Fluid–solid coupled model for the internal erosion of gap‐graded soil–rock mixtures with different fines contents: Its verification and application

Cao, Zhilin; Sun, Weichen; Xie, Qiang; Wu, Zhihui; Fu, Xiang; Fumagalli, Alessio; Tian, Da-Lang; Li, Liang

doi:10.1002/hyp.14677

Cited by 4 publications

(1 citation statement)

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“…In previous internal erosion studies, the effects of gap ratio [15,21], fines content [8,[22][23][24], and particle morphology [25][26][27][28] on internal erosion have been investigated, and valuable insights into how these factors influence the erosion process have been provided. However, most of these experimental studies focused on silty sands or sandy gravels with gravels finer than 20 mm, owing to the size limitation of the permeameters.…”

Section: Introductionmentioning

confidence: 99%

Effect of Gradation Characteristics and Particle Morphology on Internal Erosion of Sandy Gravels: A Large-Scale Experimental Study

Deng

Chen

Jin

et al. 2023

Water

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Internal erosion refers to the seepage-induced fine particle migration phenomenon in soil. Deep alluviums in valleys usually contain cohesionless gap-graded sandy gravels with poor internal stability. The construction of embankment dams on such alluviums could pose a high risk of internal erosion. This study systematically investigated the internal erosion of cohesionless gap-graded sandy gravels with an emphasis on the effects of gradation characteristics and particle morphology. A series of large-scale internal erosion tests were conducted on gap-graded sandy gravels with different gap ratios, fines contents, and coarse particle morphologies under the surcharge pressure of 1 MPa. The internal erosion characteristics, including soil permeability, eroded soil mass, and soil deformation during the erosion process were comparatively analyzed in combination with a meso-mechanism interpretation. The results show that the increase of the gap ratio can reduce the internal stability of soil and promote the mechanical instability. Fines content affected the permeability and internal stability of soil by altering the filling state of inter-granular pores and the constraints on fine particles. Coarse particles with higher roundness, sphericity, and smoothness can facilitate the movement of fine particles and promote the mechanical instability of the soil matrix.

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