elements. These connections are essential for distributing loads across components and ensuring that structures can withstand external forces. The planned failure of these bolts is of great importance in steel safety barriers (SSBs), as it can directly influence the height of the guardrail and the working width of the SSB during the vehicle impact, which consequently affects the crash consequences. Therefore, it is of great importance to determine the bolt response until fractures under different strain rates. For that purpose, experimental tensile tests of low-strength steel rods of grade 4.6 were conducted at various strain rates (0.0025–25 s−1) until fracture. Test specimens were photographed during the testing, and by means of image processing, input data for calculation of true stresses and strains up to the point of fracture were extracted. Based on the experimental data, material parameters were determined for the Cowper–Symonds model, enabling precise numerical simulations of these connections at various strain rates. A validation study was also performed successfully. [ABSTRACT FROM AUTHOR]

Published

2024

3. Correlational Research of Strength Parameters of Waste Soils Determined in the Laboratory and In Situ in Cracow.

Author

Zięba, Jakub and Pilecka, Elżbieta

Subjects

ANTHROPOGENIC soils, PORE water pressure, CONE penetration tests, SODIC soils, STATISTICAL correlation

Abstract

This work presents an analysis of the relationship between strength parameters determined in the laboratory and the results of a cone penetration test with pore water pressure measurement (CPTU) of waste soils in the "White Seas" area in Cracow. Anthropogenic soil is an alkaline waste formed during the production of soda ash and deposited in the area of the former Solvay Sodium Plant factory in Cracow, Poland. Due to the large area of the land and numerous investment plans and completed buildings, there was a need to identify reliable functional relationships enabling the determination of the strength parameters of these soils based on the results of the CPTU. Statistical analysis showed that the best correlation with the test results was provided by two logarithmic functions in which the dependent variables were the effective friction angle and effective cohesion. The dependent variable for both cases was the corrected cone resistance qt. The functional relationship combined data from labour-intensive, long-lasting and costly laboratory measurements with quick and less expensive measurements, i.e., in situ CPTUs. The obtained relationships enable the determination of the strength properties of the subsoil of these anthropogenic soils. [ABSTRACT FROM AUTHOR]

Published

2024

4. Evaluating the impact of nanomaterials on soil strength parameters.

Author

Moazzami, Alireza

Subjects

NANOSTRUCTURED materials, SOILS, SCANNING electron microscopes, ATOMIC force microscopes, SOIL particles

Abstract

This study investigates the impact of nanomaterials on soil strength parameters. This project is carried out according to laboratory tests to determine the impact of nano-silica on the compressive strength and plasticity properties of soil. This project covers the operation of injecting nano-silica into the remoulded soil of Yazd University region, and performing the CPT test as the executive studies in addition to the analysis of nanoparticles by SEM (scanning electron microscope) and AFM (atomic force microscope) images of soil samples. These tests are done for two methods with and without nanomaterials, and then the results are compared. According to the results, nano-silica increases the Plastic Limit (PL) slightly and Liquid Limit (LL) considerably; hence, the addition of nano-silica will increase the Plasticity Index (PI) of soil. Following the increase in nano-silica, the soil compressive strength is also increased; the more the curing time increases, the more the compressive strength will be enhanced. The average rate of increase in compressive strength with time will be increased by increasing the percentage of nano-silica. Based on the results of field and laboratory tests for the injection of nanomaterials and according to silica cementation between soil particles, the nano-silica injection has resulted in the increased CPT strength of soil; hence it is offered as a suitable solution. [ABSTRACT FROM AUTHOR]

Published

2025

5. Effect of Phase Composition Variation of Oxy–Nitride Composite Ceramics on Heat Resistance and Preservation of Strength Parameters.

Author

Borgekov, Daryn B., Azambayev, Serik B., Kozlovskiy, Artem L., and Shlimas, Dmitriy I.

Subjects

CERAMIC materials, CONSTRUCTION materials, THERMAL conductivity, PHASE transitions, CERAMICS

Abstract

The aim of this study is to determine the effect of changes in the phase composition of Al2O3–Si3N4 ceramics that were obtained using the method of mechanochemical solid-phase grinding on their resistance to the process of long-term thermal exposure, accompanied by the processes of oxidation and softening. The relevance of this research consists of determining the influence of the phase composition of ceramics on the change in their strength and thermophysical parameters, on the basis of which, we can draw a conclusion about the optimal composition of composite ceramics that have great prospects in the field of fire-resistant, heat-resistant, or radiation-resistant structural materials. During this study, the dynamics of the changes in the phase transformations of the xAl2O3–(1−x)Si3N4 ceramics, with variations in the ratio of the components, initiated by the thermal annealing of the samples, was established. According to the assessment of the phase transformations with variations in the ratio of the components, it was found that thermal annealing in an air environment at an Al2O3 concentration in the order of 0.3–0.5 M leads to the formation of an orthorhombic Al2(SiO4)O phase and an elevation in its contribution at concentrations above 0.5 M, which causes a rise in the thermophysical parameters and resistance to high-temperature degradation. During the heat resistance tests, it was found that the formation of the composite ceramics with the Si3N4(SiO2)/Al2(SiO4)O/Al2O3 phase composition results in an increase in the stability of their strength properties when exposed to thermally induced oxidation, which has a negative impact on their resistance to softening and a decrease in hardness. Moreover, the presence of the Al2(SiO4)O phase in the composition of the ceramics causes a slowdown in the processes of thermal oxidation of the Si3N4 phase under prolonged temperature exposure, alongside an increase in the degradation resistance of strength properties by more than 4–7 times, in comparison with the softening data established for single-component ceramics. [ABSTRACT FROM AUTHOR]

Published

2024

6. Experimental Investigation on Performance of Hollow Brick with Fly Ash, Cement and Sand

Author

Reddy Maddikera Lokanath and Lingeshwaran N

Subjects

compressive strength, modulus of rupture, water absorption, mix design ratio: cement clay interlocking, strength parameters, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Cement clay interlocking (CCI) hollow bricks have been used as a construction material in many developed and developing countries. Many emerging and underdeveloped nations have utilised cement clay interlocking (CCI) hollow bricks as building materials. In India, Andhra Pradesh local makers prepare these cement clay interlocking (CCI) hollow bricks by simply mixing clay, cement, and sand in a traditional method, without following strict design criteria or rules. Previous research has demonstrated that the mechanical characteristics of CCI hollow bricks gathered from various locations in detailed manner respect to hand books on Civil Engineering as per Indian Standards. Bricks from one region had compressive strengths that were significantly lower than the other region Indian Community Standards. Various methods were employed in this investigation to enhance the mechanical characteristics of CCI bricks. New mix patterns were created with the use of sand, cement, and fly ash in this research paper.

Published

2024

7. Effects of the Ketogenic Diet on Strength Performance in Trained Men and Women: A Systematic Review and Meta-Analysis.

