电子束焊接条件下Ti-TiB合金焊缝材料结晶特征

Petro Loboda, Volodymyr Zvorykin, Constantine Zvorykin, Eduard Vrzhyzhevskyi, Tatjana Taranova, Valery Kostin, Leonid Zvorykin
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 The purpose of this study is the determination of formation mechanism of boride microfibers originated in the welded seam material. Two most probable variants of the formation mechanism are analyzed, which involve eutectic decomposition during crystallization from a liquid melt or eutectoid decomposition from a metastable crystallized alloy. The third version is a mixed variant of the two above-mentioned mechanisms.
 In the article the results of metallographic analysis of features of boride phase distribution and an analysis of elemental composition of boride fibers based on local Auger electron spectroscopy are presented. The object of study was a Ti-TiB alloy joint obtained by electron-beam welding. The analysis factors were the features of size, orientation, and nature of the distribution of boride phase microfibers in different areas of the welded seam. The characteristic elemental composition of boride microfibers, which characterizes the correspondence to equilibrium phases, is also studied.
 The degree of deviation of the ratio of boron and titanium in such a phase from the thermodynamically equilibrium in different layers of the material of the welded seam, formed by an electron beam in vacuum, is determined. The dependence of boride phase distribution under various conditions of heat exchange in the welded seam material on the side surfaces and in the central regions is established. It is shown that some of boride microfibers formed in the material of the welded seam are characterized by a deviation from the thermodynamically stable composition ТіВn (n = 1) to ТіВn (n = 0.85). The dendritic nature of boride microfibers distribution and the presence of meta-stable phase formations on Ti and B basis provide the grounds for proposing the predominant mechanism for the formation of structure of the welded seam material in the Ti-TiB alloy during crystallization.
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引用次数: 2

摘要

天然金属复合材料是一类很有前途的需要焊接的现代结构材料。这类材料可以通过熔合焊接,以Ti-TiB合金为例。这种材料的增强操作性能是由微观结构决定的,其特征是在金属基体中存在硼化物、碳化物或硅化物的微纤维。为了保持焊接接头中材料的力学性能,必须保证焊缝材料中形成增强微纤维。确定源自焊缝材料的硼化物微纤维的形成机理,将成为优化熔焊方式,特别是电子束焊接方式的基础。 本研究的目的是确定源自焊缝材料的硼化物微纤维的形成机制。分析了两种最可能的形成机制,一种是液体熔体结晶过程中的共晶分解,另一种是亚稳结晶合金的共晶分解。第三个版本是上述两种机制的混合变体。本文介绍了硼化物相分布特征的金相分析结果和基于局部俄歇电子能谱的硼化物纤维元素组成分析结果。以电子束焊接制备的Ti-TiB合金接头为研究对象。分析因素为焊缝不同区域硼化物相微纤维的尺寸、取向和分布性质特征。研究了与平衡相对应的硼化物微纤维的特征元素组成。 测定了在真空中电子束形成的焊缝材料的不同层中,该相中硼钛的比例与热力学平衡的偏差程度。建立了不同换热条件下焊缝材料中硼化物相分布在侧面和中部的依赖关系。结果表明,在焊缝材料中形成的一些硼化物微纤维的特征是从热力学稳定成分ТіВn (n = 1)到ТіВn (n = 0.85)的偏差。晶化过程中,硼化物微纤维的枝晶性分布以及在Ti基和B基上的亚稳定相的存在,为提出Ti- tib合金中焊缝材料在晶化过程中组织形成的主要机制提供了依据。 对源自焊缝材料的硼化物微纤维形成机制的假设变体分析表明,枝晶型结构的形成是新相晶体在液相中生长的特征。这种生长的特点是形成平衡相。焊缝中存在大量非平衡硼化物相,表明非平衡硼在钛基体中残留,硼化物纤维在结晶焊缝中继续生长。源于焊缝材料的硼化物微纤维形成的确定机制是在结晶过程中由液体熔体产生的共晶分解与TiB微纤维的形成以及由于亚稳结晶Ti-TiB合金的共晶分解而进一步生长。所获得的结果使理解焊接天然复合金属材料中焊缝的形成机制成为可能,从而可以为优化此类材料的焊接技术提出建议。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Features of the welded seam material crystalliza-tion in Ti-TiB alloy under electron-beam welding conditions
Natural metal composite materials represent a promising class of modern structural materials that need to be welded. Such materials can be welded by fusion, as has been established with the Ti-TiB alloy as an example. The enhanced operational properties of such materials are determined by the microstructure, which is characterized by the presence of microfibers of borides, carbides, or silicides in the metal matrix. To preserve the mechanical properties of materials in a welded joint, it is necessary to ensure the formation of reinforcing microfibers in the welded seam material. Determination of formation mechanism of boride microfibers, originated in the welded seam material, will become the basis for optimizing of fusion welding modes, in particular, electron beam welding mode. The purpose of this study is the determination of formation mechanism of boride microfibers originated in the welded seam material. Two most probable variants of the formation mechanism are analyzed, which involve eutectic decomposition during crystallization from a liquid melt or eutectoid decomposition from a metastable crystallized alloy. The third version is a mixed variant of the two above-mentioned mechanisms. In the article the results of metallographic analysis of features of boride phase distribution and an analysis of elemental composition of boride fibers based on local Auger electron spectroscopy are presented. The object of study was a Ti-TiB alloy joint obtained by electron-beam welding. The analysis factors were the features of size, orientation, and nature of the distribution of boride phase microfibers in different areas of the welded seam. The characteristic elemental composition of boride microfibers, which characterizes the correspondence to equilibrium phases, is also studied. The degree of deviation of the ratio of boron and titanium in such a phase from the thermodynamically equilibrium in different layers of the material of the welded seam, formed by an electron beam in vacuum, is determined. The dependence of boride phase distribution under various conditions of heat exchange in the welded seam material on the side surfaces and in the central regions is established. It is shown that some of boride microfibers formed in the material of the welded seam are characterized by a deviation from the thermodynamically stable composition ТіВn (n = 1) to ТіВn (n = 0.85). The dendritic nature of boride microfibers distribution and the presence of meta-stable phase formations on Ti and B basis provide the grounds for proposing the predominant mechanism for the formation of structure of the welded seam material in the Ti-TiB alloy during crystallization. An analysis of hypothetical variants of the formation mechanism of boride microfibers originated in the welded seam material showed that the formation of a dendritic type of structure is characteristic for the growth of crystals of a new phase in the liquid phase. Such growth is characterized by the formation of equilibrium phases. The presence of a significant amount of non-equilibrium boride phase in the welded seam indicates the residue of non-equilibrium boron in the titanium matrix and continuation of growing of boride fibers in the crystallized welded seam. A determined mechanism for formation of boride microfibers originated in the welded seam material is eutectic decomposition during crystallization from a liquid melt with the formation of TiB microfibers and further growth of such crystals due to eutectoid decomposition from a metastable crystallized Ti-TiB alloy. The results obtained make it possible to understand the mechanism of formation of a welded seam in welded natural-composite metal materials, which permits to develop the recommendations for optimizing the welding technology for such materials.
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