A Novel Physics-Based and Data-Supported Microstructure Model for Part-Scale Simulation of Ti-6Al-4V Selective Laser Melting

The elasto-plastic material behavior, material strength and failure modes of metals fabricated by additive manufacturing technologies are significantly determined by the underlying process-specific microstructure evolution. In this work a novel physics-based and data-supported phenomenological microstructure model for Ti-6Al-4V is proposed that is suitable for the part-scale simulation of selective laser melting processes. The model predicts spatially homogenized phase fractions of the most relevant microstructural species, namely the stable $\beta$-phase, the stable $\alpha_{\text{s}}$-phase as well as the metastable Martensite $\alpha_{\text{m}}$-phase, in a physically consistent manner. In particular, the modeled microstructure evolution, in form of diffusion-based and non-diffusional transformations, is a pure consequence of energy and mobility competitions among the different specifies, without the need for heuristic transformation criteria as often applied in existing models. The mathematically consistent formulation of the evolution equations in rate form renders the model suitable for the practically relevant scenario of temperature- or time-dependent diffusion coefficients, arbitrary temperature profiles, and multiple coexisting phases. Due to its physically motivated foundation, the proposed model requires only a minimal number of free parameters, which are determined in an inverse identification process considering a broad experimental data basis in form of time-temperature transformation diagrams. Subsequently, the predictive ability of the model is demonstrated by means of continuous cooling transformation diagrams, showing that experimentally observed characteristics such as critical cooling rates emerge naturally from the proposed microstructure model, instead of being enforced as heuristic transformation criteria.

[1]  R. M. Ferencz,et al.  Experimental comparison of residual stresses for a thermomechanical model for the simulation of selective laser melting , 2016 .

[2]  M. Grujicic,et al.  Computer simulations of the evolution of solidification microstructure in the LENS™ rapid fabrication process , 2001 .

[3]  Gabriel Bugeda Miguel Cervera,et al.  Numerical prediction of temperature and density distributions in selective laser sintering processes , 1999 .

[4]  R. Pederson,et al.  A model for Ti–6Al–4V microstructure evolution for arbitrary temperature changes , 2012 .

[5]  J. Newkirk,et al.  The Jominy end quench for light-weight alloy development , 2000 .

[6]  Z. Guo,et al.  Resistivity study and computer modelling of the isothermal transformation kinetics of Ti–6Al–4V and Ti–6Al–2Sn–4Zr–2Mo–0.08Si alloys , 2001 .

[7]  N. S. Reddy,et al.  Prediction of flow stress in Ti–6Al–4V alloy with an equiaxed α + β microstructure by artificial neural networks , 2008 .

[8]  Wolfgang A. Wall,et al.  A Generalized Probabilistic Learning Approach for Multi-Fidelity Uncertainty Propagation in Complex Physical Simulations , 2020, ArXiv.

[9]  S. Semiatin,et al.  Introduction to Fundamentals of Modeling for Metals Processing , 2009 .

[10]  O. Ojo,et al.  Numerical modeling of microstructure evolution during laser additive manufacturing of a nickel-based superalloy , 2014 .

[11]  Matthias Markl,et al.  A coupled Cellular Automaton–Lattice Boltzmann model for grain structure simulation during additive manufacturing , 2016 .

[12]  Hugh Shercliff,et al.  Microstructural modelling in metals processing , 2002 .

[13]  H. J. Rack,et al.  Phase transformations during cooling in α+β titanium alloys , 1998 .

[14]  Ernst Rank,et al.  A hierarchical computational model for moving thermal loads and phase changes with applications to selective laser melting , 2017, Comput. Math. Appl..

[15]  Grain topology in Ti–6Al–4V welds—Monte Carlo simulation and experiments , 2004 .

[16]  T. DebRoy,et al.  Three dimensional Monte Carlo simulation of grain growth during GTA welding of titanium , 2000 .

[17]  Alessandro Reali,et al.  Accurate Prediction of Melt Pool Shapes in Laser Powder Bed Fusion by the Non-Linear Temperature Equation Including Phase Changes , 2019, Integrating Materials and Manufacturing Innovation.

