Performance of X-shaped and circular pile-improved ground subject to liquefaction-induced lateral spreading

• Published in: Soil dynamics and earthquake engineering (1984) Vol. 109; pp. 273 - 281
• Main Authors: Li, Wenwen, Chen, Yumin, Stuedlein, Armin W., Liu, Hanlong, Zhang, Xinlei, Yang, Yaohui
• Format: Journal Article
• Language: English
• Published: Barking Elsevier Ltd 01.06.2018; Elsevier BV
• Subjects: Circularity; Deformation mechanisms; Design; Design parameters; Earthquake damage; Earthquakes; Ground improvement; Lateral displacement; Lateral spreading; Liquefaction; Pile groups; Piles; Seismic activity; Seismic design; Seismic engineering; Shake table test; Shake table tests; Soil investigations; Soil mechanics; Soil-structure interaction; Spreading; Structural engineering; X-shaped pile; Ground improvement; X-shaped pile; Liquefaction; Shake table test; Lateral spreading
• ISSN: 0267-7261; 1879-341X
• DOI: 10.1016/j.soildyn.2018.03.022

Liquefaction-induced lateral spreading has caused severe damage and significant financial losses in major earthquakes distributed globally. Groups of piling installed in liquefaction- and lateral spreading-susceptible ground has been proven to be effective in reducing lateral displacements, but further investigation into the soil-structure interactions is required to elucidate the mechanisms for mitigation of displacement. Further, it is hypothesized that cross-, or X-shaped, piling may provide improved restraint on lateral flow deformations due the destructive interference of flow imposed by their cross-section. In this paper, the effectiveness of groups of X-shaped and circular piles to mitigate lateral spreading ground was investigated to improve the understanding of the mechanisms for improvement. Shake table tests were carried out to examine and compare the efficacy and efficiency of X-shaped and circular pile groups. Design parameters including the pile arrangement (square vs. triangular spacing) and orientation (X vs. +) of the X-shaped piling were also taken into consideration. The results demonstrate that the X-shaped pile groups can significantly reduce the lateral displacement and the areal extent of liquefied sand flow as compared to the unimproved and circular pile-improved ground, and that the spacing and orientation play a critical role in the deformation response. These findings will help inform the design of pile-improved ground as well as the design of structural piling adjacent to submerged, liquefiable slopes. •The efficacy and efficiency of X-shaped pile group to mitigate liquefaction-induced lateral spreading were investigated.•Instrumented shake table tests enabled comparisons between X-shaped and circular pile group.•Design variables including the pile arrangement and X-shaped pile orientation were considered.•Image processing techniques were used to quantify the areal extent of lateral flow.•X-shaped pile groups can significantly reduce the extent of lateral displacement.