Ti-2 Al-2.5 Zr合金焊丝的低倍组织中普遍存在细小坑痕形貌。为判定焊丝坑痕的缺陷性质,通过对显微组织和能谱成分的综合分析,初步判断钛合金焊丝低倍组织中出现的细小坑痕为金相腐蚀造成的腐蚀坑,再通过观察不同腐蚀时间的显微组织发现坑痕直径随着金相腐蚀时间增加而不断变大,从而验证了低倍坑痕为金相检验过程中的点腐蚀所致。 Ti-2 Al-2.5 Zr合金铸锭制备过程中不可避免地存在微区成分的差异,加上热加工过程中动态再结晶对成分的再分配效应,引发了材料局部微区成分及组织不均匀,这是金相腐蚀后呈现坑痕形貌的原因。由此可见,低倍组织中的腐蚀坑痕不属于冶金缺陷,不会影响钛合金焊丝的整体冶金质量和性能水平。
It was found that some imperceptible spots usually appear in macroscopic examination of Ti -2Al-2.5Zr alloy welding wire .In order to determine the nature of the defects of the welding wire , microstructure observation and energy spectroscopic analysis were carried out , and it was preliminary judged that fine spots in the macrostructure of titanium alloy welding wire were etch pit .After corrosion in metallurgical corrosion solution , it was found that spot diameter became larger with increase of etching period , which confirmed that spots were pitting .This redistribution of constitute is inevitable during melting of Ti-2 Al-2.5 Zr alloy ingot , combine with redistribution effect of dynamic recrystallization on the composition of the components during hot working , the appearances of spots in macrostructure are normal phenomena and not harmful to integral alloy quality and solder wire performance .
参考文献
| [1] | HE Xiao,WU Jihong,SHEN Liru.Characterization of micro-arc ceramic coatings on Ti-2Al-2.5Zr alloy substrates[J].稀有金属(英文版),2007(05):414-419. |
| [2] | 魏寿庸;祝瀑;刘峰 等.Ti-2Al-2.5Zr 钛合金简介[J].钛工业进展,1998,15(3):6-8. |
| [3] | 吴继红,祖小涛.新型钛合金Ti-2Al-2.5Zr研究现状[J].材料导报,2004(06):15-18. |
| [4] | 于振涛;周廉;邓炬 .Ti-2Al-2.5Zr合金的循环变形行为与组织观察[J].金属学报,1999,35(增刊1):469-474. |
| [5] | 张利军,周中波,常辉,薛祥义,白钰,王幸运,刘娣.高钼含量β型钛合金的偏析行为及预防措施[J].中国有色金属学报,2013(08):2206-2212. |
| [6] | 于振涛,周廉,邓炬,顾海澄.Ti-2Al-2.5Zr合金再结晶特性及动力学机制[J].稀有金属材料与工程,1999(06):340-344. |
| [7] | 林海峰;曹继敏;杨宏进 等.TiNi合金铸锭VAR熔炼化学成分均匀性控制技术研究[J].稀有金属,2010,34(增刊1):17-20. |
| [8] | Chapelle P;Jaerdy A;Bellot J P .Effect of electro-magnet-ic stirring on melt pool free surface dynamics during vacuum arc remelting[J].Journal of Materials Science,2008,43:5734-5746. |
| [9] | Zagrebelnyy D;Krane M J M .Segregation development in multiple melt vacuum arc remelting[J].Metallurgical and Materials Transactions B:Process Metallurgy and Materials Processing Science,2009,40(3):281-288. |
| [10] | 李雄;庞克昌;郭华 等.变形钛及钛合金熔炼技术[J].中国有色金属学报,2010,10(增刊1):906-911. |
| [11] | 刘道新.材料的腐蚀与防护[M].西安:西北工业大学出版社,2006:40-42. |
| [12] | 毛为民;赵新兵.金属的再结晶与晶粒长大[M].北京:冶金工业出版,1994:168-183. |
| [13] | 刘丽娟,吕明,武文革.钛合金Ti-6Al-4V热变形中的动态再结晶研究[J].热加工工艺,2014(24):1-6. |
| [14] | Stefansson N;Semiatin S L .Mechanisms of Globularization of Ti-6Al-4V during Static Heat Treatment[J].Metallurgical and Materials Transactions,2003,34A:691-698. |
| [15] | Seshacharyulu T;Medeiros S C;Frazier WG et al.Hot deformation mechanisms in ELI grade Ti-6Al-4V[J].Scrip-ta Mater,1999,41(3):283-288. |
| [16] | Seshacharyulu T;Medeiros S C;Frazier W G et al.Hot deformation and microstructural damage mechanisms in extra-low interstitial (ELI) grade Ti-6Al-4V[J].Material Science and Engineering,2000,A279:289-299. |
| [17] | Nesterenko V F;Meyers M A;LaSalvia J C et al.Shear localization and recrystallization in high-strain,high-strain-rate deformation of titalum[J].Materials Science and Engineering A,1997,229(1/2):23-30. |
| [18] | Li H W;Wu C;Yang H .Crystal plasticity modeling of the dynamic recrystallization of two-phase titanium alloys during isothermal processing[J].International Journal of Plasticity,2013,51(12):271-291. |
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