Full-scale test and numerical study on seismic performance of bridge piers with 650 MPa grade steel bars

Full-scale test and numerical study on seismic performance of bridge piers with 650 MPa grade steel bars

This study employs full-scale pseudo-static cyclic tests and advanced numerical simulations to investigate the mechanical behavior and seismic performance of concrete columns reinforced with 650MPa-grade high-strength steel bars. Monotonic tensile testing demonstrates that HRB650E steel bars exhibit...

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Bibliographic Details
Main Authors: Yong Li, Dezhang Sun, Junwu Dai, Yuxuan Peng, Dali Fang, Tao Jiang, Hongyu Lei
Format: Article
Language:English
Published: Elsevier 2025-12-01
Series:Case Studies in Construction Materials
Subjects:
High-strength steel bars
HRB650E
Full-scale
Seismic performance
Pseudo-static
Online Access:http://www.sciencedirect.com/science/article/pii/S2214509525007673
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Summary:This study employs full-scale pseudo-static cyclic tests and advanced numerical simulations to investigate the mechanical behavior and seismic performance of concrete columns reinforced with 650MPa-grade high-strength steel bars. Monotonic tensile testing demonstrates that HRB650E steel bars exhibit significantly higher yield and ultimate tensile strengths than lower-grade HRB400 and HRB500E specimens. And an improved shear strength model is proposed, which can enable precise prediction of the shear capacity for HRB650E reinforced concrete bridge piers, achieving a deviation margin within 3 % of experimental values. A comparative analytical evaluation reveals that bridge piers incorporating HRB650E steel bars exhibit superior performance characteristics in structural performance assessments when compared to HRB400-grade reinforcement systems, with quantifiable improvements observed in critical metrics including load-bearing capacity, ductility, and energy dissipation mechanisms. Notably, the synergistic use of C70 high-performance concrete with HRB650E steel reinforcement demonstrates enhanced load-bearing capacity in bridge pier systems. Then, a four-segment piecewise model is developed through systematic parameterization of experimental skeleton curves, delineating sequential behavioral phases: elastic deformation, crack initiation, yielding plateau, and post-peak strength degradation. Numerical simulations in OpenSees successfully replicates the hysteretic behavior of HRB650E bridge piers. This systematic investigation establishes theoretical and practical foundations for next-generation high-performance reinforced concrete infrastructure design.
ISSN:2214-5095

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