Peng Yu-Quan, Chen Tai-Cheng, Chung Tien-Jung, Jeng Sheng-Long, Huang Rong-Tan, Tsay Leu-Wen
Institute of Materials Engineering, National Taiwan Ocean University, Keelung 20224, Taiwan.
Division of Nuclear Fuels and Materials, Institute of Nuclear Energy Research, Lungtan, Taoyuan 32546, Taiwan.
Materials (Basel). 2017 Feb 8;10(2):139. doi: 10.3390/ma10020139.
The increased thermal efficiency of fossil power plants calls for the development of advanced creep-resistant alloy steels like T92. In this study, microstructures found in the heat-affected zone (HAZ) of a T92 steel weld were simulated to evaluate their creep-rupture-life at elevated temperatures. An infrared heating system was used to heat the samples to 860 °C (around A), 900 °C (slightly below A), and 940 °C (moderately above A) for one minute, before cooling to room temperature. The simulated specimens were then subjected to a conventional post-weld heat treatment (PWHT) at 750 °C for two hours, where both the 900 °C and 940 °C simulated specimens had fine grain sizes. In the as-treated condition, the 900 °C simulated specimen consisted of fine lath martensite, ferrite subgrains, and undissolved carbides, while residual carbides and fresh martensite were found in the 940 °C simulated specimen. The results of short-term creep tests indicated that the creep resistance of the 900 °C and 940 °C simulated specimens was poorer than that of the 860 °C simulated specimens and the base metal. Moreover, simulated T92 steel samples had higher creep strength than the T91 counterpart specimens.
化石发电厂热效率的提高需要开发像T92这样先进的抗蠕变合金钢。在本研究中,模拟了T92钢焊缝热影响区(HAZ)中的微观结构,以评估其在高温下的蠕变断裂寿命。使用红外加热系统将样品加热到860℃(约A)、900℃(略低于A)和940℃(略高于A)并保持一分钟,然后冷却至室温。然后将模拟试样在750℃下进行两小时的常规焊后热处理(PWHT),其中900℃和940℃模拟试样具有细小的晶粒尺寸。在处理后的状态下,900℃模拟试样由细小的板条马氏体、铁素体亚晶粒和未溶解的碳化物组成,而在940℃模拟试样中发现了残余碳化物和新鲜马氏体。短期蠕变试验结果表明,900℃和940℃模拟试样的抗蠕变性能比860℃模拟试样和母材差。此外,模拟的T92钢样品比T91对应试样具有更高的蠕变强度。