Characterization of bending vibration fatigue of SLM fabricated Ti-6Al-4V

Abstract Additive Manufacturing (AM) is a novel process that promises an increased efficiency in material use, while allowing the production of advanced topologies and the seamless integration of inner cavities and pathways without the use of complex tooling. As of now, little work has been done on the fatigue performance of these materials. Concurrently, an interest in understanding fatigue behavior specific to turbine and compressor blades has been expressed by original equipment manufacturers. This type of fatigue loading is characterized by high frequency, short wavelength stress states as well as mixed mode loading. It has been found that conventional fatigue data are inadequate in representing this type of fatigue loading. In response, a vibration-based fatigue technique has presented itself as a viable alternative. In this work, the vibration-based fatigue behavior of Ti-6Al-4V is studied in an effort to address the use of AM for the production of compressor parts. Samples produced by Selective Laser Melting (SLM) are cycled in the first bending mode to quantify the average stress amplitude at failure for 107 cycles using the Dixon-Mood staircase method. Subsequent fractography and statistical analysis are used to determine the dominant failure mechanisms and the effect of chosen variables, respectively. The effect of the build direction and post-build heat treatment are examined. Lastly, 3D laser vibrometry data are used to critically assess the vibration test method relative to AM materials. The study concludes that fatigue life can be greatly increased by a Hot Isostatic Pressing (HIP) treatment, even surpassing wrought alloy performance, and that build direction has a significant effect on fatigue performance. Also, the vibrometry data indicate that AM and conventional materials present similar modal behavior.

[1]  Christoph Leyens,et al.  Deposition of Ti–6Al–4V using laser and wire, part I: Microstructural properties of single beads , 2011 .

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

[3]  Y. Furuya,et al.  The effect of frequency on the giga‐cycle fatigue properties of a Ti–6Al–4V alloy , 2008 .

[4]  J. Hall Fatigue crack initiation in alpha-beta titanium alloys , 1997 .

[5]  Gun Jin Yun,et al.  Development of a Closed-Loop High-Cycle Resonant Fatigue Testing System , 2012 .

[6]  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 .

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

[8]  Joseph A. Beck,et al.  Fatigue and Strength Studies of Titanium 6Al–4V Fabricated by Direct Metal Laser Sintering , 2016 .

[9]  S. Suresh Fatigue of materials , 1991 .

[10]  Steve Vanlanduit,et al.  Optical measurement of the dynamic strain field of a fan blade using a 3D scanning vibrometer , 2011 .

[11]  Jeremy D. Seidt,et al.  Development of a novel vibration based high cycle fatigue test method , 2001 .

[12]  Fude Wang Mechanical property study on rapid additive layer manufacture Hastelloy® X alloy by selective laser melting technology , 2012 .

[13]  J. Mei,et al.  Microstructure study of direct laser fabricated Ti alloys using powder and wire , 2006 .

[14]  Christoph Leyens,et al.  Morphology, microstructure, and hardness of titanium (Ti-6Al-4V) blocks deposited by wire-feed additive layer manufacturing (ALM) , 2012 .

[15]  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 .

[16]  Nima Shamsaei,et al.  Fatigue behavior and failure mechanisms of direct laser deposited Ti–6Al–4V , 2016 .

[17]  T. Nicholas Tensile testing of materials at high rates of strain , 1981 .

[18]  Jeremy D. Seidt,et al.  Development of a novel vibration-based fatigue testing methodology , 2004 .

[19]  Brent Stucker,et al.  Analysis of defect generation in Ti–6Al–4V parts made using powder bed fusion additive manufacturing processes , 2014 .

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

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

[22]  E. M. Lui,et al.  Fatigue and Fracture , 2005 .

[23]  S. Kelly,et al.  Microstructural evolution in laser-deposited multilayer Ti-6Al-4V builds: Part I. Microstructural characterization , 2004 .

[24]  Randall D. Pollak,et al.  Analysis of Methods for Determining High Cycle Fatigue Strength of a Material With Investigation of Ti-6Al-4V Gigacycle Fatigue Behavior , 2005 .

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

[26]  Alexander M. Mood,et al.  A Method for Obtaining and Analyzing Sensitivity Data , 1948 .

[27]  Yun-Che Wang,et al.  Mechanical Fatigue Measurement via a Vibrating Cantilever Beam for Self-Supported Thin Solid Films , 2006 .

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

[29]  L. Murr,et al.  Metal Fabrication by Additive Manufacturing Using Laser and Electron Beam Melting Technologies , 2012 .

[30]  David L. McDowell,et al.  Frequency and stress ratio effects in high cycle fatigue of Ti-6Al-4V , 1999 .

[31]  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 .

[32]  Influence of Build Direction on the Fatigue Behaviour of Ti6Al4V Alloy Produced by Direct Metal Laser Sintering , 2016 .

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

[34]  F. Walther,et al.  Fatigue Performance of Laser Additive Manufactured Ti–6Al–4V in Very High Cycle Fatigue Regime up to 109 Cycles , 2015, Front. Mater..

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

[36]  Joseph A. Beck,et al.  Material Property Determination of Vibration Fatigued DMLS and Cold-Rolled Nickel Alloys , 2014 .

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

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