Author

Vargas-Molina, Salvador, Murri, Mora, Gonzalez-Jimenez, Andrés, Gómez-Urquiza, José Luis, and Benítez-Porres, Javier

Abstract

Ketogenic diets (KDs) are an alternative to improve strength performance and body composition in resistance training participants. The objective of this review and meta-analysis is to verify whether a ketogenic diet produces an increase in the strength of resistance-trained participants. We have evaluated the effect of the ketogenic diet in conjunction with resistance training on the strength levels in trained participants. Boolean algorithms from various databases (PubMed, Scopus, and Web of Science) were used. Meta-analyses were carried out, one on the 1-RM squat (SQ), with 106 trained participants or athletes, and another on the 1-RM on the bench press (BP), evaluating 119 participants. We did not find significant differences between the groups in the variables of SQ or BP, although the size of the effect was slightly higher in the ketogenic group. Conclusions: KDs do not appear to impair 1-RM performance; however, this test does not appear to be the most optimal tool for assessing hypertrophy-based strength session performance in resistance-trained participants. [ABSTRACT FROM AUTHOR]

Published

2024

8. A review on the performance of concrete filled tubular columns under axial compression: Emphasis on geometrical parameters and various concrete infills and encasings.

Author

Rohilla, Isha and Gupta, Surinder

Subjects

COMPOSITE columns, HIGH strength concrete, CONCRETE, COMPOSITE structures, CRUMB rubber, CARBON steel

Abstract

Summary: This paper summarizes the literature available on the behavior of concrete‐filled steel tubular (CFST) columns to evaluate the effect of geometrical properties such as shape of cross‐section, diameter‐to‐thickness ratio, and length‐to‐diameter ratio of CFST columns under axial loading. Then, the impact of different material composition for core concrete and encasing material is concluded for columns under axial loading. The performance of CFST is evaluated in terms of failure modes, ductility, stiffness, and axial compressive strength. For encasing tube, carbon steel, stainless steel, and aluminum are studied while for core, various concretes such as Normal (NSC) and high strength concrete (HSC), light weight concrete (LWC), recycled aggregate concrete (RAC), expansive concrete (EC), rubber crumb concrete(RuCC), and steel slag concrete (SSC) are covered for review in this paper. Material limitations as provided by various codes for design of composite structures is also mentioned for both tube and core concrete. Failure modes of concrete‐filled tubular(CFT) columns are most affected by geometric properties columns while materials used for concrete and encasing tube do not cause much difference. Though, ductility, axial compressive strength, and stiffness are affected by both geometric and material properties. [ABSTRACT FROM AUTHOR]

Published

2024

9. Predicting the Strength Properties of LWC Using Response Surface

Author

Reddy, Panga Narasimha, Kavyatheja, Bode Venkata, Hussain Vali, R., Madhu Mohan, G., Damodhara Reddy, B., Aruna Jyothy, S., Mohan Babu, M., Howlett, Robert J., Series Editor, Jain, Lakhmi C., Series Editor, Talpa Sai, P. H. V. Sesha, editor, Potnuru, Srikar, editor, Avcar, Mehmet, editor, and Ranjan Kar, Vishesh, editor

Published

2024

10. Correlational Research of Strength Parameters of Waste Soils Determined in the Laboratory and In Situ in Cracow

Author

Jakub Zięba and Elżbieta Pilecka

Subjects

waste soil, strength parameters, correlation function, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

This work presents an analysis of the relationship between strength parameters determined in the laboratory and the results of a cone penetration test with pore water pressure measurement (CPTU) of waste soils in the “White Seas” area in Cracow. Anthropogenic soil is an alkaline waste formed during the production of soda ash and deposited in the area of the former Solvay Sodium Plant factory in Cracow, Poland. Due to the large area of the land and numerous investment plans and completed buildings, there was a need to identify reliable functional relationships enabling the determination of the strength parameters of these soils based on the results of the CPTU. Statistical analysis showed that the best correlation with the test results was provided by two logarithmic functions in which the dependent variables were the effective friction angle and effective cohesion. The dependent variable for both cases was the corrected cone resistance qt. The functional relationship combined data from labour-intensive, long-lasting and costly laboratory measurements with quick and less expensive measurements, i.e., in situ CPTUs. The obtained relationships enable the determination of the strength properties of the subsoil of these anthropogenic soils.

Published

2024

11. Evaluation of Xanthan and Guar Gum for Stabilising Soil in Terms of Strength Parameters - A Review

Author

Pydi, Rakesh, Yadu, Laxmikant, and Chouksey, Sandeep Kumar

Published

2024

12. Artificial Neural Network Approach to Evaluate Geotechnical Properties of Lime-Treated Mountain Soil: A Slope Stabilization Perspective

Author

Sharma, L. K., Umrao, R. K., Singh, Rajesh, and Singh, T. N.

Published

2025

13. Correlation of Geotechnical and Mineralogical Properties of Lithomargic Clays in Uttara Kannada Region of South India.

Author

Nayak, Deepak, Sarvade, Purushotham G., Udayashankar, H. N., Maddodi, Balakrishna S., and Kumar, M. Prasanna

Subjects

CLAY, PARTICLE size distribution, SUSTAINABLE engineering, SLOPE stability, CLAY minerals

Abstract

The present study explores the intricate relationship between the geotechnical and mineralogical properties of lithomargic clays in the Uttara Kannada region of south India. Lithomargic clays, characterized by their unique composition of clay minerals and calcareous content, play a crucial role in the geotechnical behavior of soils. The study aims to provide a comprehensive understanding of the interplay between the mineralogical composition and engineering characteristics of lithomargic clays, shedding light on their suitability for various construction and infrastructure projects. The research methodology involves a systematic analysis of lithomargic clay samples collected from different locations in the Uttara Kannada region. Geotechnical investigations, including particle size distribution, Atterberg limits, unconfined compressive strength (UCS), California bearing ratio (CBR) and triaxial tests, are conducted to assess the engineering properties of the clays. Concurrently, mineralogical analyses, such as X-ray diffraction (XRD) and scanning electron microscopy (SEM), are employed to identify and quantify the clay mineral constituents within the samples. The findings of this study reveal correlations between specific mineralogical features and geotechnical behaviors of lithomargic clays. Understanding these relationships is crucial for predicting the response of these clays to different engineering applications, including slope stability, foundation design and embankment construction. The research contributes valuable insights to the scientific and engineering communities, aiding in the informed utilization of lithomargic clays in geotechnical projects in the Uttara Kannada region and beyond. The outcomes of this investigation, such as the correlation of geotechnical properties with the variation in minerals in various sample locations, enhance our understanding of the complex nature of lithomargic clays, providing a foundation for more sustainable and effective engineering practices in the geologically diverse landscapes of south India. [ABSTRACT FROM AUTHOR]

Published

2024

14. Effect of Phase Composition Variation of Oxy–Nitride Composite Ceramics on Heat Resistance and Preservation of Strength Parameters

Author

Daryn B. Borgekov, Serik B. Azambayev, Artem L. Kozlovskiy, and Dmitriy I. Shlimas

Subjects

oxy–nitride ceramics, thermal tests, phase transformations, strength parameters, thermal conductivity, high-strength ceramic materials, Crystallography, QD901-999

Abstract

The aim of this study is to determine the effect of changes in the phase composition of Al2O3–Si3N4 ceramics that were obtained using the method of mechanochemical solid-phase grinding on their resistance to the process of long-term thermal exposure, accompanied by the processes of oxidation and softening. The relevance of this research consists of determining the influence of the phase composition of ceramics on the change in their strength and thermophysical parameters, on the basis of which, we can draw a conclusion about the optimal composition of composite ceramics that have great prospects in the field of fire-resistant, heat-resistant, or radiation-resistant structural materials. During this study, the dynamics of the changes in the phase transformations of the xAl2O3–(1−x)Si3N4 ceramics, with variations in the ratio of the components, initiated by the thermal annealing of the samples, was established. According to the assessment of the phase transformations with variations in the ratio of the components, it was found that thermal annealing in an air environment at an Al2O3 concentration in the order of 0.3–0.5 M leads to the formation of an orthorhombic Al2(SiO4)O phase and an elevation in its contribution at concentrations above 0.5 M, which causes a rise in the thermophysical parameters and resistance to high-temperature degradation. During the heat resistance tests, it was found that the formation of the composite ceramics with the Si3N4(SiO2)/Al2(SiO4)O/Al2O3 phase composition results in an increase in the stability of their strength properties when exposed to thermally induced oxidation, which has a negative impact on their resistance to softening and a decrease in hardness. Moreover, the presence of the Al2(SiO4)O phase in the composition of the ceramics causes a slowdown in the processes of thermal oxidation of the Si3N4 phase under prolonged temperature exposure, alongside an increase in the degradation resistance of strength properties by more than 4–7 times, in comparison with the softening data established for single-component ceramics.

