Sage Journals: Discover world-class research

Abstract

Selective laser sintering (SLS^®, a trademark of 3D systems Inc.) is a manufacturing process which has emerged from numerous other technologies as the leading process considered viable for rapid manufacturing (RM). SLS of polymers has found use in a wide range of industries ranging from aerospace to medicine. The ability to manufacture easily parts that previously have been difficult or impossible to produce, without tooling, has proved invaluable for many applications. A major area of focus within RM is the requirement to produce parts with more repeatable mechanical properties than can currently be achieved. This research has investigated the use of a novel method of interpreting a differential scanning calorimetry curve to indicate the level of melting within semicrystalline selective laser-sintered parts, or the degree of particle melt (DPM). The DPM has been shown firstly to be affected by the amount of energy input into the process whereby, as the energy input increases, the DPM also increases. Results have also shown that, as the DPM increases, the tensile strength and elongation at break also increase, whilst there is no significant effect on the Young's modulus. These findings will enhance the ability to optimize and predict the properties of the SLS process, an area which is critical when producing end-use parts, particularly when considering demanding applications such as in the aerospace and automotive industries.

Keywords

rapid prototyping rapid manufacturing selective laser sintering differential scanning calorimetry degree of particle melt

References

Wohlers

Wohlers Report 2006. Wohlers Associates

Fort Collins, Colorado

2006.

Hopkinson

Dickens

P. M.

Rapid prototyping for direct manufacture. Rapid Prototyping J.20017(4)197–202.

Hopkinson

Hague

R. J. M.

Dickens

P. M.

Rapid manufacturing: an industrial revolution for the digital age2005 (John WileyChichester, West Sussex).

Johnson

J. A.

Evaluating processing conditions by optical microscopy. In Proceedings of the SPE Annual Technical Conference (ANTEC 1996), Indianapolis, Indiana, USA, 5-10 May 1996, pp. 3318–3323 (Society of Plastics EngineersBrookfield, Connecticut).

Moeskops

Kamperman

van de Vorst

Knopppers

Creep behaviour of polyamide in selective laser sintering. In Proceedings of the 15th Solid Freeform Fabrication Symposium, Austin, Texas, USA, August 2004, pp. 60–68 (University of Texas at AustinAustin, TX).

Zarringhalam

Hopkinson

Kamperman

N. F.

de Vlieger

J. J.

Effects of processing on microstructure and properties of SLS Nylon 12. Mater. Sci. Engng A2006435-436172–180.

Zarringhalam

Investigation into crystallinity and degree of particle melt in selective laser sintering. PhD ThesisLoughborough University2007.

Caulfield

McHugh

P. E.

Lohfeld

Dependence of mechanical properties of polyamide components on build parameters in the SLS process. J. Mater. Processing Technol.2007182477–488.

3D Systems, DuraForm LS materials: datasheets2007, accessed January 2008, available from http://www.3dsystems.com.

10.

Gibson

Shi

Material properties and fabrication parameters in selective laser sintering process. Rapid Prototyping J.19973-4129–136.

11.

Ajoku

Saleh

Hopkinson

Hague

Erasenthiran

Investigating mechanical anisotropy and end-of-vector effect in laser-sintered nylon parts. Proc. IMechE, Part B: J. Engineering Manufacture2006220(7)1077–1086.

12.

Hinton

P. R.

Statistics explained2004 (Routledge Taylor & Francis GroupLondon).

13.

Deshmane

Yuan

Misra

R. D. K.

On the fracture characteristics of impact tested high density polyethylene-calcium carbonate nanocomposites. Mater. Sci. Engng A2007452-453592–601.

14.

Bessell

T. J.

Hull

Shortall

J. B.

The effect of polymerization conditions and crystallinity on the mechanical properties and fracture of spherulitic Nylon 6. J. Mater. Sci.1975101127–1136.

Effect of the degree of particle melt on mechanical properties in selective laser-sintered Nylon-12 parts

Abstract

Keywords

References