Laser Powder Bed Fusion of GH3536 Alloy

Shiling Min; Juan Hou; Kai Zhang; Aijun Huang

doi:10.3788/LOP202158.1700008

[1] Shi C X, Zhong Z Y. Development and innovation of superalloy in China[J]. Acta Metallurgica Sinica, 46, 1281-1288(2010).

[2] Tang Z J, Guo T M, Fu Y et al. Research present situation and the development prospect of nickel-based superalloy[J]. Metal World, 36-40(2014).

[3] Li X L, Ma J X, Li P et al. 3D printing technology and its application trend[J]. Process Automation Instrumentation, 35, 1-5(2014).

[4] Liu J S. Numerical simulation and machining emulation of selective laser sintering[D](2011).

[5] Chi M. Numerical and experimental research of selective laser melting additive manufacturing for metal material[D](2019).

[6] Lu B H, Li D C. Development of the additive manufacturing (3D printing) technology[J]. Machine Building & Automation, 42, 1-4(2013).

[7] Olakanmi E O, Cochrane R F, Dalgarno K W. A review on selective laser sintering/melting (SLS/SLM) of aluminium alloy powders: processing, microstructure, and properties[J]. Progress in Materials Science, 74, 401-477(2015).

[8] Sames W J, List F A, Pannala S et al. The metallurgy and processing science of metal additive manufacturing[J]. International Materials Reviews, 61, 315-360(2016).

[9] Gong S L, Suo H B, Li H X. Development and application of metal additive manufacturing technology[J]. Aeronautical Manufacturing Technology, 56, 66-71(2013).

[10] Zhu H B, Liu Y. Current research status of metal prototyping manufacturing (3D-printing) technology application in rail transit equipment[J]. Modern Urban Transit, 77-81(2019).

[11] Yang Y Q, Song C H, Wang D. Selective laser melting and its applications on personalized medical parts[J]. Journal of Mechanical Engineering, 50, 140-151(2014).

[12] Yang Y H. Analysis of classifications and characteristic of additive manufacturing (3D print)[J]. Advances in Aeronautical Science and Engineering, 10, 309-318(2019).

[13] Herzog D, Seyda V, Wycisk E et al. Additive manufacturing of metals[J]. Acta Materialia, 117, 371-392(2016).

[15] Shi Y S, Lu Z L, Zhang W X et al. The technology and equipment of selective laser melting[J]. China Surface Engineering, 19, 150-153(2006).

[16] He X R, Yang Y Q, Wang D et al. Direct manufacturing of customized crowns and fixed bridge by selectivelaser melting[J]. Laser Technology, 34, 1-4(2010).

[17] Yang Y Q, Wang D, Wu W H. Research progress of direct manufacturing of metal parts by selective laser melting[J]. Chinese Journal of Lasers, 38, 0601007(2011).

[18] Hu Z H, Song C H, Liu L Q et al. Research progress of selective laser melting of nitinol[J]. Chinese Journal of Lasers, 47, 1202005(2020).

[19] Zhang H Q, Wang C, He L. Investigation on microstructure and defects control of nickel-based superalloy Hastelloy-X obtained by selective laser melting process[J]. Thermal Turbine, 48, 218-222, 238(2019).

[20] Lin X, Huang W D. Laser additive manufacturing of high-performance metal components[J]. Science China: Information Sciences, 45, 1111-1126(2015).

[21] Guo C H, Wang Z C, Yan J Y et al. Research progress in additive-subtractive hybrid manufacturing[J]. Chinese Journal of Engineering, 42, 540-548(2020).

[22] Chang Y C, Pinilla J M, Kao J H et al. Automated layer decomposition for additive/subtractive solid freeform fabrication[C], 111-120(1999).

[23] Gao M Q, Zhao Y H, Zhao J B et al. Influence of matrix temperature state on surface quality during interactive additive and subtractive manufacturing[J]. Chinese Journal of Lasers, 47, 0802011(2020).

[24] Zhao J G, Hou J, Xiong X J. Research on joint performance of 304L stainless steel used in nuclear industry via an additive and reductive hybrid manufacturing based on laser direct deposition technology[J]. Electric Welding Machine, 50, 39-45, 148-149(2020).

[25] Li S. The study on the milling characteristic for titanium alloy in additive/subtractive hybrid manufacturing[D](2018).

[27] Wang W F. Study on precision forging process of GH3536 alloy nozzle shell[D](2017).