Published

2024

15. Lignocellulosic materials from the stems of annual plants.

Author

ANDRUSIAK, ADRIAN and BORYSIUK, PIOTR

Subjects

LIGNOCELLULOSE, PLANT stems, ELASTIC modulus, FLEXURAL strength, MISCANTHUS

Abstract

Copyright of Annals of Warsaw University of Life Sciences - SGGW, Forestry & Wood Technology is the property of Wydawnictwo SGGW 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 Fly Ash on Geotechnical Properties of Soft Soil: A Critical Review †.

Author

Srijan, Narula, Gautam, Sharma, Aditi, and Dogra, Vijayinder Kumar

Subjects

FLY ash, GEOTECHNICAL engineering, ELECTRIC power production, CLAY soils, POLLUTANTS

Abstract

An industrial by-product known as fly ash is produced when coal is burned for electricity production and is considered an environmental pollutant. A comprehensive fly ash utilisation programme must be implemented to reduce environmental pollution, including numerous factors at different levels. Fly ash's geotechnical qualities, including its specific gravity, permeability, internal angular friction, and consolidation characteristics, make it ideal for structural fill, particularly on clay soils, when building highways and embankments. Much research has been conducted on how fly ash affects soil stability. In order to determine the impact of fly ash addition on soil properties, this inquiry reviewed a few of these papers and conducted a critical assessment. This study also looked at combining fly ash and clay soil. Numerous investigations indicate that fly ash generally improves soil stability, notably when analysing CBR values and soil permeability, and reduces volumetric changes in the soil. The ground becomes compact due to particle size and form and a decrease in volumetric dilatation. Because the additives to the hardened soil do not dissolve, the soil's behaviour continues to be modified. [ABSTRACT FROM AUTHOR]

Published

2023

17. Effect of Coir Fiber Reinforcement on Flexural and Compressive Strengths of Masonry Mortar.

Author

Madhu Syamala, Lekshmi, Vishnudas, Subha, and Anil, K. R.

Subjects

*MORTAR, *COIR, *FLEXURAL strength, *GREENHOUSE gases, *MASONRY, *COMPRESSIVE strength

Abstract

An appreciable quantity of cement is consumed as binder for masonry mortar, which has resulted in cost escalation and high energy consumption in building construction, in addition to contributing to greenhouse gas emissions. On the other hand, disposal of waste lignocellulosic materials as agricultural residues persists as an unsolved technical problem creating environmental pollution. This paper proposes an effective solution for these two critical issues. Coir fiber, when used as a reinforcement material in cement, was found to be effective in enhancing the mechanical properties of the binder. The application of coir fiber reinforcement on strong, moderate, and weak masonry mortars with respect to strength criteria is examined in this study. ANOVA analysis was carried out to examine the level of significance of coir fiber reinforcement on the flexural and compressive strengths of masonry mortar. The findings from the study revealed that 0.5% coir fiber reinforcement enhanced flexural strength of strong mortar by 18%–22%, moderate mortar by 21%, weak mortar by 10%, and compressive strength of strong mortars by 16%–19% by contributing strength in the early curing period. Moreover, coir fiber–reinforced mortars satisfied the compressive strength criteria required of strong mortar (7.5 to 10 N/mm2), moderate mortar (5 N/mm2), and weak (3 N/mm2) mortar for its application as mortar on masonry walls in accordance with Indian standards. The strength of masonry in compression, flexure, and shear determines how well masonry operates structurally. Cement-based structures are strong in compression but are prone to shrinkage cracks over a span of 30 years due to its weakness in tension. Flexural strength is an indirect indicator for measuring tension. Coir fiber imparts tensile strength to the matrix when used as reinforcement in cement mortar. Fiber networking dissipates the tensile stresses that develop in mortar during flexure and would bridge the gap in a better way. This prolongs the life of buildings and maintains ecological equilibrium by preventing the need for periodic repair and maintenance, which reduces cost, time, and labor. The use of fibers in mortar for plastering is found to be more beneficial in enhancing the strength of a masonry structure than adding fibers to blocks. Coir fiber content of 0.25% and 0.5% (10 mm length) by weight of cement was found to be effective at enhancing the early flexural strength of cement mortar. Coir fiber–reinforced plaster cement can be made available ready to use in bags of 25 or 50 kg for a crack-free plastered surface on ceilings and internal and external walls. [ABSTRACT FROM AUTHOR]

Published

2023

18. Geotechnical Characterization of Natural Sub-Base and Subgrade Material for Pavements

Author

Kumar, A., Kumawat, S. K., Jain, M., Dangayach, S., Raj, D., Sharma, H. K., 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, Shrikhande, Manish, editor, Agarwal, Pankaj, editor, and Kumar, P. C. Ashwin, editor

Published

2023

19. A Rational Interpretation of Laboratory Direct Shear Test Results for Soils

Author

Huanca, Samuel Laura, Huanca, Julio Cesar Laura, Vilca, Russel Allidren Lozada, Howlett, Robert J., Series Editor, Jain, Lakhmi C., Series Editor, Iano, Yuzo, editor, Saotome, Osamu, editor, Kemper Vásquez, Guillermo Leopoldo, editor, de Moraes Gomes Rosa, Maria Thereza, editor, Arthur, Rangel, editor, and Gomes de Oliveira, Gabriel, editor

Published

2023

20. Pico Volcano Flank Landslides and Hazard Implications: Preliminary Results

Author

Marques, Fernando, Pisello, Anna Laura, Editorial Board Member, Hawkes, Dean, Editorial Board Member, Bougdah, Hocine, Editorial Board Member, Rosso, Federica, Editorial Board Member, Abdalla, Hassan, Editorial Board Member, Boemi, Sofia-Natalia, Editorial Board Member, Mohareb, Nabil, Editorial Board Member, Mesbah Elkaffas, Saleh, Editorial Board Member, Bozonnet, Emmanuel, Editorial Board Member, Pignatta, Gloria, Editorial Board Member, Mahgoub, Yasser, Editorial Board Member, De Bonis, Luciano, Editorial Board Member, Kostopoulou, Stella, Editorial Board Member, Pradhan, Biswajeet, Editorial Board Member, Abdul Mannan, Md., Editorial Board Member, Alalouch, Chaham, Editorial Board Member, O. Gawad, Iman, Editorial Board Member, Nayyar, Anand, Editorial Board Member, Amer, Mourad, Series Editor, Malheiro, Ana, editor, Fernandes, Francisco, editor, and Chaminé, Helder I., editor

