[1] Liu Q C, Janardhana M, Hinton B et al. Laser cladding as a potential repair technology for damaged aircraft components[J]. International Journal of Structural Integrity, 2, 314-331(2011).
[2] Leunda J, Soriano C, Sanz C et al. Laser cladding of vanadium-carbide tool steels for die repair[J]. Physics Procedia, 12, 345-352(2011).
[3] Yang J, Hu L Y. Application of laser cladding technology in coal mine machinery[J]. Coal Mine Machinery, 40, 142-143(2019).
[4] Shi X M, Yuan S Q, Yi Y H et al. Study on factors influencing the crack in laser cladding[J]. Journal of Netshape Forming Engineering, 4, 114-117(2012).
[5] Xie R S, Chen G Q, Zhao Y et al. In-situ observation and numerical simulation on the transient strain and distortion prediction during additive manufacturing[J]. Journal of Manufacturing Processes, 38, 494-501(2019).
[6] Zhang G. Fundamental research on process of planar laser cladding deformation control[D]. Urumqi: Xinjiang University, 38-42(2019).
[7] Dunbar A J, Denlinger E R, Heigel J et al. Development of experimental method for in situ distortion and temperature measurements during the laser powder bed fusion additive manufacturing process[J]. Additive Manufacturing, 12, 25-30(2016).
[8] Han H, Qi W J, Dang Y X et al. Effect of path set on laser cladding temperature field and stress and strain field of 304 stainless steel[J]. Hot Working Technology, 46, 148-152(2017).
[10] Gong X Y, You W, Gao S Y et al. Numerical simulation of temperature field in laser cladding for different scanning path[J]. Journal of North China Institute of Science and Technology, 13, 48-54(2016).
[11] Yan Z R, Liu W W, Tang Z J et al. Effect of thermal characteristics on distortion in laser cladding of AISI 316L[J]. Journal of Manufacturing Processes, 44, 309-318(2019).
[12] Lu J J. Research on the substrate deformation and stress control of thin-walled Ti6Al4V parts by laser deposition forming[D]. Jinan: Shandong University, 35-43(2016).