Research Status of Joining Technology for SiC Ceramic
- Vol. 52, Issue 8, Pages: 10-19(2022)
DOI: 10.7512/j.issn.1001-2303.2022.08.02
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徐晓卫,李宁,刘自豪,等.碳化硅陶瓷连接技术研究现状[J].电焊机,2022,52(8):10-19.
XU Xiaowei, LI Ning, LIU Zihao, et al.Research Status of Joining Technology for SiC Ceramic[J].Electric Welding Machine, 2022, 52(8): 10-19.
为预防和应对核电站事故,ATF(Accident Tolerant Fuel)材料的概念应运而生,包覆核燃料芯体的包壳管的材料选用及制造于此具有重要意义。SiC陶瓷凭借其优异的力学性能、耐腐蚀性能及抗辐照性能,成为下一代核燃料包壳管的候选材料。受限于SiC陶瓷的固有特性,SiC基包壳管难以一体成形,为确保端盖处气密性,SiC的连接技术成为国内外学者的研究重点。就SiC陶瓷基本性质、核领域应用前景和制备方法等方面进行了介绍。着重整理了SiC陶瓷的扩散焊连接和钎焊连接等常用连接技术研究现状,分析了Ti、Mo和Ni/Ti等扩散焊连接材料及Ag-Cu基、Pd基、Co基、Ni基、Ti基和Al基等钎料的优劣,论述了不同连接材料在高温、辐照、腐蚀等环境下的性能差异。就SiC陶瓷的连接技术在核包壳管的应用方面进行了评价及展望。
In order to prevent and deal with nuclear power plant accidents, the concept of ATF (Accident Tolerant Fuel) material emerged. It is of great significance to select the proper material and manufacturing method of the cladding tube which protects the nuclear fuel core. SiC ceramics has become a candidate material for the next generation of nuclear fuel cladding tubes due to its excellent mechanical properties, corrosion resistance and radiation resistance. Due to the intrinsic property of SiC ceramics, it is difficult to form SiC base cladding. To ensure the gas tightness of the end cap, the joining technology of SiC is the focus of researchers at home and abroad. The basic properties, application prospects in nuclear field and preparation method of SiC ceramics are introduced. The research status of diffusion bonding and brazing bonding of SiC ceramics is emphatically reviewed. The advantages and disadvantages of diffusion bonding materials including Ti, Mo and Ni/Ti and brazing filler materials including Ag-Cu base, Pd base, Co base, Ni base, Ti base and Al base fillers are analyzed. The property differences of joining materials under high temperature, irradiation and corrosion environment are discussed. Finally, the application of SiC ceramics joining technology in cladding is evaluated and prospected.
ATF包壳材料SiC陶瓷钎焊固相扩散焊
ATFcladding materialSiC ceramicbrazingsolid diffusion bonding
刘俊凯, 张新虎, 恽迪. 事故容错燃料包壳候选材料的研究现状及展望[J]. 材料导报, 2018,32(11): 1757-1778.
LIU Junkai, ZHANG Xinhu, YUN Di. A Complete Review and a Prospect on the Candidate Materials for Accident-tolerant Fuel Claddings[J]. Materials Review, 2018,32(11): 1757-1778.
AZEVEDO C R F. Selection of fuel cladding material for nuclear fission reactors[J]. Engineering Failure Analysis, 2011,18(8): 1943-1962.
ZINKLE S J, TERRANI K A, GEHIN J C, et al. Accident tolerant fuels for LWRs: A perspective[J]. Journal of Nuclear Materials, 2014,448(1-3): 374-379.
刘荣正, 刘马林, 邵友林, 等. 碳化硅材料在核燃料元件中的应用[J]. 材料导报, 2015,29(01): 1-5.
LIU Rongzheng, LIU Malin, SHAO Youlin, et al. Application of Silicon Carbide in Nuclear Fuel Elements[J]. Materials Review, 2015,29(01): 1-5.
SNEAD L L, NOZAWA T, KATOH Y, et al. Handbook of SiC properties for fuel performance modeling[J]. Journal of Nuclear Materials, 2007,371(1-3): 329-377.
KATOH Y, OZAWA K, SHIH C, et al. Continuous SiC fiber, CVI SiC matrix composites for nuclear applications: Properties and irradiation effects[J]. Journal of Nuclear Materials, 2014,448(1-3): 448-476.
李辰冉, 谢志鹏, 赵林. 碳化硅陶瓷材料烧结技术的研究与应用进展[J]. 陶瓷学报, 2020,41(02): 137-149.
LI Chenran, XIE Zhipeng, ZHAO Lin. Research and Application of Sintering Technologies for SiC Ceramic Materials: A review[J]. Journal of Ceramics, 2020, 41(02): 137-149.
马瑞琦, 施嘉辉, 刘东旭, 等. 以Al-B-C为烧结助剂的SiC陶瓷热压烧结工艺[J]. 材料科学与工程学报, 2021,39(06): 916-921.
MA Ruiqi, SHI Jiahui, LIU Dongxu, et al. Investigation of the Hot-pressed SiC Ceramics with Al-B-C as Sintering Aids[J]. Journal of Materials Science and Engineering, 2021,39(06): 916-921.
