长期时效对<span>C276合金组织和力学性能的影响</span>

doi:10.3724/SP.J.1037.2012.00728

金属学报

2013, Vol. 49

Issue (6): 763-768 DOI: 10.3724/SP.J.1037.2012.00728

论文

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长期时效对C276合金组织和力学性能的影响

刘锦溪^1,2),张继祥¹⁾,陆燕玲²⁾,李肖科²⁾,李志军²⁾,周兴泰²⁾

1)重庆交通大学机电与汽车工程学院, 重庆 400074
2)中国科学院上海应用物理研究所堆材料与工程技术部, 上海 201800

EFFECT OF LONG-TERM AGING ON MICROSTRUCTURE AND MECHANICAL PROPERTIES OF ALLOY C276

LIU Jinxi^1,2), ZHANG Jixiang¹⁾, LU Yanling²⁾, LI Xiaoke²⁾, LI Zhijun²⁾, ZHOU Xingtai²⁾

1) College of Mechatronics and Automobile Engineering, Chongqing Jiaotong University, Chongqing 400074
2) Department of Nuclear Materials Science and Engineering, Shanghai Institute of Applied Physics, Chinese Academy of Sciences, Shanghai 201800

引用本文:

刘锦溪,张继祥,陆燕玲,李肖科,李志军,周兴泰. 长期时效对C276合金组织和力学性能的影响[J]. 金属学报, 2013, 49(6): 763-768.
LIU Jinxi, ZHANG Jixiang, LU Yanling, LI Xiaoke, LI Zhijun, ZHOU Xingtai. EFFECT OF LONG-TERM AGING ON MICROSTRUCTURE AND MECHANICAL PROPERTIES OF ALLOY C276[J]. Acta Metall Sin, 2013, 49(6): 763-768.

全文: PDF(2998 KB)

摘要:

采用TEM和SEM研究了C276镍基高温合金在700℃长期时效过程中的组织变化,利用万能高温材料试验机研究时效后合金试样700℃高温力学性能,并利用SEM对拉伸断口进行形貌分析. 结果表明, 700℃长期时效后,C276合金在晶界和晶内析出大量块状μ相和M₆C碳化物, 且随时效时间的延长,块状析出相长大, 晶界处的析出相向晶内呈针状生长.析出相对合金有一定的强化效果,高温长期时效, 合金强度不会降低.合金的塑性随时效时间的延长先降低后增加, 在时效720 h达到峰值后又随着时间延长而降低,但在较长时效时间内合金保持较好的塑性. 高温长期时效的C276合金高温拉伸断裂方式为韧性断裂.

关键词 ：镍基高温合金C276, 长期时效, 力学性能, 析出相

Abstract：

Nickel-based superalloy C276 had become one of the alternative materials in simulation loop of thorium molten salt reactor(TMSR) nuclear power system. The strength and plasticity decay of C276 alloy under high temperature environment for long time will directly threatened the security of simulation loop of TMSR. The microstructure of C276 alloy after long-term aging at 700℃ was studied by TEM and SEM with EDS, and the high temperature mechanical performance of C276 alloy after aging was researched at 700℃ with an universal high-temperature materials testing machine. At the same time, the morphology of tensile fracture was analyzed by SEM. The results show that massive block μ phase and M₆C carbides are precipitated after long--term aging with 700℃ at the grain boundaries and within grains of C276 alloy, and the block precipitated phase grains grow up with aging time, some precipitated grains at boundaries extend forward the~interior of based crystal. The alloy is strengthened by the effect of precipitation phase, so the strength is not reduced after long--term aging at 700℃ high temperature. As aging time increases, the plasticity of C276 alloy reduces firstly and then increases to the peak after aging 720 h, and decreases again. However, the plasticity of C276 alloy still maintain well after longer aging time. The high temperature tensile fracture mode of C276 alloy is ductile fracture after long-term aging.

