A comprehensive study on surface quality in 5-axis milling of SLM Ti-6Al-4V spherical components

Surface quality is a significant factor in machining that affects the accuracy of spherical components. In this research, Ti-6Al-4V prosthetic acetabular shells have been printed using selective laser melting (SLM). Two post-processes, heat treatment and machining, have been carried out on the printed samples to improve the mechanical properties, dimensional deviations, and surface quality. Samples were printed based on Taguchi L32 design of experiment (DOE), and in order to predict the surface roughness multilayer perceptron (MLP) artificial neural networks (ANNs), Poisson and Taguchi methods have been used. The novelty of this work is in explaining the mechanical properties of as-built SLM parts such as hardness, ductility, and strength and their effect on machinability of spherical components. Characterising the effect of cutting conditions and heat treatment on the surface quality based on mechanics of cutting process and tool geometry is another contribution of this paper. Results showed that MLP ANN has high potential in the modelling of surface roughness in 5-axis machining of spherical components. To improve the surface quality of SLM parts, it is recommended to design appropriate tool paths, and machining parameters with lower scallop height, finishing allowance and higher spindle speed than normal and a higher annealing temperature.

[1]  Di Wang,et al.  The design and manufacturing of a titanium alloy beak for Grus japonensis using additive manufacturing , 2017 .

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

[3]  I. Gibson,et al.  Production of Ti-6Al-4V acetabular shell using selective laser melting: possible limitations in fabrication , 2017 .

[4]  David W. Rosen,et al.  Additive Manufacturing Technologies: Rapid Prototyping to Direct Digital Manufacturing , 2009 .

[5]  E. Chlebus,et al.  Microstructure and mechanical behaviour of Ti―6Al―7Nb alloy produced by selective laser melting , 2011 .

[6]  Guy Littlefair,et al.  Titanium in biomedical applications—properties and fabrication: a review , 2015 .

[7]  Bo Song,et al.  Vacuum heat treatment of iron parts produced by selective laser melting: Microstructure, residual stress and tensile behavior , 2014 .

[8]  Mohammad Reza Razfar,et al.  SIMULATION OF END MILLING OPERATION FOR PREDICTING CUTTING FORCES TO MINIMIZE TOOL DEFLECTION BY GENETIC ALGORITHM , 2010 .

[9]  Mohammad Reza Soleymani Yazdi,et al.  Tool Life Prediction in Face Milling Machining of 7075 Al by Using Artificial Neural Networks (ANN) and Taguchi Design of Experiment (DOE) , 2011 .

[10]  S. Zec,et al.  The effect of annealing temperatures and cooling rates on microstructure and mechanical properties of investment cast Ti–6Al–4V alloy , 2006 .

[11]  David T. D. Childs,et al.  Laser diode area melting for high speed additive manufacturing of metallic components , 2017 .

[12]  K. Zhou,et al.  Hot Deformation of Ti-5Al-5Mo-5 V-1Cr-1Fe Near β Titanium Alloys Containing Thin and Thick Lamellar α Phase , 2013 .

[13]  Suhas S. Joshi,et al.  Experimental Investigation into the Effect of Ball End Milling Parameters on Surface Integrity of Inconel 718 , 2015, Journal of Materials Engineering and Performance.

[14]  Ian Gibson,et al.  An improved static model for tool deflection in machining of Ti–6Al–4V acetabular shell produced by selective laser melting , 2016 .

[15]  N. Fang,et al.  A comparative study of the cutting forces in high speed machining of Ti–6Al–4V and Inconel 718 with a round cutting edge tool , 2009 .

[16]  E. Collings,et al.  Materials Properties Handbook: Titanium Alloys , 1994 .

[17]  Malgorzata Plaza,et al.  Comparative study of 3- and 5-axis CNC centers for free-form machining of difficult-to-cut material , 2014 .

[18]  Adriano Fagali de Souza,et al.  Evaluating surface roughness, tool life, and machining force when milling free-form shapes on hardened AISI D6 steel , 2016 .

[19]  A. Pramanik Problems and solutions in machining of titanium alloys , 2014 .

[20]  Shane Y. Hong,et al.  Cooling approaches and cutting temperatures in cryogenic machining of Ti-6Al-4V , 2001 .

[21]  Yusuf Altintas,et al.  Mechanics and Dynamics of Ball End Milling , 1998 .

[22]  Yusuf Altintas,et al.  Prediction of Milling Force Coefficients From Orthogonal Cutting Data , 1996 .

[23]  J. Wallbank,et al.  Machining of Titanium and its Alloys—a Review , 1990 .

[24]  Neil R. Ullman,et al.  Signal-to-noise ratios, performance criteria, and transformations , 1988 .

[25]  J. Sieniawski,et al.  Microstructure and Mechanical Properties of High Strength Two-Phase Titanium Alloys , 2013 .

[26]  M. R. Razfar,et al.  Simulation of three-dimension cutting force and tool deflection in the end milling operation based on finite element method , 2008, Simul. Model. Pract. Theory.

[27]  T. Kitagawa,et al.  Temperature and wear of cutting tools in high-speed machining of Inconel 718 and Ti6Al6V2Sn , 1997 .

