Research status and development trend of electron beam welding for advanced materials and dissimilar materials

[1] Feng Jicai, Research progress on dissimilar materials joining, Acta Aeronautica et Astronautica Sinica, 43, 2, pp. 6-42, (2022)

[2] Feng Jicai, Wang Ting, Zhang Binggang, Et al., Research status analysis of electron beam welding for joining of dissimilar materials, Transactiongs of the China Welding Institution, 30, 10, pp. 108-112, (2009)

[3] Lu Zhifang, Overview of ratent technology of electron beam welding in China, Modern Manufacturing Technology and Equipment, 5, pp. 216-217, (2019)

[4] Cheng M, Yu B, Guo R, Et al., Electron beam welding of a novel near α high temperature titanium alloy powder compact: effect of post-welding heat treatment on tensile properties[J], Journal of Materials Research and Technology, 10, pp. 153-163, (2021)

[5] Fu P, Mao Z, Lin J, Et al., Temperature field modeling and microstructure analysis of EBW with multi-beam for near α titanium alloy[J], Vacuum, 102, pp. 54-62, (2014)

[6] Liu H, Song J, Cao X, Et al., Enhancement of fatigue resistance by direct aging treatment in electron beam welded Ti-5Al-2Sn-2Zr4Mo-4Cr alloy joint, Materials Science and Engineering:A, 829, (2022)

[7] Liu F, Chen Y, He C, Et al., Very long life fatigue failure mechanism of electron beam welded joint for titanium alloy at elevated temperature, International Journal of Fatigue, 152, (2021)

[8] Zhang S, Ma Y, Huang S, Et al., Temperature-gradient induced microstructure evolution in heat-affected zone of electron beam welded Ti-6Al-4V titanium alloy, Journal of Materials Science & Technology, 35, 8, pp. 1681-1690, (2019)

[9] Zeng C, Zhang Y, Hu J, Et al., The role of microstructure on corrosion fatigue behavior of thick-plate Ti-6Al-4V joint via vacuum electron beam welding, Vacuum, 182, (2020)

[10] Lu Y, Turner R, Brooks J, Et al., A study of process-induced grain structures during steady state and non-steady state electron-beam welding of a titanium alloy, Journal of Materials Science & Technology, 113, pp. 117-127, (2022)

[1] Feng Jicai, Research progress on dissimilar materials joining, Acta Aeronautica et Astronautica Sinica, 43, 2, pp. 6-42, (2022)

[2] Feng Jicai, Wang Ting, Zhang Binggang, Et al., Research status analysis of electron beam welding for joining of dissimilar materials, Transactiongs of the China Welding Institution, 30, 10, pp. 108-112, (2009)

[3] Lu Zhifang, Overview of ratent technology of electron beam welding in China, Modern Manufacturing Technology and Equipment, 5, pp. 216-217, (2019)

[4] Cheng M, Yu B, Guo R, Et al., Electron beam welding of a novel near α high temperature titanium alloy powder compact: effect of post-welding heat treatment on tensile properties[J], Journal of Materials Research and Technology, 10, pp. 153-163, (2021)

[5] Fu P, Mao Z, Lin J, Et al., Temperature field modeling and microstructure analysis of EBW with multi-beam for near α titanium alloy[J], Vacuum, 102, pp. 54-62, (2014)

[6] Liu H, Song J, Cao X, Et al., Enhancement of fatigue resistance by direct aging treatment in electron beam welded Ti-5Al-2Sn-2Zr4Mo-4Cr alloy joint, Materials Science and Engineering:A, 829, (2022)

[7] Liu F, Chen Y, He C, Et al., Very long life fatigue failure mechanism of electron beam welded joint for titanium alloy at elevated temperature, International Journal of Fatigue, 152, (2021)

[8] Zhang S, Ma Y, Huang S, Et al., Temperature-gradient induced microstructure evolution in heat-affected zone of electron beam welded Ti-6Al-4V titanium alloy, Journal of Materials Science & Technology, 35, 8, pp. 1681-1690, (2019)

[9] Zeng C, Zhang Y, Hu J, Et al., The role of microstructure on corrosion fatigue behavior of thick-plate Ti-6Al-4V joint via vacuum electron beam welding, Vacuum, 182, (2020)

[10] Lu Y, Turner R, Brooks J, Et al., A study of process-induced grain structures during steady state and non-steady state electron-beam welding of a titanium alloy, Journal of Materials Science & Technology, 113, pp. 117-127, (2022)