[1] Zhao X S, Yang J Z, Chen J H et al. Surface reconstruction and tool path generation method for remanufacturing of the damaged blade[J]. China Mechanical Engineering, 1-11(2019).
[2] Chen S D. Research progress on microstructure and preparation methods for MCrAlY bond coats[J]. Materials Review, 33, 2582-2588(2019).
[3] Wang T, Wang N, Li Y et al. Study on preparation technologies of thermal barrier coatings[J]. Surface Review and Letters, 24, 1730004(2017).
[4] Wu S B, Dou W H, Yang Y Q et al. Research progress of inspection technology for addition manufacturing of SLM metal[J]. Journal of Netshape Forming Engineering, 11, 37-50(2019).
[5] Doubenskaia M, Domashenkov A, Smurov I et al. Study of selective laser melting of intermetallic TiAl powder using integral analysis[J]. International Journal of Machine Tools and Manufacture, 129, 1-14(2018).
[6] Weng W X, Wang Y M, Liao Y M et al. Comparison of microstructural evolution and oxidation behaviour of NiCoCrAlY and CoNiCrAlY as bond coats used for thermal barrier coatings[J]. Surface and Coatings Technology, 352, 285-294(2018).
[7] Falcón J C P, Echeverría A, Afonso C R M et al. Microstructure assessment at high temperature in NiCoCrAlY overlay coating obtained by laser metal deposition[J]. Journal of Materials Research and Technology, 8, 1761-1772(2019).
[8] Pereira J C, Zambrano J C, Rayón E et al. Mechanical and microstructural characterization of MCrAlY coatings produced by laser cladding: the influence of the Ni, Co and Al content[J]. Surface and Coatings Technology, 338, 22-31(2018).
[9] Pereira J, Zambrano J, Licausi M et al[J]. high temperature friction wear behavior of MCrAlY laser cladding coatings on stainless steel. Wear, 330/331, 280-287(2015).
[10] Wang T, Liu J Q, Qin L C et al. Effects of laser power on microstructure and hardness of CoNiCrAlY cladding coatings[J]. Hot Working Technology, 47, 142-145(2018).
[11] Zhou S F, Huang Y J, Zeng X Y et al. Microstructure characteristics of Ni-based WC composite coatings by laser induction hybrid rapid cladding[J]. Materials Science and Engineering: A, 480, 564-572(2008).
[12] Huang Y J, Zeng X Y, Hu Q W et al. Microstructure and interface interaction in laser induction hybrid cladding of Ni-based coating[J]. Applied Surface Science, 255, 3940-3945(2009).
[13] Lei J B, Shi C, Zhou S F et al. Enhanced corrosion and wear resistance properties of carbon fiber reinforced Ni-based composite coating by laser cladding[J]. Surface and Coatings Technology, 334, 274-285(2018).
[14] Wang H Y, Zuo D W, Wang M D et al. High temperature frictional wear behaviors of nano-particle reinforced NiCoCrAlY cladded coatings[J]. Transactions of Nonferrous Metals Society of China, 21, 1322-1328(2011).
[15] Wang T, Liu J Q, Qin L C et al. Laser direct deposition of CoCrAlSiY/YSZ composites: densification, microstructure and mechanical properties[J]. Journal of Thermal Spray Technology, 28, 862-879(2019).
[16] Song X L, Lei J B, Xie J C et al. Microstructure and electrochemical corrosion properties of nickel-plated carbon nanotubes composite Inconel718 alloy coatings by laser melting deposition[J]. Optics & Laser Technology, 119, 105593(2019).