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LI Chao. Research Progress of Laser Additive Manufacturing Formed 316L Stainless Steel[J]. Materials and Mechanical Engineering, 2022, 46(8): 1-7. DOI: 10.11973/jxgccl202208001
Citation: LI Chao. Research Progress of Laser Additive Manufacturing Formed 316L Stainless Steel[J]. Materials and Mechanical Engineering, 2022, 46(8): 1-7. DOI: 10.11973/jxgccl202208001
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Research Progress of Laser Additive Manufacturing Formed 316L Stainless Steel

  • Baotou Vocational & Technical College, Baotou 014030, China

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  • Received Date: March 22, 2021
  • Revised Date: May 22, 2022
    Graphical Abstract
    • Abstract
  • Laser additive manufacturing technique has the advantage of rapidly forming complex-shaped parts, and has received widespread attention in recent years. Two laser additive manufacturing techniques, directed energy deposition and selective laser melting, are introduced. The research progress of laser additive manufacturing formed 316L stainless steel is reviewed from the aspects of common defect, microstructure and texture, and mechanical properties. The current problems of laser additive manufacturing formed 316L stainless steel are analyzed, and its development prospects are prospected.
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  • [1]
    HUANG H W,WANG Z B,LU J,et al.Fatigue behaviors of AISI 316L stainless steel with a gradient nanostructured surface layer[J].Acta Materialia,2015,87:150-160.
    [2]
    SHARMA G S,SUGAVANESWARAN M,VIJAYALAKSHMI U,et al.Influence of γ-alumina coating on surface properties of direct metal laser sintered 316L stainless steel[J].Ceramics International,2019,45(10):13456-13463.
    [3]
    MATAYA M C,NILSSON E R,BROWN E L,et al.Hot working and recrystallization of as-cast 316L[J].Metallurgical and Materials Transactions A,2003,34(8):1683-1703.
    [4]
    CHEN X H,LU J,LU L,et al.Tensile properties of a nanocrystalline 316L austenitic stainless steel[J].Scripta Materialia,2005,52(10):1039-1044.
    [5]
    WONG K V,HERNANDEZ A.A review of additive manufacturing[J].ISRN Mechanical Engineering,2012,2012:208760.
    [6]
    WU X.A review of laser fabrication of metallic engineering components and of materials[J].Materials Science and Technology,2007,23(6):631-640.
    [7]
    WANG Y M,VOISIN T,MCKEOWN J T,et al.Additively manufactured hierarchical stainless steels with high strength and ductility[J].Nature Materials,2018,17(1):63-71.
    [8]
    YIN H,FELICELLI S D.Dendrite growth simulation during solidification in the LENS process[J].Acta Materialia,2010,58(4):1455-1465.
    [9]
    DOBBELSTEIN H,GUREVICH E L,GEORGE E P,et al.Laser metal deposition of a refractory TiZrNbHfTa high-entropy alloy[J].Additive Manufacturing,2018,24:386-390.
    [10]
    LIN X,YUE T M,YANG H O,et al.Laser rapid forming of SS316L/Rene88DT graded material[J].Materials Science and Engineering:A,2005,391(1/2):325-336.
    [11]
    LI L J.Repair of directionally solidified superalloy GTD-111 by laser-engineered net shaping[J].Journal of Materials Science,2006,41(23):7886-7893.
    [12]
    BANERJEE R,COLLINS P C,BHATTACHARYYA D,et al.Microstructural evolution in laser deposited compositionally graded α/β titanium-vanadium alloys[J].Acta Materialia,2003,51(11):3277-3292.
    [13]
    SCIPIONI BERTOLI U,MACDONALD B E,SCHOENUNG J M.Stability of cellular microstructure in laser powder bed fusion of 316L stainless steel[J].Materials Science and Engineering:A,2019,739:109-117.
    [14]
    BERTSCH K M,DE BELLEFON G M,KUEHL B,et al.Origin of dislocation structures in an additively manufactured austenitic stainless steel 316L[J].Acta Materialia,2020,199:19-33.
