钨/低活化钢钎焊用铁基非晶钎料与接头微结构

doi:10.16568/j.0254-6086.202302002

核聚变与等离子体物理 ›› 2023, Vol. 43 ›› Issue (2): 132-139.DOI: 10.16568/j.0254-6086.202302002

钨/低活化钢钎焊用铁基非晶钎料与接头微结构

魏明玉1 ，王建豹2 ，Jitendar Kumar1 ，羌建兵1 ，王英敏1 ，刘天鸷1 ，封范2 ，练友运2 ，刘翔2

(1. 大连理工大学三束材料改性教育部重点实验室，大连 116024；2. 核工业西南物理研究院，成都 610041)

收稿日期:2021-04-30 修回日期:2022-10-28 出版日期:2023-06-15 发布日期:2023-06-09
作者简介:魏明玉(1994-)，男，内蒙古呼伦贝尔人，博士研究生，从事先进钨材料研究。
基金资助:
国家磁约束聚变能发展研究专项(2019YFE03120004)；国家自然科学基金(51671045)

Fe-based amorphous filler alloys for brazing tungsten and low-activation steels and the joint microstructures

WEI Ming-yu1 , WANG Jian-bao2 , Jitendar Kumar1 , QIANG Jian-bing1 , WANG Ying-ming1 , LIU Tian-zhi1 , FENG Fan2 , LIAN You-yun2 , LIU Xiang2

(1. Key Laboratory of Materials Modification by Laser, Ion, and Electron Beams (Ministry of Education), Dalian University of Technology, Dalian 116024; 2. Southwestern Institute of physics, Chengdu 610041)

Received:2021-04-30 Revised:2022-10-28 Online:2023-06-15 Published:2023-06-09

摘要/Abstract

摘要： 为了连接 W 和 CLF-1 RAFM 钢，设计出由低活化元素组成的 Fe-B-Si、Fe-B-Si-Sn、Fe-B-Si-Cr-(Sn)、 Fe-B-Si-P-(Cr，Sn)、Fe-B-Si-Mn-(Ga，Sn)和 Fe-B-Si-(Cr，Mn，Ga，Ta，Sn)系列 Fe 基非晶钎料，结合熔体快淬技术制备出非晶合金箔带，并对 W/CLF-1 RAFM 钢接头微结构进行了对比研究。采用 X-射线衍射仪对箔带样品与焊缝进行了相鉴定；通过差热分析测量了非晶箔带的熔化温度和液相线温度；利用光学金相和电子探针分析了焊缝组织形貌和元素分布。结果表明，利用 Fe-B-Si、Fe-B-Si-Cr 和 Fe-B-Si-Mn-Sn 非晶钎料可获得结构完整的 W/CLF-1 钢接头；前两种钎料得到的焊缝组织基体相为α-Fe 固溶体，而含 Mn 钎料形成的焊缝基体为马氏体组织；在高温钎焊过程中，这些 Fe 基非晶钎料中的高 B 含量促使 FeWB、FeW₂B₂和 Fe₃B 型金属间化合物在焊缝中形成，并有效地阻止了 W 元素向低活化钢基体长程扩散。所设计的低活化 Fe 基非晶钎料可用于 W 和低活化钢的连接和接头性能研究。

关键词: 低活化 Fe 基非晶钎料；钎焊；W/钢连接；偏滤器；第一壁

Abstract: For the joining of W and CLF-1 RAFM steel, a series of Fe-based amorphous filler alloys consisting of low-activation constituent elements, namely, Fe-B-Si, Fe-B-Si-Sn, Fe-B-Si-Cr-(Sn), Fe-B-Si-P-(Cr, Sn), Fe-B-Si-Mn-(Ga, Sn) and Fe-B-Si-(Cr, Mn, Ga, Ta, Sn), have been designed and made into amorphous alloys in foil form by means of rapid melt quenching. The microstructures of the W/CLF-1 RAFM steel joints were comparatively studied. X-ray diffraction was performed to identify the phases formed in the foil alloys and in the main bonding seams. The melting temperature and the liquid-phase line temperature of the amorphous foil alloys were examined by differential thermal analysis. The morphology and element mapping for the bonding seams were carried out using optical metallography and electron probe microanalysis respectively. The results show that with the Fe-B-Si, Fe-B-Si-Cr and Fe-B-Si-Mn-Sn amorphous filler alloys, W/CLF-1 joints with perfect structure integrity were fabricated. In the bonding seams, α-Fe solid solution phase is formed as the substrate phase with the first two sorts of filler alloys, and a martensite substrate phase is obtained in the latter case. The high B-content in these Fe-based amorphous alloys impels the FeWB, FeW₂B₂ and Fe3B types of intermetallic phases to alloying formation in the bonding seams, which effectively blocks the fast diffusion of W to the substrate of low activation steel during high temperature brazing. These new low-activation filler alloys are promising materials for jointing W and RAFMs and for the property assessment of joints.

Key words: Low activation Fe-based amorphous filler alloy, Brazing, W/steel joint, Divertor, First wall

中图分类号:

TL62+ 7

魏明玉, 王建豹, Jitendar Kumar, 羌建兵, 王英敏, 刘天鸷, 封范, 练友运, 刘翔 . 钨/低活化钢钎焊用铁基非晶钎料与接头微结构 [J]. 核聚变与等离子体物理, 2023, 43(2): 132-139.

WEI Ming-yu , WANG Jian-bao , Jitendar Kumar , QIANG Jian-bing , WANG Ying-ming , LIU Tian-zhi , FENG Fan , LIAN You-yun , LIU Xiang. Fe-based amorphous filler alloys for brazing tungsten and low-activation steels and the joint microstructures [J]. Nuclear Fusion and Plasma Physics, 2023, 43(2): 132-139.

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钨/低活化钢钎焊用铁基非晶钎料与接头微结构

Fe-based amorphous filler alloys for brazing tungsten and low-activation steels and the joint microstructures

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