Published

2023

21. An Experimental Study on Self-Compacting Concrete by Using Silica Fume and Fly Ash

Author

Shruthi, B. S., Anilkumar, 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, Nandagiri, Lakshman, editor, Narasimhan, M. C., editor, and Marathe, Shriram, editor

Published

2023

22. Optimization of the Combined Effect of Lime and Ground Granulated Blast-furnace Slag on Clayey Soil

Author

Nasreddine Diaf, Mustapha Hidjeb, Khaled Boudjellal, Mohamed Boudiaf, and Ihcene Lamri

Subjects

optimization, silty clay, ggbs, quicklime, strength parameters, Engineering (General). Civil engineering (General), TA1-2040

Abstract

This work investigates the behavior of a silty clay stabilized with 3, 6, 9, and 12 % of ground granulated blast-furnace slag (GGBS), respectively, and 1 % of quicklime used as an activator. The influence of the composite (Quicklime - GGBS) on the immediate behavior of the silty clay is studied by examining the Atterberg limits, the maximum dry density, the optimum moisture content, and the immediate bearing index. The evolution, at different curing periods (1, 7, and 28 days), of the mechanical characteristics of the treated soil, namely unconfined compressive strength, cohesion, and internal angle of friction is also studied. The increase, up to a dosage of 9%, of the GGBS content, leads to an increase in the optimum moisture content, the immediate bearing index, the unconfined compressive strength, and shear strength parameters. Paradoxically, a decrease in the plasticity index and the maximum dry density was observed.

Published

2022

23. Improved Duncan-Chang model for reconstituted hydrate-bearing clayey silt from the South China Sea.

Author

Lin Dong, Nengyou Wu, Yajuan Zhang, Hualin Liao, Gaowei Hu, and Yanlong Li

Subjects

*HYDRATES, *NATURAL gas, *GEOLOGY, *ELASTIC modulus

Abstract

The experimental testing and analysis of strength and deformation characteristics of hydrate reservoirs is an integral part of natural gas hydrate exploitation. However, studies so far have failed to deeply explore samples from the South China Sea. Especially, there is a lack of a simple and applicable method to estimate their mechanical behaviors. Thus, based on test data, an improved Duncan-Chang model is established in this paper to characterize the strength and deformation of reconstituted samples with various hydrate saturation and stress states from this area. This model can accurately describe the strainhardening characteristics, and failure strength is estimated by the improved Drucker-Prager criterion with high fitting accuracy. The initial elastic modulus and failure ratio are given by the proposed empirical models, which are obtained from experimental data and fitting methods. Generally, this model has several advantages including simple structure, favorable performances, and a limited number of model parameters. Therefore, it could be widely used in strength and deformation analysis. This study can support the prevention and control of geological risks during natural gas hydrate exploitation in the South China Sea. [ABSTRACT FROM AUTHOR]

Published

2023

24. Correlation of Geotechnical and Mineralogical Properties of Lithomargic Clays in Uttara Kannada Region of South India

Author

Deepak Nayak, Purushotham G. Sarvade, H. N. Udayashankar, Balakrishna S. Maddodi, and M. Prasanna Kumar

Subjects

correlation, mineralogical properties, geotechnical properties, strength parameters, XRD analysis, Geology, QE1-996.5

Abstract

The present study explores the intricate relationship between the geotechnical and mineralogical properties of lithomargic clays in the Uttara Kannada region of south India. Lithomargic clays, characterized by their unique composition of clay minerals and calcareous content, play a crucial role in the geotechnical behavior of soils. The study aims to provide a comprehensive understanding of the interplay between the mineralogical composition and engineering characteristics of lithomargic clays, shedding light on their suitability for various construction and infrastructure projects. The research methodology involves a systematic analysis of lithomargic clay samples collected from different locations in the Uttara Kannada region. Geotechnical investigations, including particle size distribution, Atterberg limits, unconfined compressive strength (UCS), California bearing ratio (CBR) and triaxial tests, are conducted to assess the engineering properties of the clays. Concurrently, mineralogical analyses, such as X-ray diffraction (XRD) and scanning electron microscopy (SEM), are employed to identify and quantify the clay mineral constituents within the samples. The findings of this study reveal correlations between specific mineralogical features and geotechnical behaviors of lithomargic clays. Understanding these relationships is crucial for predicting the response of these clays to different engineering applications, including slope stability, foundation design and embankment construction. The research contributes valuable insights to the scientific and engineering communities, aiding in the informed utilization of lithomargic clays in geotechnical projects in the Uttara Kannada region and beyond. The outcomes of this investigation, such as the correlation of geotechnical properties with the variation in minerals in various sample locations, enhance our understanding of the complex nature of lithomargic clays, providing a foundation for more sustainable and effective engineering practices in the geologically diverse landscapes of south India.

Published

2024

25. Development and standardization of sustainable dry mix mortars with supplementary cementitious materials

Author

Bansal, Sunita, Bansal, Prince, Gautam, Lilesh, and Sharma, Kul Vaibhav

Published

2024

26. Different Effects of Cyclical Ketogenic vs. Nutritionally Balanced Reduction Diet on Serum Concentrations of Myokines in Healthy Young Males Undergoing Combined Resistance/Aerobic Training.

Author

Kysel, Pavel, Haluzíková, Denisa, Pleyerová, Iveta, Řezníčková, Kateřina, Laňková, Ivana, Lacinová, Zdeňka, Havrlantová, Tereza, Mráz, Miloš, Kasperová, Barbora Judita, Kovářová, Viktorie, Thieme, Lenka, Trnovská, Jaroslava, Svoboda, Petr, Hubáčková, Soňa Štemberková, Vilikus, Zdeněk, and Haluzík, Martin

Abstract

Myokines represent important regulators of muscle metabolism. Our study aimed to explore the effects of a cyclical ketogenic reduction diet (CKD) vs. a nutritionally balanced reduction diet (RD) combined with regular resistance/aerobic training in healthy young males on serum concentrations of myokines and their potential role in changes in physical fitness. Twenty-five subjects undergoing regular resistance/aerobic training were randomized to the CKD (n = 13) or RD (n = 12) groups. Anthropometric and spiroergometric parameters, muscle strength, biochemical parameters, and serum concentrations of myokines and cytokines were assessed at baseline and after 8 weeks of intervention. Both diets reduced body weight, body fat, and BMI. Muscle strength and endurance performance were improved only by RD. Increased musclin (32.9 pg/mL vs. 74.5 pg/mL, p = 0.028) and decreased osteonectin levels (562 pg/mL vs. 511 pg/mL, p = 0.023) were observed in RD but not in the CKD group. In contrast, decreased levels of FGF21 (181 pg/mL vs. 86.4 pg/mL, p = 0.003) were found in the CKD group only. Other tested myokines and cytokines were not significantly affected by the intervention. Our data suggest that changes in systemic osteonectin and musclin levels could contribute to improved muscle strength and endurance performance and partially explain the differential effects of CKD and RD on physical fitness. [ABSTRACT FROM AUTHOR]

Published

2023

27. Strength estimation and stress–dilatancy characteristics of natural gas hydrate-bearing sediments under high effective confining pressure.

