Multi-objective optimization of laser cladding parameters based on PCA and RSM-DE algorithm

[1] Li Congbo, Feng Ya, Du Yanbin, Et al., Decision-making method for used components remanufacturing process plan based on modified FNN, Computer Integrated Manufacturing Systems, 22, 3, pp. 728-737, (2016)

[2] Xu Guojian, Li Chunguang, Guo Yunqiang, Et al., Organization of clad layer using mixed powder of Stellite-6 and VC, Transactions of the China Welding Inesitution, 38, 6, pp. 73-78, (2017)

[3] Lee C, Park H, Yoo J, Et al., Residual stress and crack initiation in laser clad composite layer with Co-based alloy and WC + NiCr[J], Applied Surface Science, 345, pp. 286-294, (2016)

[4] Yan Ran, Li Hao, Liu Junchao, Et al., Process parameters optimization of polystyrene powder selective laser sintering based on response surface methodology, Chinese Journal of Lasers, 46, 3, pp. 5-13, (2019)

[5] Zhang Chengyan, Wang Lixin, Zu Xiaoli, Et al., Multi-objective optimization of experimental and analytical residual stresses in pre-stressed cutting of thin-walled ring using glowworm swarm optimization algorithm[J], The International Journal of Advanced Manufacturing Technology, 107, pp. 376-382, (2020)

[6] Janicki D., Laser cladding of Inconel 625-based composite coatings reinforced by porous chromium carbide particles, Optics & Laser Technology, 94, pp. 6-14, (2017)

[7] Lu Yaozhong, Lei Weining, Ren Weibin, Et al., Crack analysis and control of laser cladding Inconel 718 alloy, Surface Technology, 49, 9, pp. 233-243, (2020)

[8] Chen W J, Chen H, Li C C, Et al., Microstructure and fatigue crack growth of EA4T steel in laser cladding remanufacturing[J], Engineering Failure Analysis, 79, pp. 120-129, (2017)

[9] Li Xiang, Lai Youbin, Yang Bo, Et al., Process optimization and properties of Fe-Cr-C alloy coating prepared by plasma cladding, Surface Technology, 49, 6, pp. 177-184, (2020)

[10] Shu Linsen, Lin Ran, Optimization of laser cladding process parameters of iron-based alloy powder based on uniform design, Transactions of Materials and Heat Treatment, 42, 4, pp. 167-174, (2021)

[1] Li Congbo, Feng Ya, Du Yanbin, Et al., Decision-making method for used components remanufacturing process plan based on modified FNN, Computer Integrated Manufacturing Systems, 22, 3, pp. 728-737, (2016)

[2] Xu Guojian, Li Chunguang, Guo Yunqiang, Et al., Organization of clad layer using mixed powder of Stellite-6 and VC, Transactions of the China Welding Inesitution, 38, 6, pp. 73-78, (2017)

[3] Lee C, Park H, Yoo J, Et al., Residual stress and crack initiation in laser clad composite layer with Co-based alloy and WC + NiCr[J], Applied Surface Science, 345, pp. 286-294, (2016)

[4] Yan Ran, Li Hao, Liu Junchao, Et al., Process parameters optimization of polystyrene powder selective laser sintering based on response surface methodology, Chinese Journal of Lasers, 46, 3, pp. 5-13, (2019)

[5] Zhang Chengyan, Wang Lixin, Zu Xiaoli, Et al., Multi-objective optimization of experimental and analytical residual stresses in pre-stressed cutting of thin-walled ring using glowworm swarm optimization algorithm[J], The International Journal of Advanced Manufacturing Technology, 107, pp. 376-382, (2020)

[6] Janicki D., Laser cladding of Inconel 625-based composite coatings reinforced by porous chromium carbide particles, Optics & Laser Technology, 94, pp. 6-14, (2017)

[7] Lu Yaozhong, Lei Weining, Ren Weibin, Et al., Crack analysis and control of laser cladding Inconel 718 alloy, Surface Technology, 49, 9, pp. 233-243, (2020)

[8] Chen W J, Chen H, Li C C, Et al., Microstructure and fatigue crack growth of EA4T steel in laser cladding remanufacturing[J], Engineering Failure Analysis, 79, pp. 120-129, (2017)

[9] Li Xiang, Lai Youbin, Yang Bo, Et al., Process optimization and properties of Fe-Cr-C alloy coating prepared by plasma cladding, Surface Technology, 49, 6, pp. 177-184, (2020)

[10] Shu Linsen, Lin Ran, Optimization of laser cladding process parameters of iron-based alloy powder based on uniform design, Transactions of Materials and Heat Treatment, 42, 4, pp. 167-174, (2021)