Studies on Tensile Behaviour of Selective Laser Melted 316L Stainless Steel Using SEM Straining Stage
暂无分享,去创建一个
V. Srivastava | S. Tarafder | S. Rajkumar | K. Krishna | G. Das | S. Ghosh Chowdhury | A. Chandan | G. K. Bansal
[1] D. Raabe,et al. Steels in additive manufacturing: A review of their microstructure and properties , 2020 .
[2] M. Mukherjee. Effect of build geometry and orientation on microstructure and properties of additively manufactured 316L stainless steel by laser metal deposition , 2019, Materialia.
[3] Kaushik Chatterjee,et al. Non-equilibrium microstructure, crystallographic texture and morphological texture synergistically result in unusual mechanical properties of 3D printed 316L stainless steel , 2019, Additive Manufacturing.
[4] S. Chowdhury,et al. Stacking Fault Energy of Austenite Phase in Medium Manganese Steel , 2019, Metallurgical and Materials Transactions A.
[5] N. Provatas,et al. The Significance of Spatial Length Scales and Solute Segregation in Strengthening Rapid Solidification Microstructures of 316L Stainless Steel , 2019, Acta Materialia.
[6] Young‐kook Lee,et al. Anisotropic Mechanical Behavior of Additive Manufactured AISI 316L Steel , 2019, Metallurgical and Materials Transactions A.
[7] Yuanjian Hong,et al. Formation of strain-induced martensite in selective laser melting austenitic stainless steel , 2019, Materials Science and Engineering: A.
[8] Radovan Kovacevic,et al. An investigation on mechanical and microstructural properties of 316LSi parts fabricated by a robotized laser/wire direct metal deposition system , 2018, Additive Manufacturing.
[9] Jean-Pierre Kruth,et al. Microstructure evolution of 316L produced by HP-SLM (high power selective laser melting) , 2018, Additive Manufacturing.
[10] Chee Kai Chua,et al. Simultaneously enhanced strength and ductility for 3D-printed stainless steel 316L by selective laser melting , 2018, NPG Asia Materials.
[11] Ting Zhu,et al. Additively manufactured hierarchical stainless steels with high strength and ductility. , 2018, Nature materials.
[12] Liang Hao,et al. Effect of build orientation on the surface quality, microstructure and mechanical properties of selective laser melting 316L stainless steel , 2017 .
[13] G. Pacchioni. 3D printing: May the strength be with you , 2017 .
[14] L. Hitzler,et al. On the Anisotropic Mechanical Properties of Selective Laser-Melted Stainless Steel , 2017, Materials.
[15] Filipe S. Silva,et al. 316L stainless steel mechanical and tribological behavior—A comparison between selective laser melting, hot pressing and conventional casting , 2017 .
[16] Y. Zhong,et al. Intragranular cellular segregation network structure strengthening 316L stainless steel prepared by selective laser melting , 2016 .
[17] Yusheng Shi,et al. Differences in microstructure and properties between selective laser melting and traditional manufacturing for fabrication of metal parts: A review , 2015 .
[18] Surendar Marya,et al. Microstructural Development and Technical Challenges in Laser Additive Manufacturing: Case Study with a 316L Industrial Part , 2015, Metallurgical and Materials Transactions B.
[19] K. Kunze,et al. Texture, anisotropy in microstructure and mechanical properties of IN738LC alloy processed by selective laser melting (SLM) , 2015 .
[20] Konrad Wegener,et al. Fatigue performance of additive manufactured metallic parts , 2013 .
[21] Young‐kook Lee. Microstructural evolution during plastic deformation of twinning-induced plasticity steels , 2012 .
[22] D. Raabe,et al. The effect of grain size and grain orientation on deformation twinning in a Fe-22 wt.% Mn-0.6 wt.% C TWIP steel , 2010 .
[23] G. Frommeyer,et al. Enhanced Mechanical Properties of a Novel High-Nitrogen Cr-Mn-Ni-Si Austenitic Stainless Steel via TWIP/TRIP Effects , 2009 .
[24] S. Takaki,et al. Deformation twinning in high-nitrogen austenitic stainless steel , 2007 .
[25] Li Meng,et al. Dependence of deformation twinning on grain orientation in a high manganese steel , 2006 .
[26] L. Froyen,et al. Binding Mechanisms in Selective Laser Sintering and Selective Laser Melting , 2004 .