[18]  Frank W. Liou,et al.  Probabilistic Simulation of Solidification Microstructure Evolution During Laser-based Metal Deposition , 2013 .

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

[20]  Sebastian D. Proell,et al.  On phase change and latent heat models in metal additive manufacturing process simulation , 2019, Advanced Modeling and Simulation in Engineering Sciences.

[21]  M. Shephard,et al.  Heat transfer model and finite element formulation for simulation of selective laser melting , 2018 .

[22]  Zhengxiao Guo,et al.  Microstructural evolution of a Ti–6Al–4V alloy during β-phase processing: experimental and simulative investigations , 2004 .

[23]  A. Crespo,et al.  Modelling of Heat Transfer and Phase Transformations in the Rapid Manufacturing of Titanium Components , 2011 .

[24]  P. Cochat,et al.  Et al , 2008, Archives de pediatrie : organe officiel de la Societe francaise de pediatrie.

[25]  G. Meyrick,et al.  Phase Transformations in Metals and Alloys , 1973 .

[26]  Sarma B Gorti,et al.  Phase Field Simulations of Autocatalytic Formation of Alpha Lamellar Colonies in Ti-6Al-4V , 2016, Metallurgical and Materials Transactions A.

[27]  Zemin Wang,et al.  Formation and control of martensite in Ti-6Al-4V alloy produced by selective laser melting , 2016 .

[28]  Paul Steinmann,et al.  Macroscopic simulation and experimental measurement of melt pool characteristics in selective electron beam melting of Ti-6Al-4V , 2017 .

[29]  G. Welsch,et al.  Young's modulus and damping of Ti6Al4V alloy as a function of heat treatment and oxygen concentration , 1990 .

[30]  N. Hodge,et al.  Towards improved speed and accuracy of laser powder bed fusion simulations via representation of multiple time scales , 2020 .

[31]  Wolfgang A. Wall,et al.  A computational approach for thermo-elasto-plastic frictional contact based on a monolithic formulation using non-smooth nonlinear complementarity functions , 2018, Adv. Model. Simul. Eng. Sci..

[32]  P. Åkerfeldt,et al.  Temperature and Microstructure Evolution in Gas Tungsten Arc Welding Wire Feed Additive Manufacturing of Ti-6Al-4V , 2019, Materials.

[33]  Pan Michaleris,et al.  Thermomechanical Modeling of Additive Manufacturing Large Parts , 2014 .

[34]  Jaimie Tiley,et al.  Modeling the tensile properties in β-processed α/β Ti alloys , 2006 .

[35]  Michael F. Zäh,et al.  Investigations on residual stresses and deformations in selective laser melting , 2010, Prod. Eng..

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

[37]  Xibing Gong,et al.  Phase-Field Modeling of Microstructure Evolution in Electron Beam Additive Manufacturing , 2015 .

[38]  Sean F. Wu 2002 ASME International Mechanical Engineering Congress and Exposition , 2003 .

[39]  Jerome Solberg,et al.  Implementation of a thermomechanical model for the simulation of selective laser melting , 2014 .

[40]  Boris Wilthan,et al.  Thermophysical Properties of Solid and Liquid Ti-6Al-4V (TA6V) Alloy , 2006 .

[41]  Yu Zou,et al.  Thermophysical Phenomena in Metal Additive Manufacturing by Selective Laser Melting: Fundamentals, Modeling, Simulation and Experimentation , 2017, ArXiv.

[42]  I. Yadroitsev,et al.  Heat transfer modelling and stability analysis of selective laser melting , 2007 .

[43]  Wei Zhang,et al.  Phase transformation dynamics during welding of Ti–6Al–4V , 2004 .

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

[45]  D. Hoemberg A numerical simulation of the Jominy end-quench test , 1996 .

[46]  A. Wilson,et al.  Differential scanning calorimetry study and computer modeling of β ⇒ α phase transformation in a Ti-6Al-4V alloy , 2001 .

[47]  Ninggang Shen,et al.  NUMERICAL THERMAL ANALYSIS IN ELECTRON BEAM ADDITIVE MANUFACTURING WITH PREHEATING EFFECTS , 2012 .

[48]  D. Dye,et al.  Effect of texture on load partitioning in Ti-6Al-4V , 2012 .

