Analytical Modeling of In-Process Temperature in Powder Bed Additive Manufacturing Considering Laser Power Absorption, Latent Heat, Scanning Strategy, and Powder Packing

Temperature distribution gradient in metal powder bed additive manufacturing (MPBAM) directly controls the mechanical properties and dimensional accuracy of the build part. Experimental approach and numerical modeling approach for temperature in MPBAM are limited by the restricted accessibility and high computational cost, respectively. Analytical models were reported with high computational efficiency, but the developed models employed a moving coordinate and semi-infinite medium assumption, which neglected the part dimensions, and thus reduced their usefulness in real applications. This paper investigates the in-process temperature in MPBAM through analytical modeling using a stationary coordinate with an origin at the part boundary (absolute coordinate). Analytical solutions are developed for temperature prediction of single-track scan and multi-track scans considering scanning strategy. Inconel 625 is chosen to test the proposed model. Laser power absorption is inversely identified with the prediction of molten pool dimensions. Latent heat is considered using the heat integration method. The molten pool evolution is investigated with respect to scanning time. The stabilized temperatures in the single-track scan and bidirectional scans are predicted under various process conditions. Close agreements are observed upon validation to the experimental values in the literature. Furthermore, a positive relationship between molten pool dimensions and powder packing porosity was observed through sensitivity analysis. With benefits of the absolute coordinate, and high computational efficiency, the presented model can predict the temperature for a dimensional part during MPBAM, which can be used to further investigate residual stress and distortion in real applications.

[1]  Norbert Pirch,et al.  Investigation on reducing distortion by preheating during manufacture of aluminum components using selective laser melting , 2014 .

[2]  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 .

[3]  K. Salonitis,et al.  Simulation of metallic powder bed additive manufacturing processes with the finite element method: A critical review , 2017 .

[4]  Pan Michaleris,et al.  Thermal modeling of Inconel 718 processed with powder bed fusion and experimental validation using in situ measurements , 2016 .

[5]  S. Liang,et al.  Predictive Modeling of Machining Temperatures with Force–Temperature Correlation Using Cutting Mechanics and Constitutive Relation , 2019, Materials.

[6]  D. Mynors,et al.  A three-dimensional finite element analysis of the temperature field during laser melting of metal powders in additive layer manufacturing , 2009 .

[7]  Anas Yaghi,et al.  Distortion prediction and compensation in selective laser melting , 2017 .

[8]  S. Liang,et al.  Analytical modeling of machining forces of ultra-fine-grained titanium , 2018, The International Journal of Advanced Manufacturing Technology.

[9]  D. Rosenthal,et al.  The Theory of Moving Sources of Heat and Its Application to Metal Treatments , 1946, Journal of Fluids Engineering.

[10]  Guanqun Yu,et al.  Porosity evolution and its thermodynamic mechanism of randomly packed powder-bed during selective laser melting of Inconel 718 alloy , 2017 .

[11]  P. Michaleris,et al.  Selection of powder or wire feedstock material for the laser cladding of Inconel® 625 , 2016 .

[12]  A. Rubenchik,et al.  Calculation of laser absorption by metal powders in additive manufacturing. , 2015, Applied optics.

[13]  S. Liang,et al.  Prediction of Temperature Distribution in Orthogonal Machining Based on the Mechanics of the Cutting Process Using a Constitutive Model , 2018, Journal of Manufacturing and Materials Processing.

[14]  Rémy Glardon,et al.  3D FE simulation for temperature evolution in the selective laser sintering process , 2004 .

[15]  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 .

[16]  Richard Leach,et al.  Review of in-situ process monitoring and in-situ metrology for metal additive manufacturing , 2016 .

[17]  Steven Y. Liang,et al.  Inverse determination of Johnson–Cook model constants of ultra-fine-grained titanium based on chip formation model and iterative gradient search , 2018, The International Journal of Advanced Manufacturing Technology.

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

[19]  Jean-Pierre Kruth,et al.  Advanced fatigue analysis of metal lattice structures produced by Selective Laser Melting CIRP Annals - Manufacturing Technology , 2017 .

[20]  K. Osakada,et al.  Residual Stress within Metallic Model Made by Selective Laser Melting Process , 2004 .

[21]  R. Poprawe,et al.  Laser additive manufacturing of metallic components: materials, processes and mechanisms , 2012 .

[22]  T. Özel,et al.  Sensitivity analysis of material and process parameters in finite element modeling of selective laser melting of Inconel 625 , 2016 .

