# Numerical Study of Stud Welding Temperature Fields on Steel–Concrete Composite Bridges

**Authors:** Sicong Wei, Han Su, Xu Han, Heyuan Zhou, Sen Liu

PMC · DOI: 10.3390/ma18153491 · Materials · 2025-07-25

## TL;DR

This paper studies how welding studs on steel-concrete bridges creates temperature changes that affect structural performance.

## Contribution

A precise simulation method for stud welding temperature fields is introduced and validated with real measurements.

## Key findings

- Simulated and measured peak temperatures showed a maximum error of 5%.
- Input current positively correlates with peak temperature, while plate thickness significantly affects temperature in the thickness direction.
- Welding new studs near existing ones causes minor temperature disturbances.

## Abstract

Non-uniform temperature fields are developed during the welding of studs in steel–concrete composite bridges. Due to uneven thermal expansion and reversible solid-state phase transformations between ferrite/martensite and austenite structures within the materials, residual stresses are induced, which ultimately degrades the mechanical performance of the structure. For a better understanding of the influence on steel–concrete composite bridges’ structural behavior by residual stress, accurate simulation of the spatio-temporal temperature distribution during stud welding under practical engineering conditions is critical. This study introduces a precise simulation method for temperature evolution during stud welding, in which the Gaussian heat source model was applied. The simulated results were validated by real welding temperature fields measured by the infrared thermography technique. The maximum error between the measured and simulated peak temperatures was 5%, demonstrating good agreement between the measured and simulated temperature distributions. Sensitivity analyses on input current and plate thickness were conducted. The results showed a positive correlation between peak temperature and input current. With lower input current, flatter temperature gradients were observed in both the transverse and thickness directions of the steel plate. Additionally, plate thickness exhibited minimal influence on radial peak temperature, with a maximum observed difference of 130 °C. However, its effect on peak temperature in the thickness direction was significant, yielding a maximum difference of approximately 1000 °C. The thermal influence of group studs was also investigated in this study. The results demonstrated that welding a new stud adjacent to existing ones introduced only minor disturbances to the established temperature field. The maximum peak temperature difference before and after welding was approximately 100 °C.

## Full-text entities

- **Chemicals:** ferrite (MESH:C001215), Steel (MESH:D013232)

## Full text

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## Figures

22 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12347306/full.md

## References

38 references — full list in the complete paper: https://tomesphere.com/paper/PMC12347306/full.md

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Source: https://tomesphere.com/paper/PMC12347306