# Study on Seismic Behavior of Earthquake-Damaged Joints Retrofitted with CFRP in Hybrid Reinforced Concrete–Steel Frames

**Authors:** Xiaotong Ma, Tianxiang Guo, Yuxiao Xing, Ruize Qin, Huan Long, Chao Bao, Fusheng Cao, Ruixiao Hong

PMC · DOI: 10.3390/ma18214857 · 2025-10-23

## TL;DR

This study tests how adding carbon fiber to damaged building joints improves their ability to withstand earthquakes.

## Contribution

A new seismic retrofit method using CFRP is proposed and validated through low-cycle load tests and finite element analysis.

## Key findings

- Repaired joints showed a 33% increase in horizontal ultimate strength and 85% increase in energy dissipation.
- Two layers of CFRP provided better performance than one layer.
- Damage patterns shifted from surface to localized concrete deterioration at the column base.

## Abstract

Mixed structures with lightweight steel added stories are particularly vulnerable to damage and failure at the joints during seismic events. To evaluate the secondary seismic behavior of the joints in lightweight steel added stories after seismic damage repair, a low-cycle load test was conducted in this study. Following the initial damage, carbon fiber-reinforced polymer (CFRP) was applied for reinforcement, along with epoxy resin for the repair of concrete cracks. The experimental analysis focused on the structural deformation, failure characteristics, and energy dissipation capacity in both the original and repaired joint states. On the basis of the experimental findings, finite element analysis was carried out to examine the influence of varying CFRP layer configurations on the seismic performance of the repaired joints. The results revealed a significant change in the damage pattern of the repaired specimen, shifting from secondary surface damage to significant concrete deterioration localized at the bottom of the column. The failure mechanism was characterized by the CFRP-induced tensile forces acting on the concrete at the column base, following considerable deformation at the beam’s end. When compared to the original joint, the repaired joints exhibited markedly improved performance, with a 33% increase in horizontal ultimate strength and an 85% increase in energy dissipation capacity at failure. Additionally, the rotation angle between the beams and columns was effectively controlled. Joints repaired with two layers of CFRP demonstrated superior performance in contrast to those with a single layer. However, once the repaired joints met the required strength, further increasing the number of CFRP layers had a minimal influence on the mechanical properties of the joints. The proposed CFRP-based seismic retrofit method, which accounts for the strength degradation of concrete in damaged joints due to earthquake-induced damage, has proven to be both feasible and straightforward, offering an easily implementable solution to improve the seismic behavior of structures.

## Linked entities

- **Chemicals:** epoxy resin (PubChem CID 3559)

## Full-text entities

- **Chemicals:** CFRP (-), epoxy resin (MESH:D004853), Steel (MESH:D013232)

## Figures

23 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12609211/full.md

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Source: https://tomesphere.com/paper/PMC12609211