[23]  L. Rosenhead Conduction of Heat in Solids , 1947, Nature.

[24]  K. Senthilkumaran,et al.  Numerical and experimental investigations on laser melting of stainless steel 316L metal powders , 2014 .

[25]  L. Shaw,et al.  Finite element analysis of the effect of volume shrinkage during laser densification , 2005 .

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

[27]  M. Bambach,et al.  Analytical and Numerical Temperature Prediction in Direct Metal Deposition of Ti6Al4V , 2017 .

[28]  Huan Qi,et al.  Numerical simulation of heat transfer and fluid flow in coaxial laser cladding process for direct metal deposition , 2006 .

[29]  Steven Y. Liang,et al.  Model-driven determination of Johnson-Cook material constants using temperature and force measurements , 2018 .

[30]  Brandon M. Lane,et al.  Laser powder bed fusion of nickel alloy 625: Experimental investigations of effects of process parameters on melt pool size and shape with spatter analysis , 2017 .

[31]  J. Chen,et al.  Process analysis for laser solid forming of thin-wall structure , 2010 .

[32]  Richard M. Everson,et al.  Finite element simulation of the temperature and stress fields in single layers built without-support in selective laser melting , 2013 .

[33]  Pei Wei,et al.  Forming and defect analysis for single track scanning in selective laser melting of Ti6Al4V , 2018, Applied Physics A.

[34]  Srinivasan Chandrasekar,et al.  Simulation of thermal stresses due to grinding , 2001 .

[35]  J. Kruth,et al.  Effects of build orientation and heat treatment on the microstructure and mechanical properties of selective laser melted Ti6Al4V lattice structures , 2015 .

[36]  Lai‐Chang Zhang,et al.  Improved corrosion behavior of ultrafine-grained eutectic Al-12Si alloy produced by selective laser melting , 2018 .

[37]  M. Baelmans,et al.  Solutions for modelling moving heat sources in a semi-infinite medium and applications to laser material processing , 2007 .

[38]  P. Michaleris,et al.  In situ monitoring and characterization of distortion during laser cladding of Inconel® 625 , 2015 .

[39]  D. Gu,et al.  Thermal behavior during selective laser melting of commercially pure titanium powder: Numerical simulation and experimental study , 2014 .

[40]  Alan T. Zehnder,et al.  Interface shear stresses induced by non-uniform heating of a film on a substrate , 1993 .

[41]  Pei Wei,et al.  Thermal behavior in single track during selective laser melting of AlSi10Mg powder , 2017 .

[42]  R. Fabbro,et al.  Analytical and numerical modelling of the direct metal deposition laser process , 2008 .

[43]  Yabin Yang,et al.  A semi-analytical thermal modelling approach for selective laser melting , 2018 .

[44]  Jean-Pierre Kruth,et al.  Determination of geometrical factors in Layerwise Laser Melting using optical process monitoring , 2011 .

[45]  Chee Kai Chua,et al.  Numerical investigation and an effective modelling on the Selective Laser Melting (SLM) process with aluminium alloy 6061 , 2015 .

[46]  G. Tapia,et al.  A Review on Process Monitoring and Control in Metal-Based Additive Manufacturing , 2014 .

[47]  Harry Bikas,et al.  Additive manufacturing methods and modelling approaches: a critical review , 2015, The International Journal of Advanced Manufacturing Technology.

[48]  Andrew J. Pinkerton,et al.  The significance of deposition point standoff variations in multiple-layer coaxial laser cladding (coaxial cladding standoff effects) , 2004 .

[49]  L. Ladani,et al.  Finite element simulation of laser additive melting and solidification of Inconel 718 with experimentally tested thermal properties , 2017 .

[50]  Jean-Pierre Kruth,et al.  In situ quality control of the selective laser melting process using a high-speed, real-time melt pool monitoring system , 2014 .

[51]  C. Kamath,et al.  A processing diagram for high-density Ti-6Al-4V by selective laser melting , 2018, Rapid Prototyping Journal.

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

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

[54]  Vinod Yadava,et al.  Finite element analysis of temperature distribution in single metallic powder layer during metal laser sintering , 2007 .

[55]  L. Papadakis,et al.  A computational reduction model for appraising structural effects in selective laser melting manufacturing , 2014 .

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

[57]  Andrew J. Pinkerton,et al.  Advances in the modeling of laser direct metal deposition , 2015 .