Critical assessment of the fatigue performance of additively manufactured Ti–6Al–4V and perspective for future research

Abstract To realize the potential benefits of additive manufacturing technology in airframe and ground vehicle applications, the fatigue performance of load bearing additively manufactured materials must be understood. Due to the novelty of this rapidly developing technology, a very limited, yet swiftly evolving literature exists on the topic. Motivated by these two points, we have attempted to catalog and analyze the published fatigue performance data of an additively manufactured alloy of significant technological interest, Ti–6Al–4V. Focusing on uniaxial fatigue performance, we compare to traditionally manufactured Ti–6Al–4V, discussing failure mechanisms, defects, microstructure, and processing parameters. We then attempt to identify key knowledge gaps that must be addressed before AM technology can safely and effectively be employed in critical load bearing applications.

[1]  Omer Van der Biest,et al.  Wire based additive layer manufacturing: Comparison of microstructure and mechanical properties of Ti–6Al–4V components fabricated by laser-beam deposition and shaped metal deposition , 2011 .

[2]  S. Sun,et al.  Ti-6Al-4V Additively Manufactured by Selective Laser Melting with Superior Mechanical Properties , 2015 .

[3]  Fatigue Life of Selective Laser Melted and Hot Isostatically Pressed Ti-6Al-4v Absent of Surface Machining , 2015 .

[4]  Christoph Leyens,et al.  Additive manufactured Ti-6Al-4V using welding wire: comparison of laser and arc beam deposition and evaluation with respect to aerospace material specifications , 2010 .

[5]  R. Ritchie,et al.  Influence of microstructure on high-cycle fatigue of Ti-6Al-4V: Bimodal vs. lamellar structures , 2002 .

[6]  Ma Qian,et al.  Effect of Powder Reuse Times on Additive Manufacturing of Ti-6Al-4V by Selective Electron Beam Melting , 2015 .

[7]  Thomas Tröster,et al.  Fatigue Strength Prediction for Titanium Alloy TiAl6V4 Manufactured by Selective Laser Melting , 2015, Metallurgical and Materials Transactions A.

[8]  J. Planell,et al.  Influence of tempering temperature and time on the α′-Ti-6Al-4V martensite , 1996 .

[9]  C. Rodopoulos,et al.  On the use of supersonic particle deposition to restore the structural integrity of damaged aircraft structures , 2011 .

[10]  J. Kruth,et al.  On the determination of fatigue properties of Ti6Al4V produced by selective laser melting , 2012 .

[11]  Ryan B. Wicker,et al.  Effect of Melt Scan Rate on Microstructure and Macrostructure for Electron Beam Melting of Ti-6Al-4V , 2012 .

[12]  A. Dehghan-Manshadi,et al.  Development of α-phase morphologies during low temperature isothermal heat treatment of a Ti–5Al–5Mo–5V–3Cr alloy , 2011 .

[13]  D. Eylon Fatigue crack initiation in hot isostatically pressed Ti-6Al-4V castings , 1979 .

[14]  Ryan B. Wicker,et al.  Microstructures and mechanical properties of electron beam-rapid manufactured Ti–6Al–4V biomedical prototypes compared to wrought Ti–6Al–4V , 2009 .

[15]  Ryan B. Wicker,et al.  Characterization of titanium aluminide alloy components fabricated by additive manufacturing using electron beam melting , 2010 .

[16]  Kevin D Rekedal,et al.  Investigation of the High-Cycle Fatigue Life of Selective Laser Melted and Hot Isostatically Pressed Ti-6Al-4v , 2015 .

[17]  P. Colegrove,et al.  Microstructure and Mechanical Properties of Wire and Arc Additive Manufactured Ti-6Al-4V , 2013, Metallurgical and Materials Transactions A.

[18]  C. Ju,et al.  A comparison of the fatigue behavior of cast Ti-7.5Mo with c.p. titanium, Ti-6Al-4V and Ti-13Nb-13Zr alloys. , 2005, Biomaterials.

[19]  D. Eylon,et al.  Fatigue crack initiation in Ti-6wt % Al-4 wt % V castings , 1979 .

[20]  Konrad Wissenbach,et al.  Ductility of a Ti‐6Al‐4V alloy produced by selective laser melting of prealloyed powders , 2010 .

[21]  Robert L. Mason,et al.  Fatigue Life of Titanium Alloys Fabricated by Additive Layer Manufacturing Techniques for Dental Implants , 2013, Metallurgical and Materials Transactions A.

