全部 标题 作者
关键词 摘要

OALib Journal期刊
ISSN: 2333-9721
费用:99美元
投递稿件

查看量下载量

相关文章

更多...
金属学报  2012 

C和Nb含量对TP347HFG钢在650℃析出相参量和持久寿命的影响

DOI: 10.3724/SP.J.1037.2011.00677, PP. 450-454

Keywords: TP347HFG钢,C和Nb含量,相参量,持久寿命

Full-Text   Cite this paper   Add to My Lib

Abstract:

研究了C和Nb含量对TP347HFG钢在650℃析出相参量(成分、体积分数和尺寸)和持久寿命的影响.对ASME成分范围内的2种不同C和Nb含量的TP347HFG钢在650℃,230和150MPa条件下进行持久实验,持久寿命分别为199,420h和2426,8837h,其中C含量较低Nb含量较高的样品持久寿命较长.对持久管样的EPMA-EDS+MPSM和TEM-EDS分析表明,较低的C含量和较高的Nb含量对应较少的M23C6和较多的MX,并阻碍了M23C6的聚集粗化,同时基体中可保留较多的Cr,有利于延长持久寿命.此外,运用热力学软件Thermo-Calc分析了在500--1300℃范围内C和Nb组合含量的变化对各相成分和体积分数的影响,与实验结果相吻合.

 References

[1]  (彭芳芳, 彭志方, 陈方玉. 见: 中国电机工程学会主编, 600 MW /1000 MW超超临界机组新型钢国产化研讨会报告文集, 扬州: 中国电力期刊网, 2009: 175)
[2]  Peng Z F, Peng F F, Chen F Y. Electr Power Constr, 2009; 30(12): 1
[3]  (彭志方, 彭芳芳, 陈方玉. 电力建设, 2009; 30(12): 1)
[4]  Peng Z F, Cai L S, Dang Y Y, Zhao L, Peng F F, Yang Z G, Yan G Z,Chen S G, Zhou J, Zhou Y G. Mater Sci Forum, 2011; 706-709: 2450
[5]  Kuai C G, Peng Z F. Acta Metall Sin, 2008; 44: 897
[6]  (蒯春光, 彭志方. 金属学报, 2008; 44: 897)
[7]  Iseda A, Okada H, Semba H, Igarashi M. Energy Mater, 2007; 2: 199
[8]  Yagi K, Merckling G, Kern T U, Irie H, Warlimont H. Creep Properties of Heat Resistant Steels and Superalloys.Berlin: Springer-Verlag, 2004: 249
[9]  Erneman J, Schwind M, Andren H O, Nilsson J O, Wilson A,Agren J. Acta Mater, 2006; 54: 67
[10]  Nilsson J O. Mater Sci Forum, 2007; 539-543: 4920
[11]  Sourmail T. Mater Sci Technol, 2001; 17: 1
[12]  Thorvaldsson T, Dunlop G L. Met Sci, 1980; 1: 513
[13]  Laha K, Kyono J, Sasaki T, Kishimoto S, Shinya. Metall Mater Trans,2005; 36A: 399
[14]  Thorvaldsson T, Dunlop G L. Met Sci, 1982; 16: 184
[15]  Grot A S, Spruiell J E. Metall Trans, 1975; 6A: 2023
[16]  Keown S R, Pickering F B. Creep Strength in Steel and High-Temperature Alloys. London: The Metals Society, 1974: 134
[17]  Wadsworth J, Keown S R, Woodhead J H. Met Sci, 1976; 10: 105
[18]  Adamson J M, Martin J W. J Iron Steel Inst, 1972; 210: 271
[19]  Yu H Y, Dong J X, Xie X S. Chin J Mater Res, 2010; 24: 449
[20]  (于鸿垚, 董建新, 谢锡善.材料研究学报, 2010; 24: 449)
[21]  Guo F Q, Cheng S C, Liu Z D, Bao H S, Zhang D M. Mater Mech Eng, 2007; 31: 11
[22]  (郭富强, 程世长, 刘正东, 包汉生, 张代明. 机械工程材料, 2007; 31: 11)
[23]  Taneike M, Sawada K, Abe F. Metall Mater Trans, 2004; 35A: 1255
[24]  Peng Z F, Yang Z G, Yan G Z, Chen S G, Zhou Y G. In: Academic Committees of the Superalloys, CSM ed., High-Temperature Structural Materials for Power and Energy Resource-Proc 11th Annual Chinese Conference on Superalloys, Shanghai: Metallurgical Industry Press, 2007: 666
[25]  (彭志方, 杨志刚, 阎光宗, 陈盛广, 周元贵. 见: 中国金属学会高温材料分会主编,动力与能源用高温结构材料-第11届中国高温合金年会论文集, 上海: 冶金工业出版社,2007: 666)
[26]  Peng F F, Peng Z F, Chen F Y. In: Chinese Society for Electrical Engineering ed., Symposium on Sinicization of New Type Steels for 600 MW/1000 MW Ultra-Supercritical Units, Yangzhou: China Electric Power Journal Net, 2009: 175

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133