Literature Review on the Discrete Element Method in Asphalt Mixtures

Yao, Hui; Xu, Mingming; Liu, Junfu; Liu, Yu; Ji, Jie; You, Zhanping

doi:10.3389/fmats.2022.879245

Cited by 11 publications

(4 citation statements)

References 38 publications

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“…Numerical simulation tests are more suitable for characterizing the load transfer mechanism of asphalt mixtures. Furthermore, the combination of DIP and a numerical simulation method, which is the recommended method to be used in current and future research, can provide a better way to investigate the load transfer mechanism of an asphalt mixture [ 52 , 53 ]. Based on the meso-scale structure of asphalt mixture obtained by the DIP method, the asphalt mixture load transfer characteristics can be studied by a numerical simulation.…”

Section: Definitions and Test Methods For Load Transfer Mechanismmentioning

confidence: 99%

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Review on Load Transfer Mechanisms of Asphalt Mixture Meso-Structure

Wang

Miao

et al. 2023

Materials

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Asphalt mixture is a skeleton filling system consisting of aggregate and asphalt binder. Its performance is directly affected by the internal load transfer mechanism of the skeleton filling system. It is significant to understand the load transfer mechanisms for asphalt mixture design and performance evaluation. The objective of this paper is to review the research progress of the asphalt mixture load transfer mechanism. Firstly, this paper summarizes the test methods used to investigate the load transfer mechanism of asphalt mixtures. Then, an overview of the characterization of load transfer mechanism from three aspects was provided. Next, the indicators capturing contact characteristics, contact force characteristics, and force chain characteristics were compared. Finally, the load transfer mechanism of asphalt mixtures under different loading conditions was discussed. Some recommendations and conclusions in terms of load transfer mechanism characterization and evaluation were given. The related work can provide valuable references for the study of the load transfer mechanism of asphalt mixtures.

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Section: Definitions and Test Methods For Load Transfer Mechanismmentioning

confidence: 99%

“… The indirect tensile (IDT) test of asphalt mixtures [ 52 ]: the green balls represent aggregates; the blue balls represent mastic; the white balls represent air voids; the black line represents the force chain. …”

Section: Figurementioning

confidence: 99%

Review on Load Transfer Mechanisms of Asphalt Mixture Meso-Structure

Wang

Miao

et al. 2023

Materials

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“…Fluorescence microscopy enables direct observation of the microstructure in the cold mixed asphalt, clearly presenting the interfacial bonding between the geopolymer, asphalt, and aggregates. Meanwhile, discrete element simulation establishes a virtual model on the computer to simulate the loading damage process of the Marshall test, assessing the internal mechanical responses of the mixture (Xiao et al, 2021;Yao et al, 2022). The two techniques are complementary to each other, with one directly characterizing the microscopic morphology and the other simulating the microscopic mechanisms, jointly revealing the strengthening mechanism of the geopolymer modification.…”

Section: Methodsmentioning

confidence: 99%

Investigation on strength characteristics and mechanism of cold mix based on geopolymerization reaction

Fan,

Liang,

Sun

et al. 2023

Front. Built Environ.

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Cold mix asphalt is an energy-efficient and eco-friendly pavement material, yet its early strength is deficient. This study investigated the strength augment of cold mix asphalt through modification with geopolymer additives. Macro-strength was assessed via Marshall stability testing under varied geopolymer contents, curing durations, and water immersion conditions. Microscale analysis encompassed fluorescence microscopy to discern geopolymer-asphalt interactions and discrete element modeling to simulate the compression process. Results showed that stability rose and then fell as geopolymer content increased, with an optimal ratio of 4:3 between base asphalt and additive. Stability increased rapidly in the first 3 days of curing and accumulated at a slower rate afterwards. Fluorescence microscopy revealed that geopolymer bonded the asphalt to the aggregate surfaces. Modeling exhibited geopolymer resisted vertical loads and confined the aggregate. In summation, geopolymerization enhances cold mix strength by improving adhesion and generating a rigid 3D network encompassing aggregate particles. The discoveries provide guidance on formulating durable cold mix asphalt utilizing geopolymer additives.

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“…For instance, 2D DEM is unable to sufficiently account for aggregate interlocking and irregular aggregate shapes. The 3D models have advantages in these respects but the procedures of creating and optimizing them are computationally more expensive due to the complexity of interconnections and structures [26]. You et al [27,28] developed 2D and 3D discrete element models to simulate the dynamic modulus test of asphalt mixtures and predict the dynamic modulus of asphalt mixtures using image processing and 3D digital generation technologies.…”

Section: Introductionmentioning

confidence: 99%

Mesoscopic Analysis of Fatigue Damage Development in Asphalt Mixture Based on Modified Burgers Contact Algorithm in Discrete Element Modeling

Zhou,

Cao

2024

Materials

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This study is aimed at examining the mesoscopic mechanical response and crack development characteristics of asphalt mixtures using the three-dimensional discrete element approach via particle flow code (PFC). The material is considered an assembly of three phases of aggregate, mortar, and voids, for which three types of contact are identified and described using a modified Burgers model allowing for bond failure and crack formation at contact. The laboratory splitting test is conducted to determine the contact parameters and to provide the basis for selecting three different load levels used in the indirect tensile fatigue test and simulation. The reliability of the simulation is verified by comparing the fatigue lives and dissipated energies against those from the test. Under cyclic loading, the internal tensile and compressive force chains vary dynamically as a response to the cyclic loading; both are initially concentrated beneath the top loading strip and then extend downward along the loading line. The compressive chains are oriented roughly vertically and develop an elliptic shape as damage grows, while the tensile chains are mostly horizontal and become denser. An analysis based on the histories of the numbers of different contact types indicates that damage mainly originates from bond failures among the aggregate particles and at the aggregate–mortar interfaces. In terms of location, cracking is initiated below the loading point (consistent with observations from the force chains) and propagates downward and laterally, leading to the macrocrack along the vertical diameter. The findings provide a mesoscopic understanding of the fatigue damage initiation and propagation in asphalt mixture.

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Literature Review on the Discrete Element Method in Asphalt Mixtures

Cited by 11 publications

References 38 publications

Review on Load Transfer Mechanisms of Asphalt Mixture Meso-Structure

Review on Load Transfer Mechanisms of Asphalt Mixture Meso-Structure

Investigation on strength characteristics and mechanism of cold mix based on geopolymerization reaction

Mesoscopic Analysis of Fatigue Damage Development in Asphalt Mixture Based on Modified Burgers Contact Algorithm in Discrete Element Modeling

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