Density of additively-manufactured, 316L SS parts using laser powder-bed fusion at powers up to 400 W

Buchbinder D, Schleifenbaum H, Heidrich S, Meiners W, Bültmann J (2011) High power selective laser melting (HP SLM) of aluminum parts. Phys Procedia Part A 12:271–278

Dadbakhsh S, Hao L, Sewell N (2012) Effect of selective laser melting layout on the quality of stainless steel parts. Rapid Prototyp J 18:241–249

Delgado J, Ciurana J, Rodriguez C (2012) Influence of process parameters on part quality and mechanical properties for DMLS and SLM with iron-based materials. Int J Adv Manuf Technol 60:601–610

Eagar T, Tsai N (1983) Temperature-fields produced by traveling distributed heat-sources. Weld J 62:S346–S355

Fang KT, Li R, Sudjianto A (2005) Design and modeling for computer experiments. Chapman and Hall/CRC Press, Boca Raton

Inselberg A (2009) Parallel coordinates: visual multidimensional geometry and its applications. Springer, New York

Kamath C (2009) Scientific data mining: a practical perspective. Society for Industrial and Applied Mathematics (SIAM), Philadelphia

Kruth J, Yasa E, Deckers J (2008) Roughness improvement in selective laser melting. In: Proceedings of the international conference PMI 2008, Ghent, pp 170–183

Kruth J, Badrossamay M, Yasa E, Deckers J, Thijs L, Van Humbeeck J (2010a) Part and material properties in selective laser melting of metals. In: Proceedings of the 16th international symposium on electromachining (ISEM XVI), Shanghai

Kruth JP, Deckers J, Yasa E, Wauthlé R (2010b) Assessing influencing factors of residual stresses in selective laser melting using a novel analysis method. In: Proceedings of the 16th international symposium on electromachining (ISEM XVI), Shanghai, pp 531–537

Laohaprapanon A, Jeamwatthanachai P, Wongcumchang M, Chantarapanich N, Chantaweroad S, Sitthiseripratip K, Wisutmethangoon S (2012) Optimal scanning condition of selective laser melting processing with stainless steel 316l powder. Material and Manufacturing Technology Ii, Pts 1 and 2 Trans Tech Publications Ltd, Stafa-Zurich, pp 816–820

Liu B, Wildman R, Tuck C, Ashcroft I, Hague R (2011) Investigation the effect of particle size distribution on processing parameters optimisation in selective laser melting process. In: Bourell D (ed) International solid freeform fabrication symposium: an additive manufacturing conference. University of Texas at Austin, Austin, pp 227–238

Madison J, Aagesen L (2012) Quantitative characterization of porosity in laser welds of stainless steel. Scr Mater 67:783–786

Niendorf T, Leuders S, Riemer A, Richard H, Troster T, Schwarze D (2013) Highly anisotropic steel processed by selective laser melting. Metall Mater Trans B-Proc Metall Mater Proc Sci 44:794–796

Oehlert GW (2000) A first course in design and analysis of experiments. W. H. Freeman, available from http://users.stat.umn.edu/%7Egary/Book.html

Rai R, Elmer J, Palmer T, DebRoy T (2007) Heat transfer and fluid flow during keyhole mode laser welding of tantalum Ti-6Al-4V, 304L stainless steel and vanadium. J Phys D-Appl Phys 40:5753–5766

Sisto A, Kamath C (2013) Ensemble feature selection on scientific data analysis. Tech. Rep. LLNL-TR-644160. Lawrence Livermore National Laboratory, Livermore

Spierings A, Levy G (2009) Comparison of density of stainless steel 316L parts produced with selective laser melting using different powder grades. In: Bourell D (ed) Symposium, twentieth annual international solid freeform fabrication: an additive manufacturing conference. University of Texas at Austin, Austin, pp 342–353

Yadroitsev I (2009) Selective laser melting: direct manufacturing of 3D-objects by selective laser melting of metal powders. LAP Lambert Academic Publishing

Yadroitsev I, Smurov I (2010) Selective laser melting technology: from the single laser melted track stability to 3d parts of complex shape. Phys Procedia 5:551–560

Yadroitsev I, Gusarov A, Yadroitsava I, Smurov I (2010) Single track formation in selective laser melting of metal powders. J Mater Proc Technol 210:1624–1631

Yasa E (2011) Manufacturing by combining selective laser melting and selective laser erosion/laser re-melting. PhD thesis, Faculty of Engineering, Department of Mechanical Engineering, Katholieke Universiteit Leuven, Heverlee (Leuven), available from Katholieke Universiteit Leuven

Yasa E, Craeghs T, Badrossamay M, Kruth JP (2009) Rapid manufacturing research at the Catholic University of Leuven. In: RapidTech 2009: US-TURKEY workshop on rapid technologies, Istanbul

Yasa E, Deckers J, Kruth J, Rombouts M, Luyten J (2010) Investigation of sectoral scanning in selective laser melting. In: Proceedings of the ASME 10th biennial conference on engineering systems design and analysis, vol 4, pp 695–703

Yasa E, Deckers J, Kruth J (2011) The investigation of the influence of laser re-melting on density, surface quality and microstructure of selective laser melting parts. Rapid Prototyp J 17:312–327