산화물 분산강화 표면처리에 따른 지르코늄 피복관의 기계적 강도

정양일; 김일현; 김현길; 장훈; 이승재; Yang-Il Jung; Il-Hyun Kim; Hyun-Gil Kim; Hun Jang; Seung-Jae Lee

Korean Journal of Materials Research, Vol.29, No.4, 271-276, April, 2019

DOI10.3740/MRSK.2019.29.4.271 Export Citation

산화물 분산강화 표면처리에 따른 지르코늄 피복관의 기계적 강도

Effects of Surface Treatment using Oxide-Dispersion-Strengthening on the Mechanical Properties of Zr-based Fuel Cladding Tubes

정양일^†, 김일현, 김현길, 장훈¹, 이승재¹

한국원자력연구원
¹한전원자력연료

Yang-Il Jung^†, Il-Hyun Kim, Hyun-Gil Kim, Hun Jang¹, and Seung-Jae Lee¹

Korea Atomic Energy Research Institute, Yuseong, Daejeon, 34057, Republic of Korea
¹KEPCO Nuclear Fuel, Yuseong, Daejeon, 34057, Republic of Korea

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Oxide-dispersion-strengthened (ODS) alloy has been developed to increase the mechanical strength of metallic materials; such an improvement can be realized by distributing fine oxide particles within the material matrix. In this study, the ODS layer was formed in the surface region of Zr-based alloy tubes by laser beam treatment. Two kinds of Zr-based alloys with different alloying elements and microstructures were used: KNF-M (recrystallized) and HANA-6 (partial recrystallized). To form the ODS layer, Y2O3-coated tubes were scanned by a laser beam, which induced penetration of Y2O3 particles into the substrates. The thickness of the ODS layer varied from 20 to 55 μm depending on the laser beam conditions. A heat affected zone developed below the ODS layer; its thickness was larger in the KNF-M alloy than in the HANA-6 alloy. The ring tensile strengths of the KNF-M and HANA-6 alloy samples increased more than two times and 20.50%, respectively. This procedure was effective to increase the strength while maintaining the ductility in the case of the HANA-6 alloy samples; however, an abrupt brittle facture was observed in the KNF-M alloy samples. It is considered that the initial microstructure of the materials affects the formation of ODS and the mechanical behavior.

Keywords:Zr-based alloy;oxide-dispersion-strengthening;surface treatment;tensile strength

[References]

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Reppich B, Acta Mater., 46, 61 (1998)
Proville L, Bako B, Acta Mater., 58, 5565 (2010)
Jung YI, Kim HG, Kim IH, Kim SH, Park JH, Park DJ, Yang JH, Koo YH, Mater. Des., 116, 325 (2017)
Jung YI, Kim HG, Guim HU, Lim YS, Park JH, Park DJ, Yang JH, Appl. Surf. Sci., 429, 272 (2018)
Jung YI, Park DJ, Park JH, Kim HG, Yang JH, Koo YH, Nucl. Eng. Technol., 50, 218 (2018)
Kim HG, Kim IH, Jung YI, Park DJ, Park JH, Yang JH, Koo YH, Addit. Manuf., 22, 75 (2018)

[1] Meiklejohn WH, Skoda RE, Acta Metall. Mater., 8, 773 (1960)

[2] Reppich B, Acta Mater., 46, 61 (1998)

[3] Proville L, Bako B, Acta Mater., 58, 5565 (2010)

[4] Jung YI, Kim HG, Kim IH, Kim SH, Park JH, Park DJ, Yang JH, Koo YH, Mater. Des., 116, 325 (2017)

[5] Jung YI, Kim HG, Guim HU, Lim YS, Park JH, Park DJ, Yang JH, Appl. Surf. Sci., 429, 272 (2018)

[6] Jung YI, Park DJ, Park JH, Kim HG, Yang JH, Koo YH, Nucl. Eng. Technol., 50, 218 (2018)

[7] Kim HG, Kim IH, Jung YI, Park DJ, Park JH, Yang JH, Koo YH, Addit. Manuf., 22, 75 (2018)