    [15]
    XU K,LI B C,LI S M,et al.In situ observation for the fatigue crack growth mechanism of 316L stainless steel fabricated by laser engineered net shaping[J].International Journal of Fatigue,2020,130:105272.
    [16]
    GAO S B,HU Z H,DUCHAMP M,et al.Recrystallization-based grain boundary engineering of 316L stainless steel produced via selective laser melting[J].Acta Materialia,2020,200:366-377.
    [17]
    MILLER J T,MARTIN H J,CUDJOE E.Comparison of the effects of a sulfuric acid environment on traditionally manufactured and additive manufactured stainless steel 316L alloy[J].Additive Manufacturing,2018,23:272-286.
    [18]
    SUN Z J,TAN X P,TOR S B,et al.Selective laser melting of stainless steel 316L with low porosity and high build rates[J].Materials&Design,2016,104:197-204.
    [19]
    WANG D,SONG C H,YANG Y Q,et al.Investigation of crystal growth mechanism during selective laser melting and mechanical property characterization of 316L stainless steel parts[J].Materials&Design,2016,100:291-299.
    [20]
    LIU L F,DING Q Q,ZHONG Y,et al.Dislocation network in additive manufactured steel breaks strength-ductility trade-off[J].Materials Today,2018,21(4):354-361.
    [21]
    GRAY G T III,LIVESCU V,RIGG P A,et al.Structure/property (constitutive and spallation response) of additively manufactured 316L stainless steel[J].Acta Materialia,2017,138:140-149.
    [22]
    LALEH M,HUGHES A E,XU W,et al.On the unusual intergranular corrosion resistance of 316L stainless steel additively manufactured by selective laser melting[J].Corrosion Science,2019,161:108189.
    [23]
    YADOLLAHI A,SHAMSAEI N,THOMPSON S M,et al.Effects of process time interval and heat treatment on the mechanical and microstructural properties of direct laser deposited 316L stainless steel[J].Materials Science and Engineering:A,2015,644:171-183.
    [24]
    SUN Z J,TAN X P,TOR S B,et al.Simultaneously enhanced strength and ductility for 3D-printed stainless steel 316L by selective laser melting[J].NPG Asia Materials,2018,10(4):127-136.
    [25]
    WOO W,JEONG J S,KIM D K,et al.Stacking fault energy analyses of additively manufactured stainless steel 316L and CrCoNi medium entropy alloy using in situ neutron diffraction[J].Scientific Reports,2020,10:1350.
    [26]
    KUMAR P,JAYARAJ R,SURYAWANSHI J,et al.Fatigue strength of additively manufactured 316L austenitic stainless steel[J].Acta Materialia,2020,199:225-239.
    [27]
    WILSON-HEID A E,QIN S P,BEESE A M.Multiaxial plasticity and fracture behavior of stainless steel 316L by laser powder bed fusion:Experiments and computational modeling[J].Acta Materialia,2020,199:578-592.
    [28]
    ZHENG B,ZHOU Y,SMUGERESKY J E,et al.Thermal behavior and microstructural evolution during laser deposition with laser-engineered net shaping:Part I.numerical calculations[J].Metallurgical and Materials Transactions A,2008,39(9):2228-2236.
    [29]
    XIONG Y H,HOFMEISTER W H,CHENG Z,et al.In situ thermal imaging and three-dimensional finite element modeling of tungsten carbide-cobalt during laser deposition[J].Acta Materialia,2009,57(18):5419-5429.
    [30]
    YE R Q,SMUGERESKY J E,ZHENG B L,et al.Numerical modeling of the thermal behavior during the LENS® process[J].Materials Science and Engineering:A,2006,428(1/2):47-53.
    [31]
    XIAO W J,LI S M,WANG C S,et al.Multi-scale simulation of dendrite growth for direct energy deposition of nickel-based superalloys[J].Materials&Design,2019,164:107553.
    [32]
    MOOREHEAD M,BERTSCH K,NIEZGODA M,et al.High-throughput synthesis of Mo-Nb-Ta-W high-entropy alloys via additive manufacturing[J].Materials&Design,2020,187:108358.