NESS J N, PAGE T F. Microstructural evolution in reaction-bonded silicon carbide[J]. Journal of materials science, 1986,21(4): 1377-1397.
GROSS E, DAHAN D B, KAPLAN W D. The role of carbon and SiO2 in solid-state sintering of SiC[J]. Journal of the European Ceramic Society, 2015,35(7): 2001-2005.
李少峰. 无压烧结碳化硅复合材料的制备与性能研究[J]. 佛山陶瓷, 2022,32(01): 16-19.
LI Shaofeng. The Research on Preparation Process and Properties of SiC Composites by Pressureless Sintering[J]. Foshan Ceramics, 2022,32(01): 16-19.
KATOH Y, SNEAD L L, CHENG T, et al. Radiation-tolerant joining technologies for silicon carbide ceramics and composites[J]. Journal of Nuclear Materials, 2014,448(1-3): 497-511.
GRASSO S, TATARKO P, RIZZO S, et al. Joining of β-SiC by spark plasma sintering[J]. Journal of the European Ceramic Society, 2014,34(7): 1681-1686.
AROSHAS R, ROSENTHAL I, STERN A, et al. Silicon Carbide Diffusion Bonding by Spark Plasma Sintering[J]. Materials and manufacturing processes, 2015,30(1): 122-126.
LI M, ZHOU X, YANG H, et al. The critical issues of SiC materials for future nuclear systems[J]. Scripta Materialia, 2018,143: 149-153.
BHANUMURTHY K, SCHMID-FETZER R. Interface reactions between silicon carbide and metals (Ni, Cr, Pd, Zr)[J]. Composites Part A: Applied Science and Manufacturing, 2001,32(3-4): 569-574.
KOYANAGI T, KATOH Y, KIGGANS J O, et al. Irradiation resistance of silicon carbide joint at light water reactor–relevant temperature[J]. Journal of Nuclear Materials, 2017,488: 150-159.
JUNG Y, PARK J, KIM H, et al. Effect of Ti and Si Interlayer Materials on the Joining of SiC Ceramics[J]. Nuclear Engineering and Technology, 2016,48(4): 1009-1014.
RODRIGUES G, NUNES C A, SUZUKI P A, et al. Thermal expansion of the V5Si3 and T2 phases of the V-Si-B system investigated by high-temperature X-ray diffraction[J]. Intermetallics, 2009,17(10): 792-795.
YANG H, ZHOU X, SHI W, et al. Thickness-dependent phase evolution and bonding strength of SiC ceramics joints with active Ti interlayer[J]. Journal of the European Ceramic Society, 2017,37(4): 1233-1241.
LI J, YANG Y, FENG G, et al. First-principles study of stability and properties on β-SiC/TiC(111) interface[J]. Journal of Applied Physics, 2013,114(16): 163522.
YANO T, SUEMATSU H, ISEKI T. High-resolution electron microscopy of a SiC/SiC joint brazed by a Ag-Cu-Ti alloy[J]. Journal of Materials Science, 1988,23(9): 3362-3366.
ZHOU Y, SUN Z. Electronic structure and bonding properties in layered ternary carbide Ti3SiC2[J]. Journal of physics. Condensed matter, 2000,12(28): 457-462.
JI Y, ZAN Q, WANG X, et al. High temperature oxidation resistance of Ti3SiC2 in air and low oxygen atmosphere[J]. International Journal of Applied Ceramic Technology, 2017,14(5): 851-859.
RADOVIC M, BARSOUM M W. MAX PHASES: BRIDGING THE GAP BETWEEN METALS AND CERAMICS[Z]. Columbus: American Ceramic Society, 2013: 92, 20-27.
DONG H, HAN W B, LI S J. Joining of SiC Ceramic with Ternary Carbide Ti3SiC2[J]. Materials Science Forum, 2005,475-479: 1255-1258.
COCKERAM B V. Flexural Strength and Shear Strength of Silicon Carbide to Silicon Carbide Joints Fabricated by a Molybdenum Diffusion Bonding Technique[J]. Journal of the American Ceramic Society, 2005,88(7): 1892-1899.
DU Y, WANG B, ZHONG Y, et al. Assessment of the Potential Diffusion Barriers between Tungsten and Silicon Carbide for Nuclear Fusion Application[J]. Coatings, 2022,12(5): 639.
KISHIMOTO H, SHIBAYAMA T, SHIMODA K, et al. Microstructural and mechanical characterization of W/SiC bonding for structural material in fusion[J]. Journal of Nuclear Materials,2011,417(1-3):387-390.
张志豪. Ti/Ni为中间层的SiC陶瓷扩散连接接头高温力学性能研究[D]. 黑龙江:哈尔滨工业大学, 2016.
ZHANG Zhihao. High-Temperature Mechanical Properties of Diffusion Bonding Joints Between SiC Ceramics With Ti/Ni Interlayers[D]. Heilongjiang:Harbin Institute of Technology, 2016.
