Frontiers in Earth Science (May 2023)

Effect of geogrid on dry-shrinkage cracking of loess

  • Hong Guo,
  • Hong Guo,
  • Kuibin Yang,
  • Kuibin Yang,
  • Shaofei Wang,
  • Shaofei Wang,
  • Chen Guo,
  • Chen Guo,
  • Yalin Nan,
  • Yalin Nan,
  • Mingjiang Tao

DOI
https://doi.org/10.3389/feart.2023.1180045
Journal volume & issue
Vol. 11

Abstract

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In this paper, an experimental approach is employed to investigate the reinforcing impact of geogrids on the dry-shrinkage cracking of loess. At various evaporation temperatures and for varying specimen thicknesses, the evolution of the surface fissures induced in the loess samples with and without geogrids was monitored and analyzed. According to the findings, the evaporation rate of the samples increased when the evaporation temperature was increased, and the thickness of the samples was reduced under the same conditions. At higher temperatures, geogrids had a substantial impact on reducing the evaporation rate and suppressing the dry-shrinkage cracks. The occurrence and development of the dry-shrinkage cracks of loess are divided into three stages: the formation stage, the acceleration stage, and the stabilization stage. The maximum crack width was reduced by 20%–34% for different sample thicknesses. The ratio of the number of cracks to the number of fracture nodes in the reinforced soil was lower than that of the unreinforced soil. This reduction ratio changed further from 5.6% to 24.4% with the increased thickness. The geogrids can effectively reduce the evaporation rate of water and the development rate of the dry-shrinkage cracks in loess. Consequently, the crack distribution in the loess samples is uniform and prevents the formation of large and long cracks. Using a 3D discrete element model, it is feasible to simulate the loess before and after the geogrid reinforcement.

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