Mesoscale modelling of selective laser melting: Thermal fluid dynamics and microstructural evolution

In this paper, an integrated computational materials science approach for selective laser melting (SLM) at the mesoscale is presented. A particle dropping model was developed to simulate the representative powder-bed particle distribution of a measured titanium alloy powder. Thermal fluid flow and resulting microstructural evolution of a set of laser scanned single tracks with different powder layer thicknesses and scanning speeds during SLM were also studied using both computational and experimental approaches. The simulated powder particle distribution was found to be consistent with experimental measurement. The thermal fluid flow model predicts that single laser scanned tracks become increasingly irregular-shaped with increased powder layer thickness and increased laser scanning speed. These findings were reinforced by scanning electron microscopy analysis. The more dispersed dissipation of the localised heat for thicker powder layers is understood to cause increased melting and evaporation. This can lead to increased Marangoni force and recoil pressure which in turn destabilises the melt flow. The use of an argon atmosphere speeds up the solidification process when compared with air but does not affect the morphology of single tracks significantly. The predicted microstructure was consistent with the electron backscattered diffraction data. The microstructure-based modelling methodology considering the representative powder size distribution provides a good predictive capability for the laser-powder interaction behaviour, surface structure and porosity development.

[1]  W. Johnson,et al.  Thermal expansion of liquid Ti–6Al–4V measured by electrostatic levitation , 2006 .

[2]  S. Khairallah,et al.  Mesoscopic Simulation Model of Selective Laser Melting of Stainless Steel Powder , 2014 .

[3]  Chee Kai Chua,et al.  Graded microstructure and mechanical properties of additive manufactured Ti–6Al–4V via electron beam melting , 2015 .

[4]  Todd Palmer,et al.  Heat transfer and fluid flow during keyhole mode laser welding of tantalum, Ti–6Al–4V, 304L stainless steel and vanadium , 2007 .

[5]  Modeling of powder absorption in additive manufacturing , 2014, 2014 Conference on Lasers and Electro-Optics (CLEO) - Laser Science to Photonic Applications.

[6]  D. Brüggemann,et al.  Shell-and-tube type latent heat thermal energy storage: numerical analysis and comparison with experiments , 2011 .

[7]  Tom Craeghs,et al.  A pragmatic model for selective laser melting with evaporation , 2009 .

[8]  Wei Liu,et al.  3D-imaging of selective laser melting defects in a Co–Cr–Mo alloy by synchrotron radiation micro-CT , 2015 .

[9]  L. Scriven,et al.  The Marangoni Effects , 1960, Nature.

[10]  L. Murr,et al.  Microstructures and mechanical behavior of Inconel 718 fabricated by selective laser melting , 2012 .

[11]  Wilfried Kurz,et al.  Theory of Microstructural Development during Rapid Solidification , 1986 .

[12]  Guoliang Qin,et al.  Adaptive volumetric heat source models for laser beam and laser + pulsed GMAW hybrid welding processes , 2011 .

[13]  C. Panwisawas,et al.  A Multi‐Scale Multi‐Physics Approach to Modelling of Additive Manufacturing in Nickel‐Based Superalloys , 2016 .

[14]  T. Ytrehus,et al.  Kinetic theory approach to interphase processes , 1996 .

[15]  Moataz M. Attallah,et al.  Microstructure and tensile properties of selectively laser-melted and of HIPed laser-melted Ti–6Al–4V , 2013 .

[16]  A. Rubenchik,et al.  Laser powder-bed fusion additive manufacturing: Physics of complex melt flow and formation mechanisms of pores, spatter, and denudation zones , 2015, 1512.02593.

[17]  Christoph Beckermann,et al.  Diffuse interface modeling of two-phase flows based on averaging: mass and momentum equations , 2004 .

[18]  D. Gu,et al.  Selective laser melting additive manufacturing of Inconel 718 superalloy parts: Densification, microstructure and properties , 2014 .

[19]  Xiangzhong Jin,et al.  A study on fresnel absorption and reflections in the keyhole in deep penetration laser welding , 2002 .

[20]  Moataz M. Attallah,et al.  The influence of the laser scan strategy on grain structure and cracking behaviour in SLM powder-bed fabricated nickel superalloy , 2014 .

[21]  C. Körner,et al.  Mesoscopic simulation of selective beam melting processes , 2011 .

[22]  Alexander M. Rubenchik,et al.  Denudation of metal powder layers in laser powder bed fusion processes , 2016 .

[23]  Thomas Graf,et al.  Multiple reflections and Fresnel absorption in an actual 3D keyhole during deep penetration laser welding , 2006 .

[24]  T. DebRoy,et al.  Heat transfer and fluid flow during electron beam welding of 21Cr–6Ni–9Mn steel and Ti–6Al–4V alloy , 2009 .

[25]  Moataz M. Attallah,et al.  On the role of thermal fluid dynamics into the evolution of porosity during selective laser melting , 2015 .

[26]  Moataz M. Attallah,et al.  On the role of melt flow into the surface structure and porosity development during selective laser melting , 2015 .

[27]  J. Brackbill,et al.  A continuum method for modeling surface tension , 1992 .

[28]  J. Mazumder,et al.  Modelling of high-density laser-material interaction using fast level set method , 2001 .

[29]  Manfred Geiger,et al.  A 3D transient model of keyhole and melt pool dynamics in laser beam welding applied to the joining of zinc coated sheets , 2009, Prod. Eng..

[30]  Moataz M. Attallah,et al.  Microstructural and texture development in direct laser fabricated IN718 , 2014 .

[31]  C. Gandin,et al.  A three-dimensional cellular automation-finite element model for the prediction of solidification grain structures , 1999 .

[32]  C. Gandin,et al.  A coupled finite element-cellular automaton model for the prediction of dendritic grain structures in solidification processes , 1994 .

[33]  P. Masson,et al.  A new approach to compute multi-reflections of laser beam in a keyhole for heat transfer and fluid flow modelling in laser welding , 2013 .

[34]  M. Cross,et al.  An enthalpy method for convection/diffusion phase change , 1987 .

[35]  Yuwen Zhang,et al.  Numerical Simulation of Random Packing of Spherical Particles for Powder-Based Additive Manufacturing , 2009 .

[36]  C. Gandin,et al.  Probabilistic modelling of microstructure formation in solidification processes , 1993 .