Surface residual stress and phase stability in unstable β-type Ti–15Mo–5Zr–3Al alloy manufactured by laser and electron beam powder bed fusion technologies

[1]  T. Ishimoto,et al.  Lattice distortion in selective laser melting (SLM)-manufactured unstable β-type Ti-15Mo-5Zr-3Al alloy analyzed by high-precision X-ray diffractometry , 2021 .

[2]  K. Mølhave,et al.  Analysis of Electron Transparent Beam-Sensitive Samples Using Scanning Electron Microscopy Coupled With Energy-Dispersive X-ray Spectroscopy , 2020, Microscopy and Microanalysis.

[3]  M. Pham,et al.  The role of side-branching in microstructure development in laser powder-bed fusion , 2020, Nature Communications.

[4]  A. Revuelta,et al.  On the effect of shielding gas flow on porosity and melt pool geometry in laser powder bed fusion additive manufacturing , 2020 .

[5]  Devlin Hayduke,et al.  An inherent strain based multiscale modeling framework for simulating part-scale residual deformation for direct metal laser sintering , 2019, Additive Manufacturing.

[6]  Xiaodong Li,et al.  An overview of residual stresses in metal powder bed fusion , 2019, Additive Manufacturing.

[7]  G. Requena,et al.  Exploring the Correlation between Subsurface Residual Stresses and Manufacturing Parameters in Laser Powder Bed Fused Ti-6Al-4V , 2019, Metals.

[8]  K. Hagihara,et al.  Excellent mechanical and corrosion properties of austenitic stainless steel with a unique crystallographic lamellar microstructure via selective laser melting , 2019, Scripta Materialia.

[9]  J. Ding,et al.  Model of laser energy absorption adjusted to optical measurements with effective use in finite element simulation of selective laser melting , 2018, Materials & Design.

[10]  Christopher J. Sutcliffe,et al.  Determination of the effect of scan strategy on residual stress in laser powder bed fusion additive manufacturing , 2018, Additive Manufacturing.

[11]  Haihong Zhu,et al.  Microstructure prediction of selective laser melting AlSi10Mg using finite element analysis , 2018 .

[12]  J. S. Zuback,et al.  Additive manufacturing of metallic components – Process, structure and properties , 2018 .

[13]  M. Benedetti,et al.  Fatigue and biological properties of Ti-6Al-4V ELI cellular structures with variously arranged cubic cells made by selective laser melting. , 2018, Journal of the mechanical behavior of biomedical materials.

[14]  Lars-Erik Rännar,et al.  Fabrication of multiple-layered gradient cellular metal scaffold via electron beam melting for segmental bone reconstruction , 2017 .

[15]  Eric J. Faierson,et al.  A framework to link localized cooling and properties of directed energy deposition (DED)-processed Ti-6Al-4V , 2017 .

[16]  K. Mumtaz,et al.  In-situ residual stress reduction, martensitic decomposition and mechanical properties enhancement through high temperature powder bed pre-heating of Selective Laser Melted Ti6Al4V , 2017 .

[17]  K. Hagihara,et al.  Crystallographic texture control of beta-type Ti–15Mo–5Zr–3Al alloy by selective laser melting for the development of novel implants with a biocompatible low Young's modulus , 2017 .

[18]  R. Dehoff,et al.  Effects of heat treatments on microstructure and properties of Ti-6Al-4V ELI alloy fabricated by electron beam melting (EBM) , 2017 .

[19]  Amitava De,et al.  Mitigation of thermal distortion during additive manufacturing , 2017 .

[20]  A. Beese,et al.  Residual stress mapping in Inconel 625 fabricated through additive manufacturing: Method for neutron diffraction measurements to validate thermomechanical model predictions , 2017 .

[21]  J. Bernardin,et al.  Neutron diffraction measurements of residual stress in additively manufactured stainless steel , 2016 .

[22]  Yunping Li,et al.  Effect of Building Position on Phase Distribution in Co-Cr-Mo Alloy Additive Manufactured by Electron-Beam Melting , 2016 .

[23]  Philip Nash,et al.  Finite-element analysis and experimental validation of thermal residual stress and distortion in electron beam additive manufactured Ti-6Al-4V build plates , 2016 .

[24]  C. Tasan,et al.  From electronic structure to phase diagrams: A bottom-up approach to understand the stability of titanium–transition metal alloys , 2016 .

[25]  Hui Wang,et al.  Microstructure, defects and mechanical behavior of beta-type titanium porous structures manufactured by electron beam melting and selective laser melting , 2016 .

[26]  Rui Yang,et al.  Electron Beam Melted Beta-type Ti-24Nb-4Zr-8Sn Porous Structures With High Strength-to-Modulus Ratio , 2016 .

[27]  Lai‐Chang Zhang,et al.  Selective Laser Melting of Titanium Alloys and Titanium Matrix Composites for Biomedical Applications: A Review   , 2016 .

[28]  Nam Phan,et al.  Critical assessment of the fatigue performance of additively manufactured Ti–6Al–4V and perspective for future research , 2016 .

[29]  Matthew Roy,et al.  Residual stress of as-deposited and rolled wire+arc additive manufacturing Ti–6Al–4V components , 2016 .

[30]  Sanjooram Paddea,et al.  Fatigue crack propagation behaviour in wire+arc additive manufactured Ti‐6Al‐4V: Effects of microstructure and residual stress , 2016 .