Author

Xu, Jialin, Xu, Chengshun, Huang, Linghui, and Hyodo, Masayuki

Subjects

*NATURAL gas, *SEDIMENTS, *INTERNAL friction, *GOLD ores

Abstract

Gas production by depressurization can significantly increase the effective stress in hydrate-bearing sediments. Therefore, strength and deformation characteristics of sediments under high effective confining pressure should be fully understood before large-scale extraction. In this study, a series of triaxial tests on artificial methane hydrate-bearing specimens were conducted under effective confining pressures of 0.2–20 MPa, and the effects of effective confining pressure and hydrate saturation on the strength parameters and the stress–dilatancy characteristics were discussed. The results demonstrate that the strength and stiffness of hydrate-bearing sediments increase with increasing effective confining pressure. Shearing under high effective confining pressure leads to significant breakage of host particles, which is independent of the hydrate saturation. The increase in the effective confining pressure decreases the internal friction angle while increasing the cohesion of hydrate-bearing sediments. By linking the effective confining pressure and hydrate saturation with strength parameters of Mohr–Coulomb criterion and Drucker–Prager criterion, the strength of sediments in a high range of effective stress can be accurately predicted. With increasing effective confining pressure, the shear–dilation transfers to shear–contraction, the critical stress ratio gradually decreases to attain a constant value, and the effects of hydrate saturation and effective stress on the dilatancy characteristics gradually become less notable. [ABSTRACT FROM AUTHOR]

Published

2023

28. The Tailings Storage Facility (TSF) stability monitoring system using advanced big data analytics on the example of the Zelazny Most Facility

Author

Wioletta Koperska, Maria Stachowiak, Natalia Duda-Mróz, Paweł Stefaniak, Bartosz Jachnik, Bartłomiej Bursa, and Paweł Stefanek

Subjects

hydrotechnics, tailing dam, data mining, risk analysis, strength parameters, Engineering (General). Civil engineering (General), TA1-2040

Abstract

Approximately 30 million tons of tailings are being stored each year at the KGHMs Zelazny Most Tailings Storage Facility (TSF). Covering an area of almost 1.6 thousand hectares, and being surrounded by dams of a total length of 14 km and height of over 70 m in some areas, makes it the largest reservoir of post-flotation tailings in Europe and the second-largest in the world. With approximately 2900 monitoring instruments and measuring points surrounding the facility, Zelazny Most is a subject of round-the-clock monitoring, which for safety and economic reasons is crucial not only for the immediate surroundings of the facility but for the entire region. The monitoring network can be divided into four main groups: (a) geotechnical, consisting mostly of inclinometers and VW pore pressure transducers, (b) hydrological with piezometers and water level gauges, (c) geodetic survey with laser and GPS measurements, as well as surface and in-depth benchmarks, (d) seismic network, consisting primarily of accelerometer stations. Separately a variety of different chemical analyses are conducted, in parallel with spigotting processes and relief wells monitorin. This leads to a large amount of data that is difficult to analyze with conventional methods. In this article, we discuss a machine learning-driven approach which should improve the quality of the monitoring and maintenance of such facilities. Overview of the main algorithms developed to determine the stability parameters or classification of tailings are presented. The concepts described in this article will be further developed in the IlluMINEation project (H2020).

Published

2022

29. Application and comparison of multistage triaxial compression test procedures on reconstituted Ankara clay

Author

Vakilinezhad Amirahmad and Toker Nabi Kartal

Subjects

multistage triaxial test, high plasticity clays, ankara clay, strength parameters, Environmental sciences, GE1-350

Abstract

The ability to conduct conventional triaxial compression tests on multiple identical specimens is restricted by available sample quantity, sample homogeneity, as well as testing duration. Multistage triaxial testing is an alternative method to tackle these issues by using a single specimen sheared under different confining stresses to attain the strength parameters. Although there are widely accepted procedures to decide when to stop each shearing stage and proceed to the next stress level, the applicability of these procedures on different soil types is still a question. This study examines the applicability of combinations of two multistage triaxial testing procedures (Rational Procedure and Minimum Slope) under two different deviator stress conditions (Sustained or Cyclic) during confining stress increase. The outcome is compared to conventional triaxial test results for undrained and drained shearing of reconstituted specimens of high-plasticity Ankara Clay. Out of the four options, the rational procedure with cyclic deviator loading and minimum slope with cyclic deviatoric loading conditions, are found to give the most accurate strength parameters in reference to single-stage test results. The maximum number of the shearing-reconsolidation sequences applicable before strength loss is also investigated for each multistage triaxial testing procedure.

Published

2024

30. Dataset on physical properties and mechanical parameters of limestone rocks from Central Apennines (Italy) by laboratory test on intact rock specimens

Author

Salvatore Martino, Emiliano Di Luzio, Marco Emanuele Discenza, Carlo Esposito, Jagadish Kundu, and Mariacarmela Minnillo

Subjects

Intact rock, Laboratory tests, Limestone, Physical properties, Strength parameters, Stiffness parameters, Computer applications to medicine. Medical informatics, R858-859.7, Science (General), Q1-390

Abstract

Physical properties and mechanical parameters of intact rocks are essential in defining geomechanical characteristics of rock masses. The latter are fundamental in the geotechnical design and numerical modelling of engineering-geological applications involving slope stability analyses as well as the design of dams, foundations, tunnels, open and underground mines, nuclear storage repository etc. Time and financial constraints of many projects often do not allow to perform all the laboratory tests necessary for physical-mechanical characterization of the rock matrix. In these cases, existing published data are the only tools for appropriate definition of the geomechanical characteristics of the intact rocks and subsequent development of engineering-geological performances.This paper reports the values of major physical properties and mechanical parameters for several intact rock samples of limestone, collected from the Central Apennines region (Italy). The main physical properties measured for the rock samples are unit weight, density, and porosity. The mechanical parameters derived from the laboratory tests on the samples include uniaxial compressive strength, cohesion, friction angle, tensile strength, elastic modulus, and Poisson's ratio. Only for a few of samples, the index parameters (point load index) and the dynamic characteristics (P-wave velocity) were also measured. The laboratory tests for these samples were performed following the standards by the International Society for Rock Mechanics (ISRM).

Published

2023

31. Drained behaviour of artificially cemented dune aeolian sand.

Author

Fontoura, Tahyara Barbalho, dos Santos Junior, Olavo Francisco, Severo, Ricardo Nascimento Flores, and Coutinho, Roberto Quental

Subjects

*SOIL cement, *SAND dunes, *STRAINS & stresses (Mechanics), *SPECIFIC gravity, *CEMENT mixing, *DRUG dosage

Abstract

Mixing cement and soil is a traditional technique used to improve their mechanical properties. Other studies proposed a rational dosage methodology for soil-cement mixtures. This method is based on the void-cement ratio and aimed at obtaining a particular strength level. The present study evaluated the validity of the void-cement ratio (η/Civ) and analysed the stress – strain – strength behaviour of aeolian dune sand from Natal, Brazil, mixed with cement. Isotropically consolidated drained triaxial compression tests (CID-C) were conducted with moulded samples containing 0.0, 2.5, 5.0 and 7.5% cement by weight of dry soil. Void ratios corresponded to three conditions of relative density: loose, medium and dense, with confining stresses of 50, 100, 200 and 300 kPa. The effect of void ratio, cement content and void-cement ratio on the stress-strain-strength behaviour of the mixtures was determined. The results showed that the void-cement ratio is an appropriate parameter to assess the effective strength of the cement-sand mixture studied. [ABSTRACT FROM AUTHOR]

Published

2022

32. REVIEW ON THE MECHANICAL PROPERTIES OF FROZEN ROCKS

Author

Seyed Morteza Davarpanah, Ákos Török, and Balázs Vásárhelyi

Subjects

frozen rock, strength parameters, Young’s modulus, mathematical modelling, Mining engineering. Metallurgy, TN1-997, Geology, QE1-996.5