[28] Liu X J. Welding stress/deformation control and processing technology optimization of thin-wall casing of high temperature alloy[D](2018).

[29] Zhao J C, Larsen M, Ravikumar V. Phase precipitation and time-temperature-transformation diagram of Hastelloy X[J]. Materials Science and Engineering A, 293, 112-119(2000).

[30] Zhao H B, Feng W, Zhou T J. Distribution of primary M6C carbide in large nickel-based superalloy casting[J]. Foundry Technology, 38, 1288-1291(2017).

[31] Yi Y J. Theoretical studies on stabilities and high-temperature elastic properties of carbides in Ni-based superalloys[D](2017).

[32] Tomus D, Tian Y, Rometsch P A et al. Influence of post heat treatments on anisotropy of mechanical behaviour and microstructure of Hastelloy-X parts produced by selective laser melting[J]. Materials Science and Engineering A, 667, 42-53(2016).

[33] Wang F D. Mechanical property study on rapid additive layer manufacture Hastelloy® X alloy by selective laser melting technology[J]. The International Journal of Advanced Manufacturing Technology, 58, 545-551(2012).

[34] DebRoy T, Wei H L, Zuback J S et al. Additive manufacturing of metallic components: process, structure and properties[J]. Progress in Materials Science, 92, 112-224(2018).

[35] Wu W H, Yang Y Q, Wang D. Balling phenomenon in selective laser melting process[J]. Journal of South China University of Technology (Natural Science Edition), 38, 110-115(2010).

[36] Zaeh M F, Branner G. Investigations on residual stresses and deformations in selective laser melting[J]. Production Engineering, 4, 35-45(2010).

[37] Chen Y, Chen H, Jiang Y S et al. Research progress in stress and deformation control in laser additive manufacturing for high-performance metals[J]. Journal of Materials Engineering, 47, 1-10(2019).

[38] Zhang G Q, Yang Y Q, Zhang Z M et al. Optimal design of support structures in selective laser melting of parts[J]. Chinese Journal of Lasers, 43, 1202002(2016).

[39] Montero-Sistiaga M L, Pourbabak S, van Humbeeck J et al. Microstructure and mechanical properties of Hastelloy X produced by HP-SLM (high power selective laser melting)[J]. Materials & Design, 165, 107598(2019).

[40] Esmaeilizadeh R, Keshavarzkermani A, Ali U et al. Customizing mechanical properties of additively manufactured Hastelloy X parts by adjusting laser scanning speed[J]. Journal of Alloys and Compounds, 812, 152097(2020).

[41] Tomus D, Rometsch P A, Heilmaier M et al. Effect of minor alloying elements on crack-formation characteristics of Hastelloy-X manufactured by selective laser melting[J]. Additive Manufacturing, 16, 65-72(2017).

[42] Han Q Q, Gu Y C, Setchi R et al. Additive manufacturing of high-strength crack-free Ni-based Hastelloy X superalloy[J]. Additive Manufacturing, 30, 100919(2019).

[43] Zhang Y Z, Hou H P, Peng S et al. Anisotropy of microstructure and mechanical properties of Hastelloy X alloy produced by selective laser melting[J]. Journal of Aeronautical Materials, 38, 50-56(2018).

[44] Li Y L, Qi H, Hou H P et al. Effects of hot isostatic pressing on microstructure and mechanical properties of Hastelloy X samples produced by selective laser melting[C](2017).

[45] Xue J Q, Chen X H, Lei L M. Effects of microstructure on mechanical properties of GH3536 alloy fabricated by selective laser melting[J]. Laser & Optoelectronics Progress, 56, 141401(2019).

[46] Sanchez-Mata O, Muñiz-Lerma J A, Wang X et al. Microstructure and mechanical properties at room and elevated temperature of crack-free Hastelloy X fabricated by laser powder bed fusion[J]. Materials Science and Engineering A, 780, 139177(2020).

[47] Liu K. Impact of HIP on the structure and property of GH3536 alloy formed by SLM[D](2018).

[48] Zheng Y L, He Y L, Chen X H et al. Elevated-temperature tensile properties and fracture behavior of GH3536 alloy formed via selective laser melting[J]. Chinese Journal of Lasers, 47, 0802008(2020).

[49] Li Y. Research on forming behavior and high temperature properties of GH3536 superalloy by selective laser melting technology[D](2019).

微信扫一扫：分享

微信扫一扫：分享