Temperature uniformity measurement and temperature field simulation analysis of bell-type furnace for high-temperature annealing process of grain-oriented silicon steel

IF 2 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY

International Journal of Mechanical and Materials Engineering Pub Date : 2025-06-18 DOI:10.1186/s40712-025-00300-0

Xiaoqian Peng, Sihong Zuo, Gangqiang Fan, Xing Qin, Hang Yu, Yilai Zhou, Chuanjiang Qin, Shoutian Hu

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Abstract

The temperature uniformity of grain-oriented silicon steel coils during high-temperature annealing in bell-type furnaces critically influences the post-annealing product performance. In this study, experimental measurements of temperature values at representative points within the steel coil were combined with simulations to systematically investigate the temperature field distribution under different heating rates. The results indicate that the current heating scheme leads to a significant temperature difference between the inner ring and the peripheral area of the steel coil. To reduce this temperature difference, targeted optimization schemes have been developed to minimize the temperature differential between the coldest and hottest areas without compromising production efficiency. These optimizations aim to achieve a more uniform temperature distribution, thereby enhancing the overall performance of the final product.

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晶粒取向硅钢高温退火钟式炉温度均匀性测量及温度场模拟分析

晶粒取向硅钢卷在钟形炉高温退火过程中的温度均匀性对退火后产品的性能有重要影响。本研究通过对钢卷内代表性点温量值的实验测量与模拟相结合，系统研究了不同升温速率下的温度场分布。结果表明，当前的加热方案导致钢卷内环和外围区域之间存在明显的温差。为了减少这种温差，我们开发了有针对性的优化方案，在不影响生产效率的情况下，最大限度地减少最冷和最热区域之间的温差。这些优化旨在实现更均匀的温度分布，从而提高最终产品的整体性能。

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