Smoother and stronger high speed sintered elastomers through surface modification process Online publication date: Wed, 08-Feb-2017
by Farhana Norazman; Patrick Smith; Adam Ellis; Neil Hopkinson
International Journal of Rapid Manufacturing (IJRAPIDM), Vol. 6, No. 2/3, 2017
Abstract: High speed sintering is a novel additive manufacturing process which creates parts by employing a combination of inkjet printing and infrared heating to sinter successive layers of polymer powder. This paper investigates the effect of a new surface modification method called the PUSh™ process on the mechanical properties of high speed sintered elastomer. ALM TPE210-S elastomeric powder was used to manufacture specimens, and the PUSh™ process was subsequently performed on selected specimens. Surface roughness and mechanical properties of TPE210-S specimens were measured. The results show that the PUSh™ process reduced surface roughness by 50% from 20 to 10 µm. Finished specimens had 50% higher values of ultimate tensile strength, Young's modulus and elongation at break compared to unfinished specimens, and tear strength was significantly improved by 233%. The process resulted in 3% average part shrinkage while part hardness remains unchanged. Overall, the mechanical properties of high speed sintered TPE210-S elastomer were improved by the PUSh™ process.
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