    [33]
    YUAN P P,GU D D,DAI D H.Particulate migration behavior and its mechanism during selective laser melting of TiC reinforced Al matrix nanocomposites[J].Materials&Design,2015,82:46-55.
    [34]
    WANG X Q,CARTER L N,PANG B,et al.Microstructure and yield strength of SLM-fabricated CM247LC Ni-Superalloy[J].Acta Materialia,2017,128:87-95.
    [35]
    PARK J M, CHOE J, KIM J G, et al.Superior tensile properties of 1% C-CoCrFeMnNi high-entropy alloy additively manufactured by selective laser melting[J].Materials Research Letters, 2019, 8(1):1-7.
    [36]
    HOOPER P A.Melt pool temperature and cooling rates in laser powder bed fusion[J].Additive Manufacturing,2018,22:548-559.
    [37]
    ZIÓŁKOWSKI G,CHLEBUS E,SZYMCZYK P,et al.Application of X-ray CT method for discontinuity and porosity detection in 316L stainless steel parts produced with SLM technology[J].Archives of Civil and Mechanical Engineering,2014,14(4):608-614.
    [38]
    DEBROY T,WEI H L,ZUBACK J S,et al.Additive manufacturing of metallic components:Process,structure and properties[J].Progress in Materials Science,2018,92:112-224.
    [39]
    KING W E,BARTH H D,CASTILLO V M,et al.Observation of keyhole-mode laser melting in laser powder-bed fusion additive manufacturing[J].Journal of Materials Processing Technology,2014,214(12):2915-2925.
    [40]
    WANG G W,LIANG J J,YANG Y H,et al.Effects of scanning speed on microstructure in laser surface-melted single crystal superalloy and theoretical analysis[J].Journal of Materials Science&Technology,2018,34(8):1315-1324.
    [41]
    JOHNSON L,MAHMOUDI M,ZHANG B,et al.Assessing printability maps in additive manufacturing of metal alloys[J].Acta Materialia,2019,176:199-210.
    [42]
    ANTONY K,ARIVAZHAGAN N,SENTHILKUMARAN K.Numerical and experimental investigations on laser melting of stainless steel 316L metal powders[J].Journal of Manufacturing Processes,2014,16(3):345-355.
    [43]
    SONG J L,LI Y T,DENG Q L,et al.Cracking mechanism of laser cladding rapid manufacturing 316L stainless steel[J].Key Engineering Materials,2009,419/420:413-416.
    [44]
    陈静,林鑫,王涛,等.316L不锈钢激光快速成形过程中熔覆层的热裂机理[J].稀有金属材料与工程,2003,32(3):183-186.

    CHEN J,LIN X,WANG T,et al.The hot cracking mechanism of 316L stainless steel cladding in rapid laser forming process[J].Rare Metal Materials and Engineering,2003,32(3):183-186.
    [45]
    LIN X,YUE T M,YANG H O,et al.Microstructure and phase evolution in laser rapid forming of a functionally graded Ti-Rene88DT alloy[J].Acta Materialia,2006,54(7):1901-1915.
    [46]
    LIN X,YUE T M.Phase formation and microstructure evolution in laser rapid forming of graded SS316L/Rene88DT alloy[J].Materials Science and Engineering:A,2005,402(1/2):294-306.
    [47]
    LI Y M,YANG H O,LIN X,et al.The influences of processing parameters on forming characterizations during laser rapid forming[J].Materials Science and Engineering:A,2003,360(1/2):18-25.
    [48]
    KURZ W,BEZENÇON C,GÄUMANN M.Columnar to equiaxed transition in solidification processing[J].Science and Technology of Advanced Materials,2001,2(1):185-191.
    [49]
    GÄUMANN M,HENRY S,CLÉTON F,et al.Epitaxial laser metal forming:Analysis of microstructure formation[J].Materials Science and Engineering:A,1999,271(1/2):232-241.
    [50]
    GÄUMANN M,BEZENÇON C,CANALIS P,et al.Single-crystal laser deposition of superalloys:Processing-microstructure maps[J].Acta Materialia,2001,49(6):1051-1062.
