Low- and high-cycle fatigue resistance of Ti-6Al-4V ELI additively manufactured via selective laser melting: Mean stress and defect sensitivity

[1]  R. Boyer An overview on the use of titanium in the aerospace industry , 1996 .

[2]  Ming-Chuan Leu,et al.  Progress in Additive Manufacturing and Rapid Prototyping , 1998 .

[3]  G. Lütjering Influence of processing on microstructure and mechanical properties of (α+β) titanium alloys , 1998 .

[4]  Stefano Beretta,et al.  STATISTICAL ANALYSIS OF DEFECTS FOR FATIGUE STRENGTH PREDICTION AND QUALITY CONTROL OF MATERIALS , 1998 .

[5]  Y. Murakami Metal Fatigue: Effects of Small Defects and Nonmetallic Inclusions , 2002 .

[6]  Gideon Levy,et al.  RAPID MANUFACTURING AND RAPID TOOLING WITH LAYER MANUFACTURING (LM) TECHNOLOGIES, STATE OF THE ART AND FUTURE PERSPECTIVES , 2003 .

[7]  Isabelle Monnet,et al.  Cyclically induced softening due to low-angle boundary annihilation in a martensitic steel , 2005 .

[8]  M. Benedetti,et al.  Influence of sharp microstructural gradients on the fatigue crack growth resistance of α+β and near-α titanium alloys , 2005 .

[9]  J. Kruth,et al.  Selective laser melting of biocompatible metals for rapid manufacturing of medical parts , 2006 .

[10]  Kiyoshi Tajima,et al.  Electropolishing of CP titanium and its alloys in an alcoholic solution-based electrolyte. , 2008, Dental materials journal.

[11]  L. Murr,et al.  Microstructure and mechanical behavior of Ti-6Al-4V produced by rapid-layer manufacturing, for biomedical applications. , 2009, Journal of the mechanical behavior of biomedical materials.

[12]  L. Murr,et al.  Next-generation biomedical implants using additive manufacturing of complex, cellular and functional mesh arrays , 2010, Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[13]  Vigilio Fontanari,et al.  Numerical Simulation of Residual Stress Relaxation in Shot Peened High-Strength Aluminum Alloys Under Reverse Bending Fatigue , 2010 .

[14]  J. Kruth,et al.  A study of the microstructural evolution during selective laser melting of Ti–6Al–4V , 2010 .

[15]  H. Maier,et al.  In situ characterization of the deformation and failure behavior of non-stochastic porous structures processed by selective laser melting , 2011 .

[16]  C. Colin,et al.  As-Fabricated and Heat-Treated Microstructures of the Ti-6Al-4V Alloy Processed by Selective Laser Melting , 2011 .

[17]  Vittorio Alfieri,et al.  Experimental analysis of selective laser melting process for Ti-6Al-4V turbine blade manufacturing , 2013, Other Conferences.

[18]  A. A. Zadpoor,et al.  Mechanical properties of open-cell metallic biomaterials manufactured using additive manufacturing , 2013 .

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

[20]  Mamidala Ramulu,et al.  Electron Beam Additive Manufacturing of Titanium Components: Properties and Performance , 2013 .

[21]  William E. Frazier,et al.  Metal Additive Manufacturing: A Review , 2014, Journal of Materials Engineering and Performance.

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

[23]  F. Froes,et al.  The Additive Manufacturing (AM) of Titanium Alloys , 2014 .

[24]  Frank Walther,et al.  Effects of Defects in Laser Additive Manufactured Ti-6Al-4V on Fatigue Properties , 2014 .

[25]  S. Sun,et al.  The Effect of Manufacturing Defects on the Fatigue Behaviour of Ti-6Al-4V Specimens Fabricated Using Selective Laser Melting , 2014 .

[26]  Thomas Tröster,et al.  On the fatigue properties of metals manufactured by selective laser melting — The role of ductility , 2014 .

[27]  Ma Qian,et al.  Additive manufacturing of strong and ductile Ti–6Al–4V by selective laser melting via in situ martensite decomposition , 2015 .

[28]  X. Gómez,et al.  Elastic behaviour characterisation of TRIP 700 steel by means of loading–unloading tests , 2015 .

[29]  Galina Kasperovich,et al.  Improvement of fatigue resistance and ductility of TiAl6V4 processed by selective laser melting , 2015 .

[30]  B. Oberwinkler On the anomalous mean stress sensitivity of Ti-6Al-4V and its consideration in high cycle fatigue lifetime analysis , 2016 .

[31]  Vigilio Fontanari,et al.  On the combination of the critical distance theory with a multiaxial fatigue criterion for predicting the fatigue strength of notched and plain shot-peened parts , 2016 .

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

[33]  Filippo Zanini,et al.  Porosity testing methods for the quality assessment of selective laser melted parts , 2016 .

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

[35]  M. Benedetti,et al.  Fatigue and Fracture Resistance of Heavy-Section Ferritic Ductile Cast Iron , 2017 .

[36]  Tobias Melz,et al.  Fatigue performance of additive manufactured TiAl6V4 using electron and laser beam melting , 2017 .

[37]  M. Benedetti,et al.  The effect of post-sintering treatments on the fatigue and biological behavior of Ti-6Al-4V ELI parts made by selective laser melting. , 2017, Journal of the mechanical behavior of biomedical materials.

[38]  Gianni Nicoletto,et al.  Anisotropic high cycle fatigue behavior of Ti–6Al–4V obtained by powder bed laser fusion , 2017 .

[39]  Steven Y. Liang,et al.  Analytical modelling of residual stress in additive manufacturing , 2017 .

[40]  S. Beretta,et al.  A comparison of fatigue strength sensitivity to defects for materials manufactured by AM or traditional processes , 2017 .

[41]  M. Benedetti,et al.  Low and high‐cycle fatigue properties of an ultrahigh‐strength TRIP bainitic steel , 2017 .