[22]  B. Stucker,et al.  A comparison of the tensile, fatigue, and fracture behavior of Ti–6Al–4V and 15-5 PH stainless steel parts made by selective laser melting , 2013 .

[23]  E. Abele,et al.  Fatigue Analysis in Selective Laser Melting: Review and Investigation of Thin-walled Actuator Housings , 2014 .

[24]  O. Lyckfeldt,et al.  Characterization and Control of Powder Properties for Additive Manufacturing , 2015 .

[25]  B. Stucker,et al.  Microstructures and Mechanical Properties of Ti6Al4V Parts Fabricated by Selective Laser Melting and Electron Beam Melting , 2013, Journal of Materials Engineering and Performance.

[26]  Todd M. Mower,et al.  Degradation of titanium 6Al–4V fatigue strength due to electrical discharge machining , 2014 .

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

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

[29]  Kamran Mumtaz,et al.  Top surface and side roughness of Inconel 625 parts processed using selective laser melting , 2009 .

[30]  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.

[31]  Brent Stucker,et al.  An Integrated Approach to Additive Manufacturing Simulations Using Physics Based, Coupled Multiscale Process Modeling , 2014 .

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

[33]  Nack J. Kim,et al.  Effects of thickness on fatigue properties of investment cast Ti-6Al-4V alloy plates , 2004 .

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

[35]  Bo Song,et al.  Effects of processing parameters on microstructure and mechanical property of selective laser melted Ti6Al4V , 2012 .

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

[37]  Patrick J. Golden,et al.  Investigation of variability in fatigue crack nucleation and propagation in alpha+beta Ti-6Al-4V , 2010 .

[38]  M. Donachie Titanium: A Technical Guide , 1988 .

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

[40]  Sara M. Gaytan,et al.  Evaluation of Titanium Alloys Fabricated Using Rapid Prototyping Technologies—Electron Beam Melting and Laser Beam Melting , 2011, Materials.

[41]  Jean-Pierre Kruth,et al.  Analysis of Fracture Toughness and Crack Propagation of Ti6Al4V Produced by Selective Laser Melting , 2012 .

[42]  K. Walker The Effect of Stress Ratio During Crack Propagation and Fatigue for 2024-T3 and 7075-T6 Aluminum , 1970 .

[43]  J. Kruth,et al.  Residual stresses in selective laser sintering and selective laser melting , 2006 .

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

[45]  Christoph Leyens,et al.  Mechanical Properties of Additive Manufactured Ti-6Al-4V Using Wire and Powder Based Processes , 2011 .

[46]  Philip B. Prangnell,et al.  Effect of build geometry on the β-grain structure and texture in additive manufacture of Ti6Al4V by selective electron beam melting , 2013 .

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

[48]  H. Gu,et al.  Effects of Powder Variation on the Microstructure and Tensile Strength of Ti6Al4V Parts Fabricated by Selective Laser Melting , 2015 .

[49]  H. O. Fuchs,et al.  Metal fatigue in engineering , 2001 .

[50]  F. Walther,et al.  High Cycle Fatigue (HCF) Performance of Ti-6Al-4V Alloy Processed by Selective Laser Melting , 2013 .

[51]  Ali Fatemi,et al.  Multiaxial fatigue: An overview and some approximation models for life estimation , 2011 .

[52]  T. C. Lindley,et al.  The role of microtexture on the faceted fracture morphology in Ti–6Al–4V subjected to high-cycle fatigue , 2010 .

[53]  K. Ridgway,et al.  Preliminary Empirical Models for Predicting Shrinkage, Part Geometry and Metallurgical Aspects of Ti-6Al-4V Shaped Metal Deposition Builds , 2011 .

[54]  John J. Lewandowski,et al.  Evaluation of Orientation Dependence of Fracture Toughness and Fatigue Crack Propagation Behavior of As-Deposited ARCAM EBM Ti-6Al-4V , 2015 .

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

[56]  Lorrie Molent,et al.  Supersonic particle deposition as a means for enhancing the structural integrity of aircraft structures , 2014 .

[57]  T. Tom,et al.  Titanium investment castings , 2002 .

[58]  E. Reutzel,et al.  Thermo-mechanical model development and validation of directed energy deposition additive manufacturing of Ti–6Al–4V , 2015 .

[59]  Matthew Roy,et al.  High Pressure Interpass Rolling of Wire + Arc Additively Manufactured Titanium Components , 2014 .

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

[61]  V. Champagne,et al.  Critical Assessment 11: Structural repairs by cold spray , 2015 .

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