[31]  Yang Ren,et al.  In-situ investigation of stress-induced martensitic transformation in Ti–Nb binary alloys with low Young's modulus , 2016 .

[32]  A. Foroozmehr,et al.  Finite Element Simulation of Selective Laser Melting process considering Optical Penetration Depth of laser in powder bed , 2016 .

[33]  Brent Stucker,et al.  Influence of Defects on Mechanical Properties of Ti-6Al-4V Components Produced by Selective Laser Melting and Electron Beam Melting , 2015 .

[34]  Johanna Senatore,et al.  The effect of roughness and residual stresses on fatigue life time of an alloy of titanium , 2015 .

[35]  E. A. Payzant,et al.  Comparison of Residual Stresses in Inconel 718 Simple Parts Made by Electron Beam Melting and Direct Laser Metal Sintering , 2015, Metallurgical and Materials Transactions A.

[36]  Yuebin Guo,et al.  Three-Dimensional Temperature Gradient Mechanism in Selective Laser Melting of Ti-6Al-4V , 2014 .

[37]  A. T. Sidambe,et al.  Biocompatibility of Advanced Manufactured Titanium Implants—A Review , 2014, Materials.

[38]  D. Gu,et al.  Parametric analysis of thermal behavior during selective laser melting additive manufacturing of aluminum alloy powder , 2014 .

[39]  W. King,et al.  An Experimental Investigation into Additive Manufacturing-Induced Residual Stresses in 316L Stainless Steel , 2014, Metallurgical and Materials Transactions A.

[40]  M. Ramulu,et al.  Fatigue performance evaluation of selective laser melted Ti–6Al–4V , 2014 .

[41]  I. Yadroitsava,et al.  Selective laser melting of Ti6Al4V alloy for biomedical applications: Temperature monitoring and microstructural evolution , 2014 .

[42]  H. Maier,et al.  On the mechanical behaviour of titanium alloy TiAl6V4 manufactured by selective laser melting: Fatigue resistance and crack growth performance , 2013 .

[43]  K. Hagihara,et al.  Biocompatible low Young's modulus achieved by strong crystallographic elastic anisotropy in Ti-15Mo-5Zr-3Al alloy single crystal. , 2012, Journal of the mechanical behavior of biomedical materials.

[44]  J. Kruth,et al.  Assessing and comparing influencing factors of residual stresses in selective laser melting using a novel analysis method , 2012 .

[45]  Michele Dassisti,et al.  Methods of measuring residual stresses in components , 2012 .

[46]  Ulrich Dahmen,et al.  Atomic-resolution imaging with a sub-50-pm electron probe. , 2009, Physical review letters.

[47]  G. Brey,et al.  The iron oxidation state of garnet by electron microprobe: Its determination with the flank method combined with major-element analysis , 2007 .

[48]  H. Hosoda,et al.  Anisotropy and Temperature Dependence of Young’s Modulus in Textured TiNbAl Biomedical Shape Memory Alloy , 2005 .

[49]  David K. Aspinwall,et al.  The effect of machined topography and integrity on fatigue life , 2004 .

[50]  M. Saigo,et al.  High-precision parallel-beam X-ray system for high-temperature diffraction studies , 2002, Powder Diffraction.

[51]  W. Boettinger,et al.  Phase transformations in the (Ti, Al)3 Nb section of the TiAlNb system—I. Microstructural predictions based on a subgroup relation between phases , 1994 .

[52]  D. Bish,et al.  Quantitative phase analysis using the Rietveld method , 1988 .

[53]  G. S. Pawley,et al.  Unit-cell refinement from powder diffraction scans , 1981 .

[54]  E. Fisher,et al.  Relation of the c′ elastic modulus to stability of b.c.c. transition metals , 1970 .

[55]  Dale Yoder Book Review:Governmental Adjustment of Labor Disputes Howard S. Kaltenborn , 1945 .

[56]  Gerald L. Knapp,et al.  Experiments and simulations on solidification microstructure for Inconel 718 in powder bed fusion electron beam additive manufacturing , 2019, Additive Manufacturing.

[57]  D. Dimitrov,et al.  Influence of process parameters on residual stress related distortions in selective laser melting , 2018 .

[58]  Yuebin Guo,et al.  Residual Stress in Metal Additive Manufacturing , 2018 .

[59]  T. Niendorf,et al.  Fatigue life of additively manufactured Ti–6Al–4V in the very high cycle fatigue regime , 2017 .

[60]  Michael Schmidt,et al.  Laser based additive manufacturing in industry and academia , 2017 .

[61]  Theo Rickert,et al.  Residual Stress Measurement by ESPI Hole-Drilling☆ , 2016 .

[62]  K. Hagihara,et al.  Elastic-modulus enhancement during room-temperature aging and its suppression in metastable Ti–Nb-Based alloys with low body-centered cubic phase stability , 2016 .

[63]  Pan Michaleris,et al.  Effect of inter-layer dwell time on distortion and residual stress in additive manufacturing of titanium and nickel alloys , 2015 .

[64]  L. Huanxin,et al.  Nondestructive Testing Residual Stress Using Ultrasonic Critical Refracted Longitudinal Wave , 2015 .

[65]  Ryan R. Dehoff,et al.  Neutron Characterization for Additive Manufacturing , 2013 .

[66]  Philip J. Potts,et al.  A handbook of silicate rock analysis , 1987 .

[67]  J. I. Langford,et al.  Some applications of pattern fitting to powder diffraction data , 1987 .