[1] Xu M S, Zhou C H, Zhang Z et al. Temperature distribution of powder-gas-optical coupling temperature field in laser cladding processes[J]. China Mechanical Engineering, 33, 70-77(2022).

[2] Xie Y G, Wang C L, Zhang K X et al. Optimizing laser cladding on aluminum alloy surface with numerical simulation and rare earth modification[J]. Surface Technology, 49, 144-155(2020).

[3] Zhao L, Wang L F, Zhu G X et al. Numerical simulation on the influence of process parameters on residual stress in cladding layer by multi-mode semi-conductor laser additive manufacturing[J]. Applied Laser, 41, 366-373(2021).

[4] Tong W H, Zhang X Y, Li W X et al. Effect of laser process parameters on the microstructure and properties of TiC reinforced Co-based alloy laser cladding layer[J]. Acta Metallurgica Sinica, 56, 1265-1274(2020).

[5] Ding Q F, Pang M. Thermal-mechanical coupling simulation of high-entropy alloy laser cladding for inner barrel of an oil pump[J]. Laser & Optoelectronics Progress, 58, 0514002(2021).

[6] Li J H, An X J, Yao F P et al. Simulation on thermal stress cycle in laser cladding of H13 steel Ni-based coating[J]. Chinese Journal of Lasers, 48, 1002104(2021).

[7] Yu T B, Song B X, Xi W C et al. Influence of laser cladding process parameters on morphology of cladding layer and its optimization[J]. Journal of Northeastern University (Natural Science), 40, 537-542(2019).

[8] Gu S N, Wang G Y, Qin Y et al. Correlation between process parameters and microstructure morphologies of W-Cu composites fabricated by laser cladding[J]. Chinese Journal of Lasers, 45, 0402005(2018).

[9] Kong F R, Kovacevic R. Modeling of heat transfer and fluid flow in the laser multilayered cladding process[J]. Metallurgical and Materials Transactions B, 41, 1310-1320(2010).

[10] Zhang T G, Zhang Q, Yao B et al. Numerical simulation of temperature field and stress field of Ni-based laser cladding layer on TC4 surface[J]. Laser & Optoelectronics Progress, 58, 0314003(2021).

[11] Li M Y, Cai C B, Han B et al. Numerical simulation of preheating on temperature and stress fields by laser cladding Ni-based ceramic coating[J]. Transactions of Materials and Heat Treatment, 36, 197-203(2015).

[12] Li K K. Study on laser cladding 304 stainless steel and its enhancement by hot extrusion[D](2019).

[13] Liu H M, Li M B, Qin X P et al. Numerical simulation and experimental analysis of wide-beam laser cladding[J]. The International Journal of Advanced Manufacturing Technology, 100, 237-249(2019).

[14] Shu L S, Wang J S, Bai H Q et al. Numerical and experimental investigation on laser cladding treatment of wear shaft surface[J]. Journal of Mechanical Engineering, 55, 217-223(2019).

[15] Gao S Y, Li J, Li C G et al. Research on the variation regularity of single laser tracks cross-section morphology during laser cladding[J]. Chinese Journal of Lasers, 40, 0503010(2013).

[16] Zhao S J, Qi W J, Huang Y H et al. Numerical simulation study on thermal cycle characteristics of temperature field of TC4 surface laser cladding Ni60 based coating[J]. Surface Technology, 49, 301-308(2020).

[17] Zhao Y H, Sun J, Li J F. Research on microstructure properties and wear and corrosion resistance of FeCr repaired coating on KMN steel by laser cladding[J]. Journal of Mechanical Engineering, 51, 37-43(2015).

[18] Fan F J. Research on laser cladding coating of 718 superalloy[D](2018).

[19] Li Y Y, Hu C R[M]. Experiment design and data processing, 204-216(2017).

[20] Wei L, Pu H Y, Xiang H et al. Optimization of MDEA desulfurization process parameters based on quadratic regression orthogonal combination design[J]. Natural Gas Chemical Industry, 45, 75-79(2020).

[21] An X L, Wang Y L, Jiang F L et al. Influence of lap ratio on temperature field and residual stress distribution of 42CrMo laser cladding[J]. Chinese Journal of Lasers, 48, 1002110(2021).