Investigating the Mechanisms and Dynamic Response of Graded Aggregate Mud Pumping Based on the Hybrid DEM-FDM Method

Investigating the Mechanisms and Dynamic Response of Graded Aggregate Mud Pumping Based on the Hybrid DEM-FDM Method

This study investigated the macro and meso mechanisms of void formation in graded aggregates within high-speed railway subgrades under train loads using a hybrid discrete element–finite difference method (DEM-FDM). First, a contact parameter inversion model based on a linear model (LM) was developed...

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Bibliographic Details
Main Authors: Kang Wang, Zhongrui Chen, Qian Chen, Zhibo Cheng, Jiawen Xu, Hongfu Tan, Lei Zhang, Le You
Format: Article
Language:English
Published: MDPI AG 2025-05-01
Series:Buildings
Subjects:
high-speed railway
graded aggregate void formation
hybrid discrete element–finite difference method
parameter calibration
dynamic response
mesoscopic analysis
Online Access:https://www.mdpi.com/2075-5309/15/10/1604
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Summary:This study investigated the macro and meso mechanisms of void formation in graded aggregates within high-speed railway subgrades under train loads using a hybrid discrete element–finite difference method (DEM-FDM). First, a contact parameter inversion model based on a linear model (LM) was developed using extensive DEM simulations through angle of repose, drop, and inclined plate tests. The contact parameters for graded aggregates were further calibrated through physical and triaxial tests. Next, a refined hybrid DEM-FDM model was established to capture void formation behavior, characterized by the contact force chain ratio, and was validated against field measurements. Finally, simulations were conducted under different levels of void formation to explore the associated mechanisms based on dynamic response and meso-mechanical analysis. The results showed that the LM-based inversion model could accurately determine the contact parameters. The hybrid model’s predictions of dynamic displacement and acceleration under various train speeds fell within the range of the field data. When the fine particle loss ratio <i>l<sub>p</sub></i> was ≤3%, the dynamic displacement and acceleration remained below the standard limits of 0.22 mm and 10 m/s<sup>2</sup>. As <i>l<sub>p</sub></i> increased, the contact between the roadbed and base weakened, and complete separation occurred at <i>l<sub>p</sub></i> ≥ 11%, preventing effective load transfer. These findings offer new insights into void formation in graded aggregates and support the safe operation of high-speed railways.
ISSN:2075-5309

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