Key words： nickel-based superalloy C276 long-term aging, mechanical property precipitation

收稿日期: 2012-12-10

基金资助:

国家重点基础研究发展计划项目2010CB934501, 国家自然科学基金项目11005148和50904044,中国科学院战略性先导科技专项项目XDA02040000,中国科学院院长基金特别支持项目29以及上海市科学技术委员会项目11JC1414900资助

作者简介: 刘锦溪, 男, 1987年生, 硕士生

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https://www.ams.org.cn/CN/10.3724/SP.J.1037.2012.00728 或 https://www.ams.org.cn/CN/Y2013/V49/I6/763

[1] Rebak R B, Crook P. Adv Mater Processes, 2000; 157: 37

[2] Akhter J I, Shaikh M A.J Mater Sci Lett, 2001; 20: 333

[3] Turchi P E A, Kaufman L, Liu Z K.Calphad, 2007; 31: 237

[4] Fuchs G E, Dannemann K A, Deragon T C. Long Term Stability of High Temperature Materials. Pennsylvania: TMS, 1999: 3

[5] Janowski G M, Harmon B S, Pletkn B J.Metall Trans, 1987; 18A: 1341

[6] Pollock T M. Mater Sci Eng, 1955; B32: 255

[7] Murata Y.J Mater Sci, 1983; 23: 2069

[8] Tawancy H M.J Mater Sci, 1981; 16: 2883

[9] Garossen T J, McCathy G P. Metall Trans, 1985; 16A: 1213

[10] Liu W C, Chen Z L, Yao M. Metall Trans, 1999; 30A: 31

[11] Song J X, Xiao C B, Li S S, Han Y F. Acta Metall Sin, 2002; 38: 250

(宋尽霞, 肖程波, 李树索, 韩雅芳. 金属学报, 2002; 38: 250)

[12] Zhao S Q, Dong J X, Xie X S. Chin J Nonferrous Met, 2003; 13: 565

(赵双群, 董建新, 谢锡善. 中国有色金属学报, 2003; 13; 565)

[13] Ma Y, Lu D G , Mao X P, Zhang L Y, Cai J. Rare Met Mater Eng, 2010; 39: 1571

(马雁 , 陆道纲, 毛雪平, 张立殷, 蔡军. 稀有金属材料与工程, 2010; 39: 1571)

[14] Raghavan M, Berkowitz B J, Scanlon J C. Metall Trans, 1982; 13A: 979

[15] Lloyd A C, Shoesmith D W, Mcinyer N S, Noel J J.J Electrochem Soc, 2003; 150: B120

[16] Streicher M A. Corrosion, 1976; 32: 79

[17] Jin W K, Byunq H C, Jin S H. J Korean Inst Met Mater, 2002; 40: 1016

[18] Ahmad M, Akhter J I, Akhtar M, Iqbal M, Ahmed E, Choudhry M A. J Alloys Compd, 2005; 390: 88

[19] Jiao S Y, Zhu G N, Dong J X, Zhang Q Q. J Mater Eng, 2011; (1): 47

(焦少阳, 朱冠妮, 董建新, 章清泉. 材料工程, 2011; (1): 47)

[20] Shi A J, Dong J X, Zhang M C, Zheng L. Spec Steel, 2009; 30: 7

(施爱娟, 董建新, 张麦仓, 郑磊. 特殊钢, 2009; 30: 7)

[21] Tawancy H M. J Mater Sci, 1996; 31: 3929

[22] Zheng Y R. Acta Metall Sin, 1999; 35: 1242

(郑运荣. 金属学报, 1999; 35: 1242)

[23] Cai Y L, Zheng Y R. Acta Metall Sin, 1982; 18: 30

(蔡玉林, 郑运荣. 金属学报, 1982; 18: 30)

[24] Ma Y H, Zhao K, Lou L H, Hu Z Q. J Chin Electr Microsc Soc, 2006; 25(suppl): 116

(马永会, 赵锴, 楼琅洪, 胡壮麒. 电子显微学报, 2006; 25(增刊): 116)

[25] Zhao M H, Zhang X Y, Jiao L Y, Fu H Z. Mater Eng, 1992; (sl): 121

(赵明汉, 张旭瑶, 焦兰英, 傅宏镇. 材料工程, 1992; (sl): 121)

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