[49]  J. Rońda,et al.  Consistent thermo-mechano-metallurgical model of welded steel with unified approach to derivation of phase evolution laws and transformation-induced plasticity , 2000 .

[50]  Michel Bellet,et al.  Macroscopic thermal finite element modeling of additive metal manufacturing by selective laser melting process , 2018 .

[51]  Rishi Ganeriwala,et al.  Towards improved speed and accuracy of laser powder bed fusion simulations via multiscale spatial representations , 2021 .

[52]  G. Welsch,et al.  Elastic moduli and tensile and physical properties of heat-treated and quenched powder metallurgical Ti-6Al-4V alloy , 1991 .

[53]  J. K. Gillham,et al.  Time–temperature–transformation (TTT) cure diagram: Modeling the cure behavior of thermosets , 1983 .

[54]  J. J. Moré,et al.  Levenberg--Marquardt algorithm: implementation and theory , 1977 .

[55]  Santiago Badia,et al.  A scalable parallel finite element framework for growing geometries. Application to metal additive manufacturing , 2018, International Journal for Numerical Methods in Engineering.

[56]  Miguel Cervera,et al.  Modeling of Microstructure Evolution of Ti6Al4V for Additive Manufacturing , 2018, Metals.

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

[58]  A. Nassar,et al.  Predicting Microstructure from Thermal History during Additive Manufacturing for Ti-6Al-4V , 2016 .

[59]  Wei Sha,et al.  Application of artificial neural network for prediction of time-temperature-transformation diagrams in titanium alloys , 2000 .

[60]  I. Avramov,et al.  Generalized kinetics of overall phase transition explicit to crystallization , 2014, Journal of Thermal Analysis and Calorimetry.

[61]  John W. Cahn,et al.  Transformation kinetics during continuous cooling , 1956 .

[62]  Andreas Menzel,et al.  Towards the simulation of Selective Laser Melting processes via phase transformation models , 2019, Comput. Math. Appl..

[63]  Z. Yang,et al.  Effect of phase transformations on laser forming of Ti-6Al-4V alloy , 2005 .

[64]  S. Kelly Thermal and Microstructure Modeling of Metal Deposition Processes with Application to Ti-6Al-4V , 2004 .

[65]  J. Andersson,et al.  Simulation of additive manufacturing using coupled constitutive and microstructure models , 2016 .

[66]  W. Sha,et al.  Finite element modeling of the morphology of β to α phase transformation in Ti-6Al-4V alloy , 2002 .

[67]  D. P. Koistinen,et al.  A general equation prescribing the extent of the austenite-martensite transformation in pure iron-carbon alloys and plain carbon steels , 1959 .

[68]  Yunzhi Wang,et al.  Quantitative phase field modeling of diffusion-controlled precipitate growth and dissolution in Ti–Al–V , 2004 .

[69]  R. Pederson,et al.  Use of high temperature X-ray diffractometry to study phase transitions and thermal expansion properties in Ti-6Al-4V , 2003 .

[70]  C. C. Murgau Microstructure model for Ti-6Al-4V used in simulation of additive manufacturing , 2016 .

[71]  A. Menzel,et al.  A computational phase transformation model for selective laser melting processes , 2020, Computational Mechanics.

[72]  Julia Mergheim,et al.  Numerical microstructure prediction by a coupled finite element cellular automaton model for selective electron beam melting , 2019, Computational Materials Science.

[73]  S. Kelly,et al.  Microstructural evolution in laser-deposited multilayer Ti-6Al-4V builds: Part II. Thermal modeling , 2004 .

[74]  C. Chua,et al.  Geometry dependence of microstructure and microhardness for selective electron beam-melted Ti–6Al–4V parts , 2016 .

[75]  H. Bhadeshia,et al.  Thermodynamic analysis of isothermal transformation diagrams , 1982 .

[76]  W. Rae,et al.  Thermo-metallo-mechanical modelling of heat treatment induced residual stress in Ti–6Al–4V alloy , 2019, Materials Science and Technology.

[77]  T. Childs,et al.  Selective laser sintering (melting) of stainless and tool steel powders: Experiments and modelling , 2005 .