[1] Cheng X N, Dai Q X[M]. Austenite design and control, 4-5(2005).

[2] Duan X X, Gao S Y, Gu Y F et al. Study on reinforcement mechanism and frictional wear properties of 316L-SiC mixed layer deposited by laser cladding[J]. Chinese Journal of Lasers, 43, 0103004(2016).

[3] Raj B, Mudali U K. Materials development and corrosion problems in nuclear fuel reprocessing plants[J]. Progress in Nuclear Energy, 48, 283-313(2006).

[4] Schwendner K I, Banerjee R, Collins P C et al. Direct laser deposition of alloys from elemental powder blends[J]. Scripta Materialia, 45, 1123-1129(2001).

[5] Pu Y S, Wang B Q, Zhang L G. Metal 3D printing technology[J]. Surface Technology, 47, 78-84(2018).

[6] Kamath C, El-Dasher B, Gallegos G F et al. Density of additively-manufactured, 316L SS parts using laser powder-bed fusion at powers up to 400 W[J]. The International Journal of Advanced Manufacturing Technology, 74, 65-78(2014).

[7] Yadroitsev I, Smurov I. Selective laser melting technology: from the single laser melted track stability to 3D parts of complex shape[J]. Physics Procedia, 5, 551-560(2010).

[8] [8] LaohaprapanonA, JeamwatthanachaiP, WongcumchangM, et al., 2011, 341/342: 816- 820.

[9] Liu Y B, Sun Q J, Jiang Y L et al. 35(7): 1-4, Ⅰ(2014).

[10] Martina F, Mehnen J, Williams S W et al. Investigation of the benefits of plasma deposition for the additive layer manufacture of Ti-6Al-4V[J]. Journal of Materials Processing Technology, 212, 1377-1386(2012).

[11] Luo Z, Zhang Y. 4): 13-16, Ⅰ[J]. Jia P. Additive manufacturing of Ti-6Al-4V titanium alloy parts based on micro-plasma arc surfacing. Welding & Joining(2016).

[12] Bai J Y, Fan C L, Yang Y C et al. -Al thin-walled parts produced by shaped metal deposition[J]. Transactions of the China Welding Institution, 2016, 37(6): 124-128, Ⅵ.(2219).

[13] Mok S H, Bi G J, Folkes J et al. Deposition of Ti-6Al-4V using a high power diode laser and wire, part I: investigation on the process characteristics[J]. Surface and Coatings Technology, 202, 3933-3939(2008).

[14] Smurov I, Doubenskaia M, Zaitsev A. Comprehensive analysis of laser cladding by means of optical diagnostics and numerical simulation[J]. Surface and Coatings Technology, 220, 112-121(2013).

[15] Pan H, Zhao J F, Liu Y L et al. Controllability research on dilution ratio of nickel-based superalloy by laser cladding reparation[J]. Chinese Journal of Lasers, 40, 0403007(2013).

[16] Yu J, Chen J, Tan H et al. Effect of process parameters in the laser rapid forming on deposition layer[J]. Chinese Journal of Lasers, 34, 1014-1018(2007).

[17] Guo W, Li K K, Chai R X et al. Numerical simulation and experiment of dilution effect in laser cladding 304 stainless steel[J]. Laser & Optoelectronics Progress, 56, 051402(2019).

[18] Chen G, Li X F, Zuo D W et al. Simulation on substrate relative dilution ratio for GH4033[J]. Laser & Optoelectronics Progress, 48, 011601(2011).

[19] Katayama S, Fujimoto T, Matsunawa A. Correlation among solidification process, microstructure, microsegregation and solidification cracking susceptibility in stainless steel weld metals (materials, metallurgy & weldability)[J]. Transactions of JWRI, 14, 123-138(1985).

[20] Schaeffler A L. Constitution diagram for stainless steel weld metal[J]. Metal Progress, 56, 680(1949).

[21] Zhang B C, Dembinski L, Coddet C. The study of the laser parameters and environment variables effect on mechanical properties of high compact parts elaborated by selective laser melting 316L powder[J]. Materials Science and Engineering: A, 584, 21-31(2013).

[22] Elmer J W, Allen S M, Eagar T W. Microstructural development during solidification of stainless steel alloys[J]. Metallurgical Transactions A, 20, 2117-2131(1989).

[23] Chen X H, Li J, Cheng X et al. Microstructure and mechanical properties of the austenitic stainless steel 316L fabricated by gas metal arc additive manufacturing[J]. Materials Science and Engineering: A, 703, 567-577(2017).