Microscopic mechanism of particle detachment in granular materials subjected to suffusion in anisotropic stress states

The susceptibility of a granular soil to suffusion is strongly dependent on its grain size distribution (GSD) and the mechanical and hydraulic conditions it is subjected to. This study investigates the onset of suffusion considering the effect of confining pressure and stress anisotropy using a fully resolved computational fluid dynamics and discrete element method (CFD–DEM). Three benchmarks, including the sedimentations of single and two adjacent spheres and the classic one‐dimensional (1D) consolidation are performed to demonstrate the capability of this method for high‐fidelity particle‐fluid simulations. A modified hydraulic criterion for the onset of suffusion considering stress anisotropy is presented. The microstructural changes of soil specimens before and during global suffusion are inspected, with emphasis on the evolutions of particle kinetic energy and displacements, force chain networks, and stress anisotropy. We found that the critical hydraulic gradient is negatively correlated with the confining pressure and the degree of stress anisotropy. Fine particles in the soil matrix are locally detached at small hydraulic gradients before the apparent global suffusion, as manifested by the variation of particle kinetic energy and coordination numbers. The roles of different contact types on force transmission and stress anisotropy in eroded specimens are also examined.

Section: Coupling Proceduresmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A resolved CFD–DEM investigation into the onset of suffusion: effect of confining pressure and stress anisotropy

Chen,

Hu,

Yang

et al. 2023

“…With the development of particle scale techniques (e.g., discrete element method [DEM] 15 ), numerical simulations could provide a feasible way to track the movement of every single particle at an elementary scale. Most recently, the multiphase coupled parallel calculation methods incorporating the fluid in DEM, 16 including the coupled lattice Boltzmann-DEM 17,18 (LMB-DEM), coupled pore-scale finite volume-DEM 19 (PFV-DEM), and coupled computational fluid dynamics-DEM 20 (CFD-DEM), have been raised much attention, among which, the unresolved CFD-DEM method has been widely adopted in the study related to internal erosion. [21][22][23][24][25][26][27][28][29] Unlike the fully resolved method where the size of a CFD cell has to be at least 5−10 times smaller than the particle size to precisely calculate the fluid-particle interface, the unresolved coupling allows a much coarser fluid mesh, which is more appropriate to the geotechnical applications.…”

Section: Introductionmentioning

confidence: 99%

Effect of particle shape and bedding angle on suffusion in gap‐graded granular soils by coupled CFD‐DEM method

Zhou

Qian

Yin

et al. 2023

The natural deposition of soils results in significant fabric anisotropy, and its influence on suffusion remains unclear. In this study, a series of gap-graded soil samples with different particle shapes and bedding angles are generated and implemented into the coupled computational fluid dynamics-discrete element method (CFD-DEM) simulations to investigate the migration of fine particles within the coarse grain matrix. Macroscopic results, including mass loss, void ratio variation, and soil deformation, as well as microscopic particle trajectory, force chain network, and contact orientation are analyzed. In addition, drained triaxial tests on samples before and after erosion are carried out. All results turn out that the greater the bedding angle, the more severe the loss of fines and the more significant the soil deformation. Three different migration characteristics can be identified according to soil anisotropy degree, that is, when the bedding angle is 0 • , the migration of fine particles remains relatively stable; when the bedding angle is 30 • and 60 • , the particle migration shows a gradual change throughout the erosion; when the bedding angle is 90 • , the fine particles migrate significantly in the very early stages of suffusion. Besides, the aspect ratio (AR) of the particle is found to be beneficial for both erosion resistance and soil strength.

“…The coupling simulation of DEM‐CFD, in which the fluid flow is still simulated by the continuum method, is recently being used to describe the suffusion mechanism, especially in small‐scale tests 20,21 . Moreover, the DEM‐LBM has recently been developed for the further investigation of the suffusion behavior such that the high resolution of the fluid flow and the fluid‐particle flow interaction could be better illustrated 22 . Nevertheless, some difficulty remains in the scaling up of the simulation due to the calculation method, which requires a higher computational cost due to the increase in the number of distinct particles.…”

Section: Introductionmentioning

confidence: 99%

Modeling suffusion of ideally gap‐graded soil

Tangjarusritaratorn

Miyazaki

Kikumoto

et al. 2022

A novel framework for describing suffusion in cohesionless soil, incorporating ideally gap-graded soil, is presented in this paper. The key assumption of the proposed simulation is that an erodible particle flow is induced primarily by drag force. The multiphase flow simulation for seepage-soil particle flow phenomena is conducted based on the proposed framework. The validity of the proposed method is checked through a simulation of past laboratory experiments, in which the variation in grain size distributions is grasped by a sieve analysis. The primary results show cumulative fines loss; therefore, a comparison of the cumulative fines loss is mainly discussed in this research. In addition, a discussion is given on the two different parameters affecting the erosion behavior, namely the 𝑝 − 𝑣𝑎𝑙𝑢𝑒 in the tortuosity function, 𝑇(∅), and the clogging relaxation time, 𝛽 𝑐𝑙𝑜𝑔 . The tortuosity is the ratio of the actual flow path and the distance between its ends, while clogging relaxation time is the parameter that considers the particle flow through the bottleneck. The results show that the numerical simulation provides a good correlation with the experiment, while the 𝑝 − 𝑣𝑎𝑙𝑢𝑒 is 3 which is the highest value for a geo-material. Moreover, the simulation results of the cumulative fines loss for each particle size also confirm that smaller particles will be fully eroded earlier than larger ones, and that larger particles will slowly become detached from the soil mass.