Disturbance Evolution Behavior of Loess Soil under Triaxial Compression

Xu, Yongbin; Guo, Panpan

doi:10.1155/2020/4160898

Cited by 8 publications

(5 citation statements)

References 27 publications

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“…In recent years, with the deepening of mathematical and mechanical theories and the rapid development of computer technology, numerical simulation methods have been widely used in the theoretical research and engineering problem processing of geotechnical engineering [70][71][72][73][74][75][76][77] FEM is the widely used simulation method in the study of rock fracture mechanics [78,79]. The solution of the stress field at the crack tip, the calculation of the stress intensity factor, and the J-integral can all be solved by FEM.…”

Section: Numerical Simulation Methodsmentioning

confidence: 99%

Fracture Behavior of Rock with Initial Damage: Theoretical, Experimental, and Numerical Investigations

et al. 2020

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Geomaterials such as rock mass often have initial damage under the influence of long-term geological action and hydration corrosion environment. The initial damage affects the integrity and stability of the rock mass, resulting in a difference in the mechanical properties of jointed rock mass and intact one. Therefore, the study of the fracture and failure characteristics of the jointed rock mass is of great significance. Most of the previous researches into the fracture behavior of rock with initial damage are based on model testing, theoretical analysis, and numerical simulation of rock mass with preexisting flaws. This review concentrates on the theoretical, experimental, and numerical efforts that have been devoted to the fracture characteristics of rock or rock-like specimens with preexisting flaws under compression. Some suggestions on the future research work in this field are also given.

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Section: Numerical Simulation Methodsmentioning

confidence: 99%

Fracture Behavior of Rock with Initial Damage: Theoretical, Experimental, and Numerical Investigations

et al. 2020

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“…Sample preparation is one of the critical steps during the performance of a laboratory-scale hydraulic fracturing experiment. To prepare a sample, first, the material, geometry, and dimension need to be determined, followed by processing such as cutting, mixing, curing, drilling, and casing [88][89][90][91][92]. When selecting a sample material, the in situ reservoir formations are the preferences.…”

Section: Sample Preparationmentioning

confidence: 99%

Advances in Laboratory‐Scale Hydraulic Fracturing Experiments

Qian

Guo

Wang

et al. 2020

Advances in Civil Engineering

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Hydraulic fracturing has been widely applied to stimulate the natural gas and oil production from unconventional reservoirs. To optimize the design of hydraulic fracturing in this application, an accurate estimation of the initiation and propagation of hydraulic fractures is indispensable. However, it still remains challenging as a result of the complex stress state and geological conditions. On account of their ability to complete control some significant factors and efficient observation of fracture geometry, laboratory-scale hydraulic fracturing experiments have received abundant research attention in recent years. This paper presents a review of the state of the art of laboratory-scale hydraulic fracturing experiments, focusing on the scaling analysis, experimental setup, fracturing fluids, and sample preparation. A discussion of the directions for future research is also provided with the intention of stimulating the development of the experimental technique for investigating hydraulic fracturing.

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“…From 1966 to 1978, researchers found that the newly accumulated loess has similar characteristic indexes to Q3 loess, but it has high compressibility and low bearing capacity (Shaanxi Comprehensive Survey Institute, 1973). Since 1978, a breakthrough has been made in the microstructure, pore structure, and its influence on the engineering properties of loess Wang and Lin, 1990;Xu and Guo, 2020;Xu et al, 2020). Unfortunately, none of these methods take into account the dynamic stress like earthquake.…”

Section: Introductionmentioning

confidence: 99%

Mesoscopic Characteristics and Performance Evaluation of Loess Treated by Different Anti-Seismic Subsidence Technologies

Wang

Shao

et al. 2022

Front. Earth Sci.

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The meso-structure of the soil has an important restriction on its engineering properties. Based on dynamic triaxial tests and SEM meso-structure test experiments, this study investigated the meso-scale structural deformation characteristics of Q3 loess samples treated by physical, chemical, and compound improvement methods, before and after strong earthquakes of typical seismic subsidence loess. On this basis, the seismic subsidence performance of the improved method is given under the conditions of frequent earthquakes, fortifying earthquakes, and rare earthquakes. The results show that 1) the physical improvement method has the most obvious effect on the elimination of macropores and overhead pore structures; 2) the chemical method can generate unique glass beads or flocculated fine structures, which can greatly enhance the strength of the soil and play the role of filling, cementing, or buffering, respectively, in the event of a strong earthquake; 3) for several improved treatment methods, the amount of seismic subsidence increases non-linearly with the increase in peak acceleration; and 4) in the event of frequent earthquakes, the earthquake subsidence can be eliminated by the method of adding fly ash, and when the fortification earthquake comes, the dynamic composite method can completely eliminate the seismic subsidence of the site. The related results can give reasonable suggestions for the treatment of seismic subsidence of different foundations in the “resilient urban and rural” and key engineering construction and seismic design of China’s loess area.

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Disturbance Evolution Behavior of Loess Soil under Triaxial Compression

Cited by 8 publications

References 27 publications

Fracture Behavior of Rock with Initial Damage: Theoretical, Experimental, and Numerical Investigations

Fracture Behavior of Rock with Initial Damage: Theoretical, Experimental, and Numerical Investigations

Advances in Laboratory‐Scale Hydraulic Fracturing Experiments

Mesoscopic Characteristics and Performance Evaluation of Loess Treated by Different Anti-Seismic Subsidence Technologies

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