乌克兰巴顿焊接研究所技术发展综述

概述了巴顿焊接研究所的研究特色，介绍了其在焊接方法、焊接设备、焊接材料、焊接应力应变计算与检测及太空焊接实验等方面的焊接技术成果与应用情况。     

电阻点焊质量评判初探

在大量实验数据基础上，利用回归分析法构造了基于热量和电极压力的电阻点焊质量评判数学模型。在点焊过程参数变化情况下，用该数学模型，能有效地对焊点质量进行初级评判。     

Influence of welding parameters on microstructure and mechanical properties of electron beam welded Ti60 to GH3128 joint with a Cu interlayer

Effects of welding parameters on the microstructure and mechanical properties of Ti/Cu/Ni joint welded by electron beam were investigated. High welding heat input increased the melting quantity of Ti60 titanium alloy and promoted the formation of Ti–Cu intermetallic compounds (IMC) such as Ti₂Cu and Ti₃Cu₄, increasing the brittleness of the joints. Low welding heat input was not conducive to the complete melting of the copper interlayer, and the unmelted copper reduced the performance of the joints. Under the optimal welding parameters, Ti–Ni IMCs in the weld would be replaced by (Cu, Ni) solid solutions ((Cu, Ni)_ss). However, Ti–Cu IMC layers cannot be eliminated entirely by changing the welding parameters. The maximum tensile strength of the joints was 201 MPa. The fracture of the joints occurred at the Ti–Cu IMC layer, which was a typical brittle fracture.     

俄国Al—Mg—Li系1420合金的焊接裂纹和气孔

论述了Ａｌ－Ｍｇ－Ｌｉ系１４２０合金焊接时的主要缺陷（裂纹和气孔）的形成机理，针对这两种缺陷提出了减少和消除裂纹和气孔的有效方法。     

2219 铝合金VPTIG 焊接接头拉伸性能分析

2219 铝合金气孔敏感性较强,变极性TIG 焊接工艺可以有效减少和抑制气孔产生,是适合于
2219 铝合金的焊接工艺。本文介绍了2219T62 铝合金VPTIG 焊接接头的拉伸性能,进行了拉伸断口形貌分析
和微观组织分析。结果表明:2219T62 铝合金VPTIG 焊接接头强度系数可以达到65% 以上,焊接接头为混合
断裂方式,VPTIG 焊缝盖面层气孔相比打底层较多。     

2195铝锂合金弧焊技术研究现状

铝锂合金具有密度低、比模量高、比强度高、抗疲劳及腐蚀性能良好等特点,被认为是航空航天领域最有应用前途的结构材料之一.本文回顾了铝锂合金的发展历程,介绍了新一代2195铝锂合金的成分、组织结构及可焊接性,分析其焊接过程出现的主要问题,概述了国内外机构通过优化2195铝锂合金配用焊丝及弧焊工艺,改善接头组织结构及力学性能的...     

2195铝锂合金钨极氩弧焊接工艺研究

针对2195铝锂合金在焊接时裂纹敏感性高、气孔敏感性高、易氧化等问题，开展氩弧焊接工艺研究，对焊接头的抗裂性、力学性能及显微组织进行了分析。研究表明，提高焊缝金属中的Cu含量，可以有效降低2195铝锂合金熔焊接头的裂纹敏感性，裂纹率K₁=0%,K₂=0%。2195铝锂合金单面双层焊接接头力学性能最佳，抗拉强度超过376 MPa，延伸率达到5.5%。提高焊接试板的清理深度可以解决焊接气孔敏感性高的问题，增加氩气拖后保护及背保护措施可以有效防止焊接氧化问题。熔焊工艺研究可为2195铝锂合金的工程应用提供技术支撑。     

Review on residual stress and its effects on manufacturing of aluminium alloy structural panels with typical multi-processes

In the aerospace industry, integrated aluminium alloy plates and stiffened panels with high accuracy and performance attract significant interest. To manufacture these panels as integrity with high accuracy, multiple processes need to be utilised, such as machining, welding and forming. During the whole manufacturing chain, residual stresses can be generated and redistributed in the components among different processes. The residual stress would significantly affect the shapes and properties of the final products. Currently, these great effects are not well considered in the design and manufacturing processes. This paper aims to draw a general understanding of the residual stress generated in the pre-manufacturing processes and its effects on subsequent manufacturing processes. The mechanisms and distributions of residual stresses generated in typical pre-manufacturing processes of structural panels, including machining, welding and additive manufacturing (AM), are firstly summarised. The detailed effects of generated residual stresses on distortion and application properties in subsequent manufacturing processes are then concluded. In addition, current methods developed for the investigation of residual stress effect in multi-processes manufacturing are critically reviewed, including experimental, analytical, finite element (FE) and machine learning methods. Furthermore, the future development trend of methods for residual stress consideration and control in the design of manufacturing processes is summarised, providing comprehensive guidance to achieve the high accurate manufacturing of aluminium alloy structural components.