Abstract
This paper investigates selective laser sintering/melting (SLS/SLM) processes by a thermal model solved with a finite difference scheme. The density equation is semi-empirical based on the Arrhenius equation and experimental results taken from literature. Energy distribution function in the laser beam is appropriately considered. The main input parameters studied were as follows: laser speed, preheating temperature and laser power. The output parameters were maximum temperature and consolidation area. SLS was tried on polycarbonate powder and SLM on a Ni superalloy. Variations of temperature and density with time at the centre of the beam and at another two points at increasing distances from it were found to be qualitatively similar irrespective of the laser speed and power. Maximum temperature reached is not affected significantly by preheating temperature, by contrast to the consolidated depth and consolidation area. The latter are also affected by laser power. Increase in laser speed leads, as expected, to a decrease in consolidation depth and area as well as a decrease in maximum temperature. Continuous and pulsed lasers exhibited large differences; e.g. for the same speed and power, a pulsed laser results in much lower temperature gradients during cooling. The model can be used to obtain a preliminary picture of the response of any material to SLS/SLM processing provided that the appropriate input data is available, which is a crucial factor not to be underestimated.
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References
Kruth JP, Levy G, Klocke F (2007) Consolidation phenomena in laser and powder-bed based manufacturing. CIRP Ann Manuf Technol 56(2):730–759
Santos EC, Shiomi M, Osakada K, Laoui T (2006) Rapid manufacturing of metal components by laser forming. Int J Mach Tools Manuf 46(12–13):1459–1468
Zeng K, Pal D, Stucker B (2012) A review of thermal analysis methods in laser sintering and selective laser melting, Proceedings of the Solid Freeform Fabrication Symposium, Austin, Texas, USA, August 2012, 796–814.
Mori K, Kuzime R (2002) Microscopic approach of powder compaction using finite element method. Int J Mech Sci 44:793–807
Patil RB, Yadava V (2007) Finite element analysis of temperature distribution in single metallic powder layer during metal laser sintering. Int J Mach Tools Manuf 47:1069–1080
Dong I, Makradi A, Ahzi S, Remond Y (2009) Three-dimensional transient finite element analysis of the selective laser sintering process. J Mater Process Technol 209(2):700–706
Raghunath N, Padney PM (2007) Improving accuracy through shrinkage modeling by using Taguchi method in selective laser sintering. Int J Mach Tools Manuf 47:989–995
Matsumoto M, Shiomi M, Osakada K, Abe F (2002) Finite element analysis of single layer forming on metallic powder bed in rapid prototyping by selective laser processing. Int J Mach Tools Manuf 42(1):61–67
Childs THC, Berzins M, Ryder GR, Tontowi A (1999) Selective laser sintering of an amorphous polymer—simulations and experiments. J Eng Manuf 213:333–349
Williams JD, Deckard CR (1998) Advances in modeling the effects of selected parameters on the SLS process. Rapid Prototyp J 4(2):90–100
Puglisi C, Sturiale L, Montaudo G (1999) Thermal decomposition processes in aromatic polycarbonates investigated by mass spectrometry. Macromolecules 32(7):2194–2203
Zhao Y, Song L, Li G (2002) Chemical stabilization of MSW incinerator fly ashes. J Hazard Mater 95(1–2):47–63
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Konstantinou, I., Vosniakos, GC. Rough-cut fast numerical investigation of temperature fields in selective laser sintering/melting. Int J Adv Manuf Technol 99, 29–36 (2018). https://doi.org/10.1007/s00170-016-9091-5
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DOI: https://doi.org/10.1007/s00170-016-9091-5