Burger’s Bonded Model for Distinct Element Simulation of the Multi-Factor Full Creep Process of Soft Rock

Xia, Chang; Liu, Zhen; Zhou, Cuiying

doi:10.3390/jmse9090945

Cited by 19 publications

(5 citation statements)

References 33 publications

(41 reference statements)

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“…where E 2 denotes the elastic modulus of the spring element, η 1 denotes the viscosity coefficient of the fractional differential element, q 1 denotes the differential order of the fractional differential element (0<q 1 <1), and D denotes the fractional differential operator. The viscoplastic strain can be obtained using Eq (5) as follows:…”

Section: Plos Onementioning

confidence: 99%

“…However, the accuracy of the simulation outcome is highly dependent on the parameters that describe the mechanical properties of soft clay [4]. In particular, the nonlinear rheological properties of soft clay present a further challenge in numerical modeling [5,6]. The current modeling parameter estimation is generally based on intelligent displacement back analysis involving an iterative procedure, which may lead to simulations of low efficiency [7].…”

Section: Introductionmentioning

confidence: 99%

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Modeling consolidation of soft clay by developing a fractional differential constitutive model in conjunction with an intelligent displacement inversion method

Liu

Ming

et al. 2022

PLoS ONE

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Studying the constitutive relation of soft clays is of critical importance for fundamentally understanding their complex consolidation behavior. This study proposes a fractional differential constitutive model in conjunction with an intelligent displacement inversion method based on the classic particle swarm optimization for modeling the deformation behavior of soft clay. The model considered the rheological properties of soft clay at different consolidation stages. In addition, statistical adaptive dynamic particle swarm optimization-least squares support vector machines were implemented to identify the model parameters efficiently. The accuracy and effectiveness of the model were validated using available experimental results. Finally, the application results showed that the proposed model could efficiently simulate coupling properties of soft clay’s primary and secondary consolidations.

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Section: Plos Onementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Modeling consolidation of soft clay by developing a fractional differential constitutive model in conjunction with an intelligent displacement inversion method

Liu

Ming

et al. 2022

PLoS ONE

Self Cite

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“…In recent years, large-scale engineering construction in this area has led to a vast number of exposed red soil slopes [3,4]. Red soil softens when it comes into contact with water, and its strength decreases [5,6]; the soil erosion in these areas is more serious. In addition, because of its low erosion resistance and insufficient nutrient supplement, it also hinders the ecological restoration of gardens [7,8].…”

Section: Introductionmentioning

confidence: 99%

Soil Remediation of Subtropical Garden Grasses and Shrubs Using High-Performance Ester Materials

Gou

Tang

et al. 2022

Sustainability

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Soil erosion due to rainstorms is a serious problem in subtropical gardens in South China. Soil conservation and the restoration of degraded landscapes are important research topics at home and abroad. Because of the sluggish growth of plants under traditional cultivation techniques, they are incapable of effectively protecting the soil. Therefore, the rapid and high-quality soil conservation of subtropical landscapes remains an urgent problem to be overcome. The purpose of this study is to improve the red soil and ground environment for the growth of grasses and shrubs through high-performance ester materials. Our objective was to find a solution for the high impact of soil loss on subtropical landscapes. In this study, we used the ecological restoration of soil as the starting point and selected a typical subtropical garden in South China as the field test point. We carried out soil erosion resistance testing using high-performance ester materials. The anti-erosion abilities of slopes under various working conditions are discussed. During the growth period, the soil indexes were monitored for a long time, and the growth of grasses and shrubs was compared. The obtained monitoring data were analyzed with mathematical statistics. We found that the addition of high-performance ester materials significantly reduced soil loss by 52.60%. High-performance ester materials have a good hydrothermal regulation function, which can promote the germination and later growth of sloping plants. The decrease in ground internal density promotes the extension of plant roots. High-performance ester materials can improve soil permeability and activity and promote vegetation growth. In terms of turf thickness and overall growth as well as shrubs crown width and height, high-performance ester materials have a beneficial effect on promoting plant growth. Soil remediation using high-performance ester materials has good economic value, high water-holding capacity, adaptability, and convenience. In this study, we determined a solution for the high impact of soil loss on subtropical landscapes. The soil remediation of a subtropical garden using high-performance ester materials was successful. The practice of landscape soil remediation engineering presented in this paper can provide a reference for typical landscape soil remediation in subtropical zones.

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“…The PVD plays an essential role in solving the seepage problem in soft soil foundation engineering [1][2][3][4][5]. Construction projects involving soft soil foundations in the coastal area of South China are increasing [6][7][8][9][10][11][12][13]. The PVD has large-scale application prospects in the future.…”

Section: Introductionmentioning

confidence: 99%

Stochastic Medium Model for the Settlement Calculation of Prefabricated Vertical Drains of Soft Soil Foundations in the Coastal Area of South China

Liu

Gao

Zhou

2022

JMSE

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The prefabricated vertical drain (PVD) is an essential means to mitigate the settlement of soft soil foundations in coastal areas of South China. The commonly used elastoplastic analytical method cannot directly reflect the interaction of different PVDs and the resulting displacement of soft soil. At the same time, these elastoplastic analysis and numerical simulation methods are greatly influenced by the values adopted for rock and soil material parameters. In this paper, we present a stochastic medium model that can directly reflect the interaction of different PVDs and the resulting displacement of soft soil. It is not affected by the characteristics of rock and soil themselves and can also reflect the actual deformation process of soft soil. According to engineering practice, the settlement curves of soft soil foundations in coastal areas of South China with PVDs exhibited distinct normal distribution characteristics, which was consistent with the description of settlement by the stochastic medium model. Hence, based on the stochastic medium model, this paper analyzed the settlement mechanism of PVDs and established a stochastic medium model for the settlement calculation of PVDs. A function for the soft soil foundation in the coastal area of South China cross-section settlement curve was presented by back analysis of the PVD model. We chose the stochastic medium model based on this methodology to explore the interaction between different PVDs. The above models were then applied to an expressway in South China. Comparing actual settlement monitoring values to calculated values obtained with the PVD model, the error between the two models was less than 15%. This research provides a new settlement calculation method of PVDs in soft soil foundations in the coastal area of South China and a new basis for designing soft soil foundations.

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Burger’s Bonded Model for Distinct Element Simulation of the Multi-Factor Full Creep Process of Soft Rock

Cited by 19 publications

References 33 publications

Modeling consolidation of soft clay by developing a fractional differential constitutive model in conjunction with an intelligent displacement inversion method

Modeling consolidation of soft clay by developing a fractional differential constitutive model in conjunction with an intelligent displacement inversion method

Soil Remediation of Subtropical Garden Grasses and Shrubs Using High-Performance Ester Materials

Stochastic Medium Model for the Settlement Calculation of Prefabricated Vertical Drains of Soft Soil Foundations in the Coastal Area of South China

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