    [51]
    DUBÉ D,FISET M,COUTURE A,et al.Characterization and performance of laser melted AZ91D and AM60B[J].Materials Science and Engineering:A,2001,299(1/2):38-45.
    [52]
    DINDA G P,DASGUPTA A K,MAZUMDER J.Laser aided direct metal deposition of Inconel 625 superalloy:Microstructural evolution and thermal stability[J].Materials Science and Engineering:A,2009,509(1/2):98-104.
    [53]
    CLÉTON F,JOUNEAU P H,HENRY S,et al.Crystallographic orientation assessment by electron backscattered diffraction[J].Scanning,1999,21(4):232-237.
    [54]
    BANERJEE R,COLLINS P C,GENÇ A,et al.Direct laser deposition of in situ Ti-6Al-4V-TiB composites[J].Materials Science and Engineering:A,2003,358(1/2):343-349.
    [55]
    AMANO R S,ROHATGI P K.Laser engineered net shaping process for SAE 4140 low alloy steel[J].Materials Science and Engineering:A,2011,528(22/23):6680-6693.
    [56]
    BANERJEE R,BRICE C A,BANERJEE S,et al.Microstructural evolution in laser deposited Ni-25at.% Mo alloy[J].Materials Science and Engineering:A,2003,347(1/2):1-4.
    [57]
    ELMER J W,ALLEN S M,EAGAR T W.Microstructural development during solidification of stainless steel alloys[J].Metallurgical Transactions A,1989,20(10):2117-2131.
    [58]
    ZIETALA M,DUREJKO T,POLA AŃSKI M,et al.The microstructure,mechanical properties and corrosion resistance of 316 L stainless steel fabricated using laser engineered net shaping[J].Materials Science and Engineering:A,2016,677:1-10.
    [59]
    SURYAWANSHI J,PRASHANTH K G,RAMAMURTY U.Mechanical behavior of selective laser melted 316L stainless steel[J].Materials Science and Engineering:A,2017,696:113-121.
    [60]
    NIENDORF T,LEUDERS S,RIEMER A,et al.Highly anisotropic steel processed by selective laser melting[J].Metallurgical and Materials Transactions B,2013,44(4):794-796.
    [61]
    RIEMER A,LEUDERS S,THÖNE M,et al.On the fatigue crack growth behavior in 316L stainless steel manufactured by selective laser melting[J].Engineering Fracture Mechanics,2014,120:15-25.
    [62]
    SUN S H,ISHIMOTO T,HAGIHARA K,et al.Excellent mechanical and corrosion properties of austenitic stainless steel with a unique crystallographic lamellar microstructure via selective laser melting[J].Scripta Materialia,2019,159:89-93.
    [63]
    ZHONG Y,LIU L F,WIKMAN S,et al.Intragranular cellular segregation network structure strengthening 316L stainless steel prepared by selective laser melting[J].Journal of Nuclear Materials,2016,470:170-178.
    [64]
    SHAMSUJJOHA M,AGNEW S R,FITZ-GERALD J M,et al.High strength and ductility of additively manufactured 316L stainless steel explained[J].Metallurgical and Materials Transactions A,2018,49(7):3011-3027.
    [65]
    YIN Y J,SUN J Q,GUO J,et al.Mechanism of high yield strength and yield ratio of 316L stainless steel by additive manufacturing[J].Materials Science and Engineering:A,2019,744:773-777.
    [66]
    MAZÁNOVÁ V,HECZKO M,ŠKORÍK V,et al.Microstructure and martensitic transformation in 316L austenitic steel during multiaxial low cycle fatigue at room temperature[J].Materials Science and Engineering:A,2019,767:138407.
    [67]
    SHRESTHA R,SIMSIRIWONG J,SHAMSAEI N.Fatigue behavior of additive manufactured 316L stainless steel parts:Effects of layer orientation and surface roughness[J].Additive Manufacturing,2019,28:23-38.
    [68]
    ELANGESWARAN C,CUTOLO A,MURALIDHARAN G K,et al.Microstructural analysis and fatigue crack initiation modelling of additively manufactured 316L after different heat treatments[J].Materials&Design,2020,194:108962.
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