Scaling effects on the seismic response of a closed-end pipe pile embedded in dry and saturated coarse grain soils

• Published in: International Journal of Computational Materials Science and Engineering
• Main Author: Al-Jeznawi D.; Jais I.B.M.; Al-Janabi M.A.Q.; Alzabeebee S.; Albusoda B.S.; Keawsawasvong S.
• Format: Article
• Language: English
• Published: World Scientific 2024
• Online Access: https://www.scopus.com/inward/record.uri?eid=2-s2.0-85158897428&doi=10.1142%2fS2047684123500239&partnerID=40&md5=6e7fe8cafed74e38a494d1cf1a710c56

Foundations can be subjected to dynamic or seismic loads depending on their applications and the site being constructed in. The researchers concentrated their works on investigating the reasons of the significant damage of piles during seismic excitation. Based on the findings of laboratory experiments and other numerical analyses, such failures were referred to as the kinematic impact of the earthquake on piles since they were associated with discontinuities in the subsoil because of sudden changes in soil stiffness. The current work investigates the seismic response of closed-end (CE) pipe pile using three-dimensional finite element analysis, including the impact of the scaling-up model, acceleration-time history of the ground motion, and ground conditions. The numerical model is developed using a variety of scaling rules and the outputs of the available laboratory tests. The current results showed that the saturated sand models have larger pile deformation factors than dry sand models. Pile frictional resistance was evaluated numerically, and the entire findings were evaluated against the earlier work. Mainly, the frictional resistance around the pile shaft was lower than that at the pile tip, and the frictional resistance factor on the soil surface of dry soil models was larger than that of saturated soil models. Owing to the acceleration amplifications, the pile and soil suffered cycles of compression and tension stresses. A hysteresis loop is broader and flatter on the x-axis as the shear strain increases serve to identify the shear stress–strain plane behavior. The main outputs of the scaled models were normalized to provide a deep insight of model to prototype scaling effects. © 2024 World Scientific. All rights reserved.