Abstract

The freezing technique has been employed for a long time to strengthen the mechanical properties of intact rock and rock mass; however, it has not received as much attention as it deserves. This paper thoroughly reviews the effect of freezing on the essential mechanical properties, including uniaxial compressive strength, tensile strength, and Young’s modulus. The laboratory tests include the determination of density, ultrasound speed propagation, and strength parameters such as uniaxial compressive strength, tensile strength, and Young’s modulus. According to previously published results, the strength of different rocks such as marl, limestone, sandstone, tuff, granite, and marble increased significantly due to freezing when the samples were tested in frozen conditions. However, there is variation in strength increase based on rock type. It is outlined here that freezing increases rock strength by a factor of 4 in porous rock and by a factor of 1.8 in crystalline rock. Additionally, Young’s modulus increases with a decrease in temperature; however, a further decrease in temperature from -10 to -20 °C has no effect on Young’s modulus. Moreover, mathematical modelling for frozen rock has been reviewed comprehensively. It was found that porosity, the density of rock grains, density of water, residual unfrozen water content, minimum unfrozen water content at freezing point, material parameters, the initial temperature of rock, crystal size, orientation and alignment of minerals, and the loading rate are the most critical parameters that influence frozen rock strength.

Published

2022

33. Slope stability analysis of deep-seated landslides using limit equilibrium and finite element methods in Debre Sina area, Ethiopia.

Author

Mebrahtu, Tesfay Kiros, Heinze, Thomas, Wohnlich, Stefan, and Alber, Michael

Abstract

Slope failure is a recurring natural hazard in the western margin of the Main Ethiopian Rift and especially around the Debre Sina area. To minimize the damage caused by failure events, a detailed investigation of landslide-prone areas identified using numerical modelling plays a crucial role. The main aim of this study is to assess the stability of slopes and to evaluate and compare safety factors calculated by the different available numerical methods. Stability analyses of slopes prone to different types of failures were performed with different techniques. The stability was assessed for slopes of complex geometry composed of aphanitic basalt, porphyritic basalt, tuff, and colluvium (poorly sorted clayey sand to silty sand) using the limit equilibrium method and the shear strength reduction method based on finite elements. Furthermore, numerical analysis was done under static and pseudo-static loading using the horizontal seismic coefficient to model their stability during a seismic event. Satellite images were used to select failure-prone slopes based on slope properties and identified past landslides, as well as to derive structural and geological information for the numerical models. The slope stability analysis indicates that the studied slopes are unstable, and any small-scale disturbance will further reduce the factor of safety and cause failure. The slope stability of landslide prone hills in the study area strongly depends on the saturation conditions and the seismic load. [ABSTRACT FROM AUTHOR]

Published

2022

34. Real-time prediction of tensile and uniaxial compressive strength from artificial intelligence-based correlations.

Author

Hiba, Moaz, Ibrahim, Ahmed Farid, and Elkatatny, Salaheldin

Abstract

The study of the geomechanical parameters is necessary for field planning and development. Two of the most critical parameters used to describe the rock strength are the tensile (Ts) and the uniaxial compressive strength (UCS). Measuring these two parameters in the lab is time-consuming. Consequently, non-destructive methods have been developed to predict these parameters fast and reliable. Field drilling data can be reliable, continuous, and rapid technology in predicting UCS and Ts. Herein, an artificial neural intelligence network (ANN) predicts Ts and UCS from actual drilling data collected from two fields in the Middle East. The data include rate of penetration (ROP), weight on bit (WOB), torque (T), drilling fluid injection rate (Q), and the standpipe pressure (SPP). Several sensitivity analyses were conducted to optimize the models' parameters and inputs, followed by extracting the weights and biases for developing ANN-based relations for Ts and UCS. The results showed that the ANN was highly accurate during the training phase in predicting UCS with an AAPE of 0.28%, and Ts with an AAPE of 0.28%. The developed correlation effectively predicted Ts and UCS for an average AAPE of 0.59 % during the testing phase and only 0.65 % for the validation data set for both parameters. This method provides a real-time effective tool for predicting the strength parameters in continuous, fast, and reliable measurements from the drilling field data. [ABSTRACT FROM AUTHOR]

Published

2022

35. Investigations of Properties of Soil-Aggregate Mixtures.

Author

Skrzypczak, Izabela

Subjects

WASTE products, SOILS, CONSTRUCTION materials, RESEARCH, CONSTRUCTION

Abstract

The subject of this paper is the evaluation of the use of waste material, which is the native soil. On the example of the base ground taken from the village of Lipie (Podkarpackie voivodeship), soil-aggregate mixtures were prepared with a different degree of addition of natural aggregate. The study analysed the quantitative and qualitative parameters of the prepared mixtures and assessed their physical and mechanical properties to determine their suitability for the construction of nfrastructural facilities. It should be noted that most specifications recommend the use of primarily aggregate mixtures. The paper presents the results of a study analysing the effect of aggregate admixture to the native soil on selected physical and strength properties of the mixtures developed. The obtained results confirmed the validity of research on the use of soil-aggregate mixtures for construction purposes. [ABSTRACT FROM AUTHOR]

Published

2022

36. Utilisation of phosphogypsum along with other additives in geo- engineering- A review

Author

B. Anamika and G. Debabrata

Subjects

Phosphogypsum, Geotechnical applications, By-products, Strength parameters, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Various adverse effects and hydro-mechanical failures of soil are the dominant effects of global warming. At the same time, rapid industrial development has produced several by-products on a large scale. The reuse of industrial residues in different engineering fields without compromising the technical characteristics is propitious from the engineering, environmental, ecological and economic points of view. Phosphogypsum (PG) can be used as an alternative civil engineering material as it is rich in calcium sulphate, although it contains some radioactive molecules. Researchers are continuing to investigate the utilisation of PG by mixing it with other traditional materials to convert into alternative materials when the radioactive minerals are within the permissible limits. However, the contamination effect can be reduced by treating with citric acid. This review paper presents details of the increase in strength parameters and permeability of PG when combined with other wastes materials used in different geotechnical fields.

Published

2022

37. Investigating the impact of nano-colloidal silica on sandy clay strength: Experimental results and stress-strain modeling insights.

Author

Seif, Mohammad Esmaeil, MolaAbasi, Hossein, Saba, Hamidreza, and Mirhosseini, S.Mohammad

Subjects

*CLAY soils, *STRAINS & stresses (Mechanics), *CLAY, *SANDY soils, *SILICA, *FEED additives

Abstract

This study examines the application of nano-colloidal silica (NCS) in enhancing the mechanical properties of sandy clay soils. Consolidated undrained (CU) triaxial tests were performed on specimens containing varying percentages of NCS (0 %, 5 %, 10 %, and 20 %), which were then cured for different curing periods (1, 7, and 28 days) and subjected to three different confining pressures (50, 100, and 200 kPa). The findings revealed that the inclusion of 10 % NCS resulted in a significant 65 % increase in strength after 28 days compared to the untreated sample. However, higher NCS percentages, exceeding 10 %, led to a decline in strength as the excess NCS was not effectively utilized. The inclusion of NCS and increased curing time led to an increase in the brittleness of the soil and the application of confining pressure was able to reduce this brittleness.Furthermore, the use of 10% NCS and a curing period of 28 days significantly increased the stiffness and absorbed energy of the soil. Despite boosting the peak shear strength, NCS reduced the residual strength. Finally, polynomial modeling (Poly4) provided an excellent fit, enabling the characterization of the stress-strain and pore pressure-stain responses from the triaxial test. • A series of CU tests were conducted to investigate the strength behavior of sandy clay soil with NCS additive. • 10 % was the optimal content of NCS to modify sandy clay soil, which can improve strength. • The addition of NCS to the sandy clay soil enhances the strength and reduces the failure strain. • Empirical models were developed to predict and satisfactorily simulate q-ɛ and u- ε curves. [ABSTRACT FROM AUTHOR]