ASTHANA R, SINGH M. Active metal brazing of advanced ceramic composites to metallic systems[M]. Advances in Brazing-Science, Technology and Applications. Woodhead Publishing, 2013:323-360.
BOADI J K, YANG T, ISEKI T. Brazing of pressureless-sintered SiC using Ag-Cu-Ti alloy[J]. Journal of Materials Science, 1987,22(7): 2431-2434.
XIONG J H, HUANG J H, ZHANG H, et al. Brazing of carbon fiber reinforced SiC composite and TC4 using Ag–Cu–Ti active brazing alloy[J]. Materials Science and Engineering: A, 2010,527(4-5): 1096-1101.
LIU Y, HUANG Z R, LIU X J. Joining of sintered silicon carbide using ternary Ag-Cu-Ti active brazing alloy[J]. Ceramics International, 2009,35(8): 3479-3484.
刘岩, 黄政仁, 刘学建, 等. 采用Ag-Cu-In-Ti焊料连接碳化硅陶瓷[J]. 无机材料学报, 2009,24(04): 817-820.
LIU Yan, HUANG Zhengren, LIU Xuejian, et al. Brazing of SiC Ceramics Using Ag-Cu-In-Ti Filler Metal[J]. Journal of Inorganic Materials, 2009,24(04): 817-820.
LOCATELLI M R, DALGLEISH B J, NAKASHIMA K, et al. New approaches to joining ceramics for high-temperature applications[J]. Ceramics International, 1997,23(4): 313-322.
XIONG H, CHEN B, PAN Y, et al. Interfacial reactions and joining characteristics of a Cu–Pd–V system filler alloy with Cf/SiC composite[J]. Ceramics International, 2014,40(6): 7857-7863.
WEI J, MADENI J C, LIU S, et al. Performance comparison of Al-Si-Ti and Co-Si-V-Ti braze alloys in the vacuum brazing of reaction-bonded silicon carbide[J]. Welding in the World, 2019,63(6): 1851-1860.
李文文, 熊华平, 吴欣, 等. Co-Nb-Pd-Ni-V钎料真空钎焊Cf/SiC复合材料的接头组织与性能[J]. 焊接学报, 2019:129-132.
LI Wenwen,XIONG Huaping,WU Xin,et al. Microstructure and strength of the Cf/SiC composite joint brazed with Co-Nb-Pd-Ni-V filler alloy[J]. Transactions of The China Welding Institution,2019:129-132.
祝鑫, 石浩江, 赵毅, 等. SiC陶瓷真空钎焊接头的组织及性能分析[J]. 真空科学与技术学报, 2019,39(07): 566-570.
ZHU Xin, SHI Haojiang, ZHAO Yi, et al. Microstructures and Mechanical Properties of Vacuum Brazed SiC Ceramics Joint[J]. Chinese Journal of Vacuum Science and Technology, 2019,39(07): 566-570.
WANG Z, LIU Y, ZHANG H, et al. Joining of SiC ceramics using the Ni-Mo filler alloy for heat exchanger applications[J]. Journal of the European Ceramic Society, 2021,41(15): 7533-7542.
DUAN S, SHI X, ZHANG M, et al. Determination of the thermodynamic properties of Ni-Ti, Ni-Al, and Ti-Al, and nickel-rich Ni-Al-Ti melts based on the atom and molecule coexistence theory[J]. Journal of Molecular Liquids, 2019,294: 111462.
NAKA M, TANIGUCHI H, OKAMOTO I. Heat-Resistant Brazing of Ceramics (Report I): Brazing of SiC Using Ni-Ti Filler Metals[J]. Transactions of JWRI, 1990,19(1): 25-31.
SHI H, PENG H, YAN J, et al. Investigations of the effect of Si addition on graphite elimination and the oxidation behavior of SiC joint using Inconel 625 powder filler[J]. Journal of the European Ceramic Society, 2022,42(4): 1258-1271.
TIAN W B, SUN Z M, ZHANG P, et al. Brazing of silicon carbide ceramics with Ni-Si-Ti powder mixtures[J]. Journal of the Australian Ceramic Society, 2017,53(2): 511-516.
RICCARDI B, NANNETTI C A, WOLTERSDORF J, et al. Brazing of SiC and SiCf/SiC composites performed with 84Si-16Ti eutectic alloy: microstructure and strength[J]. Journal of materials science, 2002,37(23): 5029-5039.
白冬, 颜家振, 李宁, 等. 真空无压钎焊原位生成Ti3SiC2相连接SiC及其力学性能研究[J]. 热加工工艺, 2022: 1-5.
BAI Dong, YAN Jiazhen, LI Ning, et al. Study on Joining SiC with Ti3SiC2 Phase In-situ Formed by Vacuum Pressureless Brazing and Its Mechanical Properties[J]. Hot Working Technology, 2022: 1-5.
唐清秋. 高硅铝合金钎焊碳化硅陶瓷的接头微观组织和性能研究[D]. 安徽:合肥工业大学, 2017.
TANG Qingqiu. Microstructure and mechanical properties of silicon carbide joints brazed with high-silicon aluminum alloys [D]. Anhui:Hefei University of Technology, 2017.
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