[28]  Ian Gibson,et al.  Investigation on the effect of cutting fluid pressure on surface quality measurement in high speed thread milling of brass alloy (C3600) and aluminium alloy (5083) , 2016 .

[29]  Rida T. Farouki,et al.  A real-time surface interpolator methodology for precision CNC machining of swept surfaces , 2016 .

[30]  Ossama B. Abouelatta,et al.  Surface roughness prediction based on cutting parameters and tool vibrations in turning operations , 2001 .

[31]  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.

[32]  Ali Gökhan Demir,et al.  Additive manufacturing of cardiovascular CoCr stents by selective laser melting , 2017 .

[33]  Ronald A. Walsh,et al.  Handbook of Machining and Metalworking Calculations , 2000 .

[34]  Mohammad Reza Soleymani Yazdi,et al.  Development of a dynamic surface roughness monitoring system based on artificial neural networks (ANN) in milling operation , 2015, The International Journal of Advanced Manufacturing Technology.

[35]  Ildikó Maňková,et al.  An approach to the evaluation of multivariate data during ball end milling free-form surface fragments , 2016 .

[36]  Ian Gibson,et al.  Micro prototyping and fabrication in manufacturing , 2015 .

[37]  C. N. Chu,et al.  Effect of cutter mark on surface roughness and scallop height in sculptured surface machining , 1994, Comput. Aided Des..

[38]  I. Yadroitsava,et al.  Selective laser melting of Ti6Al4V alloy for biomedical applications: Temperature monitoring and microstructural evolution , 2014 .

[39]  Heat treatment of Ti6Al4V produced by Selective Laser Melting: Microstructure and mechanical properties , 2012 .

[40]  Yusuf Altintas,et al.  Prediction of Ball End Milling Forces , 1996 .

[41]  Adnan A. Ugla,et al.  Microstructure characterization of SS308LSi components manufactured by GTAW-based additive manufacturing: shaped metal deposition using pulsed current arc , 2017 .

[42]  Ian Gibson,et al.  On the role of different annealing heat treatments on mechanical properties and microstructure of selective laser melted and conventional wrought Ti-6Al-4V , 2017 .

[43]  H. Maier,et al.  In situ characterization of the deformation and failure behavior of non-stochastic porous structures processed by selective laser melting , 2011 .

[44]  O. Rosenberg,et al.  Trends and developments in the manufacturing of hip joints: an overview , 2006 .

[45]  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 .

[46]  R.M.S.O. Baptista,et al.  Three and five axes milling of sculptured surfaces , 2000 .

[47]  F. Nabhani Machining of aerospace titanium alloys , 2001 .

[48]  H. Liao,et al.  Fabrication and microstructure characterization of selective laser‐melted FeAl intermetallic parts , 2012 .

[49]  A. Miriyev,et al.  Additive manufacturing of complex-shaped graded TiC/steel composites , 2017 .

[50]  María Dolores Ugarte,et al.  Probability and Statistics with R , 2008 .

[51]  I. Gibson,et al.  A survey on mechanisms and critical parameters on solidification of selective laser melting during fabrication of Ti-6Al-4V prosthetic acetabular cup , 2016 .

[52]  Han Huang,et al.  Effect of substrate temperature on the interface bond between support and substrate during selective laser melting of Al-Ni-Y-Co-La metallic glass , 2015 .

[53]  Xu Han,et al.  Melt-pool motion, temperature variation and dendritic morphology of Inconel 718 during pulsed- and continuous-wave laser additive manufacturing: A comparative study , 2017 .

[54]  Gang-yu Liu,et al.  Use of nitrogen gas in high-speed milling of Ti-6Al-4V , 2009 .

[55]  Mariana Calin,et al.  Selective laser melting of in situ titanium–titanium boride composites: Processing, microstructure and mechanical properties , 2014 .

[56]  C. Lartigue,et al.  Surface topography in ball end milling process: Description of a 3D surface roughness parameter , 2008 .

[57]  Joaquim Ciurana,et al.  Surface roughness monitoring application based on artificial neural networks for ball-end milling operations , 2011, J. Intell. Manuf..

[58]  C. Kuo,et al.  Development of sheet metal forming dies with excellent mechanical properties using additive manufacturing and rapid tooling technologies , 2017 .

[59]  J. Ciurana,et al.  Surface Roughness Generation and Material Removal Rate in Ball End Milling Operations , 2010 .

[60]  F. Erzincanli,et al.  Prediction of minimum surface roughness in end milling mold parts using neural network and genetic algorithm , 2006 .

[61]  A. Weisheit,et al.  Laser additive manufacturing of iron aluminides strengthened by ordering, borides or coherent Heusler phase , 2017 .

[62]  Bo Song,et al.  Fabrication of NiCr alloy parts by selective laser melting: Columnar microstructure and anisotropic mechanical behavior , 2014 .

[63]  Z. M. Wang,et al.  Titanium alloys and their machinability—a review , 1997 .

[64]  Matthew Franchetti,et al.  An economic analysis comparing the cost feasibility of replacing injection molding processes with emerging additive manufacturing techniques , 2017 .

[65]  Ian Gibson,et al.  Additive manufacturing technologies : 3D printing, rapid prototyping, and direct digital manufacturing , 2015 .