Published

2024

38. Experimental Comparative Study on Strength Parameters of Concrete Assimilating Glass Fibers of Fine Aggregate, Cement with Rubber and GGBS

Author

Sil, Arjun, Vanapalli, Naveen Kumar, Kumari, Anisha, Gogoi, Pratyasha, Mojumder, Debasish, 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, Prashant, Amit, editor, Sachan, Ajanta, editor, and Desai, Chandrakant S., editor

Published

2020

39. Review on the mechanical properties of frozen rocks.

Author

Davarpanah, Seyed Morteza, Török, Ákos, and Vásárhelyi, Balázs

Subjects

YOUNG'S modulus, ROCK properties, CRYSTALLINE rocks, FREEZING points, COMPRESSIVE strength, TENSILE strength, FREEZE-thaw cycles

Abstract

Copyright of Rudarsko-Geolosko-Naftni Zbornik is the property of Faculty of Mining, Geology & Petroleum Engineering 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

2022

40. Strength and Energy Evolution Law of Deep-Buried Granite Under Triaxial Conditions

Author

Guangtao Guo, Dingping Xu, Guangliang Feng, Xiaogang Wu, and Yuxin Zhou

Subjects

deep-buried granite, deformation and failure characteristics, strength parameters, energy evolution, energy consumption ratio, Environmental sciences, GE1-350

Abstract

With the increasing global demand for clean and renewable energy sources, many underground hydropower caverns are built in deep mountain valleys in high-stress regions. The evolution of the mechanical properties of the surrounding rock of underground caverns under high-stress excavation requires urgent investigation. According to the deep-buried granite in the underground caverns of the Shuangjiangkou hydropower station, triaxial tests under confining pressures of 10, 30, 40, and 50 MPa were conducted by the MTS815 rock mechanics test system. Based on the stress–strain curve, the evolution law of the strength parameters of rock samples with the crack volume strain and energy with the energy consumption ratio under different confining pressures was analyzed. Our results showed that the stress–strain curve of the sample is divided into five stages with four characteristic points: the closed point, initiation point, volume expansion point, and peak point. The strength of each stage increases with an increase in the confining pressure. In addition, the failure of this granite is characterized by apparent shear failure. The internal friction angle and the cohesion increase rapidly with the increase in the crack volume strain, and they gradually tend to be constant. Furthermore, the confining pressure profoundly influences energy evolution during the loading in the stable and unstable crack growth stages. In these stages, total energy, dissipated energy, and elastic strain energy increase with an increase in the confining pressure. Finally, the energy consumption ratio can represent the preliminary criterion of rock failure in terms of energy. With the increase in the confining pressure, the energy consumption ratio of rock samples gradually increases to approximately 1.0 at the peak stress point. The research results can provide a reference for the instability prediction of surrounding rock masses of high-stress underground caverns.

Published

2022

41. Studying the Failure Behavior of Cement-fiber-treated Sand under Triaxial Direct Tension Tests.

Author

Isazadeh-Khiav, Behzad, Akhlaghi, Tohid, and Hajialilue-Bonab, Masoud

Subjects

*POLYPROPYLENE fibers, *INTERNAL friction, *RESIDUAL stresses, *SYNTHETIC fibers, *SAND, *STRAINS & stresses (Mechanics), *FIBERS

Abstract

The main goal of this research is to study the failure behavior of cement-fiber-treated sand under triaxial direct tension condition tests. Thus, a new loading system and triaxial cell was designed and built for tensile loading. Samples were prepared with content cement of 3 and 5% (dry wt.) of the sand, while two types of polypropylene fibers 0.024 m in length and 23 μm and 300 μm thick were added at 0.0% and 0.5% (dry wt.) of the sand and cement mixture. After a seven-day curing period, the samples were loaded under triaxial direct tension tests under confining pressures of 100, 200, and 300 kpa in drained conditions. Stress-strain behavior, changes in volume and energy absorbed by cement-fiber reinforced sand were measured and compared with the results of other studies. Adding fibers resulted in reduced peak deviatoric stress and increased residual deviatoric stresses of the cement-fiber reinforced sand, with changes from brittle to ductile behavior. The initial stiffness and stiffness at 50% maximum tensile stress of the samples is decreased with the addition of fibers and with an increase in fiber diameter, the reduction rate of this stiffness is more evident. The absorbed energy for fibers with a thickness of 23 μm is less than fibers with a thickness of 300 μm. The effect of adding fibers to strength parameters showed that the cohesion intercept decreases, while the internal friction angle increases. [ABSTRACT FROM AUTHOR]

Published

2022

42. Experimental Investigation of the Mechanical Properties of Methane Hydrate–Bearing Sediments under High Effective Confining Pressure.

Author

Xu, Jialin, Xu, Chengshun, Yoshimoto, Norimasa, Hyodo, Masayuki, Kajiyama, Shintaro, and Huang, Linghui

Subjects

*STRAINS & stresses (Mechanics), *SEDIMENTS, *STRESS-strain curves, *METHANE, *INTERNAL friction

Abstract

A significant increase in effective stress can be induced in hydrate-bearing reservoirs when the depressurization method is applied. A series of drained triaxial shear tests were performed on hydrate-bearing sediments with various hydrate saturations to investigate their mechanical characteristics under effective confining pressures of up to 20 MPa. The results show that significant particle crushing of the host sand occurs during shearing under high pressures, and there is no remarkable effect of hydrate saturation on the degree of particle breakage. As the effective confining pressure increases, the stress–strain curves of the hydrate-bearing specimen transformed from strain-softening to strain-hardening. The peak stress ratio and internal friction angle of the sediments gradually decrease and tend to be constant with the increased confining stress, whereas the cohesion in hydrate-bearing sediments exhibits an increasing tendency. The critical state line (CSL) of hydrate-bearing sediments in the e-lnp′ space under low-to-high effective confining pressures intersects with the normal consolidation line under the same hydrate saturation. Furthermore, the CSL moves upward and rotates clockwise as the hydrate saturation increases. [ABSTRACT FROM AUTHOR]

Published

2022

43. Changes in the Strength of High-Plasticity Clays After Stabilization: an Experimental Study

Author

Aslan Topcuoglu, Yasemin and Gurocak, Zulfu

Published

2023

44. Improving the Characteristics of a Soft Clay Soil Using Cement Activated Low-Calcium Fly Ash

Author

Qutaiba Majeed, Abdalla M Shihab M Shihab, Jasim M. Abbas, and Saad Sh. Sammen

Subjects

Soft soil, Stabilization, Strength parameters, Unconfined compression, Engineering machinery, tools, and implements, TA213-215, Mechanics of engineering. Applied mechanics, TA349-359, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Chemical engineering, TP155-156, Environmental engineering, TA170-171

Abstract

In this research, the potential improvement of some geotechnical characteristics of soft clay soil using the low Calcium fly ash was evaluated. (These characteristics include unit weight, shear strength, compaction characteristics and soil plasticity characteristics). In addition, the X-ray diffraction test was performed to measure the mineralogical changes in the soft clay soil when the low Calcium fly ash is added. The ordinary Portland cement was used to activate the fly ash. The total percent of flash and cement was10% to investigate the variation in the effectiveness of activation. The optimum moisture content that which computed by the compaction test was adopted in the rest of the experimental program. The test results revealed that the cement could be used to improve the activating of the fly ash efficiently. The maximum value of dry density was marginally affected due to activation from 1.747 to 1.738 g/cm3 along with a corresponding change in optimum water content from 17.45 to 15.5 %. The soil cohesion parameter increased from 188 to 206 kN/m2 whereas the angle of internal friction rose from about 56.7o to 59.1o. Finally, the results of the unconfined compression test reveal that the cement-activated fly ash could present better results than those obtained from a 28-days curing cement.

