焊前热处理对模拟焊接后风电钢粗晶粒热影响区微观结构和性能的影响

Metals Pub Date : 2024-05-17 DOI:10.3390/met14050587
Zhixing Wang, Xuelin Wang, Chengjia Shang
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引用次数: 0

摘要

通过扫描电子显微镜(SEM)和电子反向散射衍射(EBSD),系统地研究了焊前热处理对模拟焊接后粗颗粒热影响区(CGHAZ)的微观结构和低温冲击韧性的影响。夏比冲击试验验证了最佳焊前热处理条件的存在,从而在 CGHAZ 中观察到了最高的冲击韧性。焊前热处理采用了三种温度(690、720 和 750 °C),以获得三种不同的基体(钢 1、钢 2 和钢 3)进行模拟焊接。最佳的焊前热处理温度为 720 °C 15 分钟,然后进行水淬。显微结构表征显示,焊前热处理后,钢 1 和钢 2 的显微结构由贝氏体(B)组成,而焊前热处理温度超过 Ac1 近 60 ℃ 时,马氏体(M)的增加(钢 3)。通过焊前热处理获得的这些微观结构差异影响了高温奥氏体在后续模拟焊接再加热过程中的细化,从而导致 CGHAZ 中的微观结构特征截然不同。经过优化的焊前热处理后,进行单程焊接热模拟的钢 2 显示出细化的微观结构,其特点是 CGHAZ 中高密度的高角度晶界 (HAGB),尤其是在块状边界中更为明显。这些晶界有效阻止了脆性裂纹的扩展,从而提高了冲击韧性。
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Effect of Pre-Weld Heat Treatment on the Microstructure and Properties of Coarse-Grained Heat-Affected Zone of a Wind Power Steel after Simulated Welding
The effect of pre-weld heat treatment on the microstructure and low-temperature impact toughness of the coarse-grained heat-affected zone (CGHAZ) after simulated welding was systematically investigated through the utilization of scanning electron microscopy (SEM) and electron back-scattering diffraction (EBSD). The Charpy impact test validated the presence of an optimal pre-weld heat treatment condition, resulting in the highest impact toughness observed in the CGHAZ. Three temperatures for pre-weld heat treatment (690, 720 and 750 °C) were used to obtain three different matrices (Steel 1, Steel 2, Steel 3) for simulated welding. The optimal pre-weld heat treatment is 720 °C for 15 min followed by water quench. Microstructure characterization showed that there is an evident microstructure comprising bainite (B) in Steel 1 and Steel 2 after pre-weld heat treatment, while the addition of martensite (M) with the pre-weld heat treatment temperature exceeds Ac1 by almost 60 °C (Steel 3). These differences in microstructures obtained from pre-weld heat treatment influence the refinement of high-temperature austenite during subsequent simulated welding reheating processes, resulting in distinct microstructural characteristics in the CGHAZ. After the optimal pre-weld heat treatment, Steel 2 subjected to single-pass welding thermal simulation demonstrates a refined microstructure characterized by a high density of high-angle grain boundaries (HAGBs) within the CGHAZ, particularly evident in block boundaries. These boundaries effectively prevent the propagation of brittle cracks, thereby enhancing the impact toughness.
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