Microscopic damage mechanism of SA508 Gr3 steel in ultra-high temperature creep

ժҪ
ͼ/��
�ο��
�� (1)

ȫ��: PDF (0 KB) HTML (1 KB)
��: BibTeX | EndNote (RIS)

ժҪ The lower head of reactor pressure vessel (RPV) will endure a great temperature gradient above the phase transition temperature, and the creep and fracture will be the primary failure mode for the RPV material in such a situation. The interrupted creep tests were performed on a typical RPV material, SA508 Gr3 steel, at 800 ��C. The microstructure of different creep stages was examined by scanning electron microscopy and transmission electron microscopy. The results showed that the microscopic damage is mainly induced by creep cavities and coarse second-phase particles. Furthermore, the volume fractions of creep cavities and coarse second-phase particles show a linear relationship with the extended creep time. The second-phase particles are determined to be MoC in the second creep stage and Mo2C in the third creep stage, according to the results of selected-area electron diffraction pattern. Combined with energy-dispersive spectrum analysis, the segregation of precipitates caused by the migration of atoms is finally unveiled, which leads to the coarsening of the particles.

	��

	�ѱ��Ƽ��
	��ҵ��
	��ù��
	E-mail Alert
	RSS
	��
	Zhigang Xie
	Yanming HE
	Jianguo YANG
	Xiangqing LI
	Zengliang GAO

�ؼ�� �� Reactor pressure vessel, SA508 Gr3 steel, In-Vessel Retention, Second phase particle, Damage mechanism

Abstract��The lower head of reactor pressure vessel (RPV) will endure a great temperature gradient above the phase transition temperature, and the creep and fracture will be the primary failure mode for the RPV material in such a situation. The interrupted creep tests were performed on a typical RPV material, SA508 Gr3 steel, at 800 ��C. The microstructure of different creep stages was examined by scanning electron microscopy and transmission electron microscopy. The results showed that the microscopic damage is mainly induced by creep cavities and coarse second-phase particles. Furthermore, the volume fractions of creep cavities and coarse second-phase particles show a linear relationship with the extended creep time. The second-phase particles are determined to be MoC in the second creep stage and Mo2C in the third creep stage, according to the results of selected-area electron diffraction pattern. Combined with energy-dispersive spectrum analysis, the segregation of precipitates caused by the migration of atoms is finally unveiled, which leads to the coarsening of the particles.

Key words�� Reactor pressure vessel SA508 Gr3 steel In-Vessel Retention Second phase particle Damage mechanism

�ո��: 2017-03-01 ��: 2018-10-15

��ñ��:

Zhi-gang Xie, ? Yan-ming He ? Jian-guo Yang ? Xiang-qing Li ? Chuan-yang Lu ? Zeng-liang Gao. Microscopic damage mechanism of SA508 Gr3 steel in ultra-high temperature creep[J].Journal of Iron and Steel Research International, 2018, 25(4): 453-459. Zhi-gang Xie, ? Yan-ming He ? Jian-guo Yang ? Xiang-qing Li ? Chuan-yang Lu ? Zeng-liang Gao. Microscopic damage mechanism of SA508 Gr3 steel in ultra-high temperature creep. , 2018, 25(4): 453-459.

��ӱ��:

http://gt.chinamet.cn/Jweb_gtyjxb_en/CN/ �� http://gt.chinamet.cn/Jweb_gtyjxb_en/CN/Y2018/V25/I4/453

[1]	Hashimoto S, Ugawa S, Nanko K, et al. Sci Rep, 2 (2012), 416.
[2]	Friedman S M, Bulletin of the atomic scientists, 67 (2011) No.5, 55-65.
[3]	Steinhauser G, Brandl A, Johnson T E. Sci Total Environ, 470 (2014), 800-817.
[4]	Theofanous T G, Liu C, Addition S, et al. Nucl Eng Des, 169 (1997) No.1, 1-48.
[5]	Zhu J, Bao S, Li Y, et al. ASME 2014 Pressure Vessels and Piping Conference. Anaheim(USA) ,2014: V003T03A108 -V003T03A108.
[6]	Mao J, Zhu J, Bao S, et al. Journal of Pressure Vessel Technology, 139 (2017) No. 2, 120-126.
[7]	Jianfeng M, Xiangqing L, Shiyi B, et al. Nucl Eng Des, 310 (2016), 39-47.
[8]	Sainte C C. Report DMT/95-236, CEA Saclay. 1995.
[9]	Kim J H, Yoon E P. Journal of the Korean Institute of Metals and Materials, 36 (1998) No.8, 1329-1337.
[10]	Kim S, Kang S Y, Lee S, et al. Metallurgical and Materials Transactions A, 31(2000) No.4, 1107-1119.
[11]	Xie Z G, He Y M, Yang J G, et al. Trans Tech Publications, 853 (2016), 153-157.
[12]	Jun W. The heat treatment effect on microstructure and mechanical properties of A508-3 steel. Harbin Institute of Technology, Master Thesis, 2009.
[13]	Zhongqi S, Hong X, Feng P. Nuclear Power Engineering, (1988) No.1, 49-53.
[14]	Argon A. Strengthening mechanisms in crystal plasticity. Oxford University Press, Oxford, 2007.
[15]	Mallick A. Comp Mater Sci, 67 (2013), 27-34.