Published

2021

45. 考虑间接加筋作用的加筋黏土强度分析.

Author

雷胜友

Subjects

REINFORCED soils, SOIL cohesion, INTERFACIAL friction, FAILURE mode & effects analysis, SOILS

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

2021

46. Selected components of geological structures and numerical modelling of slope stability

Author

Kaczmarek Łukasz D. and Popielski Paweł

Subjects

slope equilibrium state, strength parameters, geological structure, heavy rains, finite element method, Geology, QE1-996.5

Abstract

This paper presents the impact of selected essential aspects of geological structure on the state of slope stability as assessed by changes in the safety factor (SF). The engineering geological slope features that were analysed include: (i) changes in soil cohesion and internal friction angle, (ii) presence of a weak soil layer and its span, (iii) structural discontinuity (i.e. fault), (iv) soil permeability properties and water conditions (i.e. groundwater level, long and heavy rainfall). A certain scheme of slope stability calculations has been proposed for a case involving complex geological conditions. The numerical modelling of a hypothetic slope was performed using the shear strength reduction method based on the finite element method.

Published

2019

47. INVESTIGATING THE STRENGTH PARAMETERS OF UNSATURATED SOIL IN SEASONAL FROZEN AREAS UNDER LOW MATRIC SUCTION AND THEIR EFFECT ON OVERWINTERING DEEP FOUNDATION PITS.

Author

Haotian Guo, Chao Sun, and Xilei Shan

Abstract

In the current paper, we explore the effect of temperature changes in seasonal frozen areas on the strength parameters of unsaturated soil under low matric suction, as well as the impact of the parameters under different temperatures on an overwintering deep foundation pit in unsaturated soil under low matric suction. In particular, we take unsaturated silty clay in its original state as the research object and Global Digital Systems Ltd. (GDS) unsaturated silty soil as the triaxial tester to perform triaxial shear tests on unsaturated silty clay under several temperatures. The strength parameters obtained from the laboratory tests are then combined with Abaqus numerical simulations to analyze the stress and deformation of the overwintering deep foundation pit supporting structure in unsaturated soil within seasonal frozen areas. Experimental results under low matric suction demonstrate that temperature variations have a greater effect on the total cohesive force of unsaturated silty clay, yet their impact on the effective internal friction angle is relatively small. The influence of the frost heaving force produced by the freezing of the unsaturated soil on supporting structures is observed to be greater than the earth pressure during the freeze-thaw process. When the unsaturated soil is frozen, the horizontal frost heaving force of the retaining structure at the top and bottom of the foundation pit is relatively large. Furthermore, the selection of strength parameters for unsaturated soil during the freeze-thaw process has a great influence on the surrounding environment of the deep foundation pit, as well as the stress and the deformation of the supporting structure. Numerical simulations using strength parameters under different temperatures (20°C, - 15°C, 20°C -15°C--20°C) resulted in the following general trend for the horizontal displacement of the retaining structure, the horizontal force of the pile side and the displacement of the top of the deep foundation: simulation results of frozen soil parameters > simulation results of dynamic changes of parameters with temperature > simulation results of normal temperature soil parameters. [ABSTRACT FROM AUTHOR]

Published

2021

48. Determination of rock mass strength parameters for use in local-scale seismic landslide hazard zonation, Roudbar quadrangle, Iran

Author

Mirabedini, M. E., Haghshenas, E., and Ganjian, N.

Published

2022

49. Evolution models of the strength parameters and shear dilation angle of rocks considering the plastic internal variable defined by a confining pressure function.

Author

Jin, Junchao, She, Chengxue, and Shang, Pengyang

Subjects

*SHEAR strength, *PLASTICS, *MINERAL collecting, *STRESS-strain curves, *EXPONENTIAL functions, *GAUSSIAN function

Abstract

Based on the triaxial test results of 30 types of rocks, by analysing the confining pressure function and defining a new plastic internal variable, the evolution laws of the strength parameters and shear dilation angle with a defined plastic internal variable are studied, and the corresponding evolution models are established. First, the complete stress-strain curves of 30 types of rocks are collected from published literature; from these curves, the critical equivalent plastic strains under different confining pressures are extracted. With the confining pressure and critical equivalent plastic strain data of the 30 types of rocks, fitting is performed for 23 different functions. The results demonstrate that the three-parameter allometric power-type function is the best to serve as the confining pressure function to define the plastic internal variable. Second, the strength and plastic strain data of the 30 types of rocks are extracted and transformed into the strength and plastic internal variable data. By analysing the evolution laws of the strength parameters considering the plastic internal variable, the Gaussian function is adopted to uniformly characterise the variation in the strength parameters with the plastic internal variable. Third, the shear dilation angle, confining pressure and plastic strain data of the 30 types of rocks are extracted and transformed into shear dilation angle, confining pressure and plastic internal variable data. By analysing the evolution law of the shear dilation angle considering the confining pressure and the plastic internal variable, a negative exponential function is adopted to uniformly characterise the nonlinear evolution of the shear dilation angle. Finally, the proposed evolution models of the strength parameters and the shear dilation angle are integrated into ABAQUS. By comparing the simulated complete stress-strain curves with the experimental curves of the different rock types, it is verified that the proposed models can be used to correctly simulate the nonlinear deformation and failure of different rock types. This research overcomes the shortcomings of the existing models and has wide application prospective. [ABSTRACT FROM AUTHOR]

Published

2021

50. Influence of the Spatial Variability of Soil Shear Strength on Deep Excavation: A Case Study of a Bangkok Underground MRT Station.

Author

Nguyen, Thanh Son and Likitlersuang, Suched

Subjects

*SHEAR strength of soils, *MONTE Carlo method, *SAFETY factor in engineering, *FINITE element method, *SUBSOILS, *RANDOM fields

Abstract

This paper investigates the effects that the spatial variability of a soil's undrained shear strength has on lateral wall movements and ground surface settlements when performing a deep excavation stability analysis. A random finite-element method is employed to statistically assess a deep excavation. A case study based on an actual deep excavation project in Bangkok's subsoils was used to validate the methodology. The two-dimensional spatial variability of the undrained shear strength in the clay layers of Bangkok's subsoil is simulated using the random field theory and Monte Carlo simulation. The Mohr–Coulomb model is used to predict lateral wall movements and ground surface settlements, while the stability analysis of the deep excavation is evaluated by the factor of safety using the strength reduction approach. The results show that spatial variability highly affects the distribution of lateral wall movements and ground surface settlements, as well as the scatter of the factor of safety corresponding to progressing stages of excavation. [ABSTRACT FROM AUTHOR]

Published

2021