Authors:
A. Nurulhuda,S.H.S.N. Aqmaliah,R. Ali,S. Yacob,DOI NO:
https://doi.org/10.26782/jmcms.spl.4/2019.11.00013Keywords:
POM Materials,Thermo-Mechanical,Plastic Degradation,Gear Geometries,Injection Plastic Gear,Abstract
The fabrication of scaffold structures for tissue engineering is extremely difficult due to requirement on porosity behavior and mechanical properties stability. This paper presents the oversights effect on the mechanical properties of multilayered ABS scaffold via FDM 3D printing due to different geometries parameter. Tensile testing methods with reference were used to examine the mechanical strength properties of 3D printed scaffold while ANOVA analysis study was used to judge the correlation and significant effect of setting parameter to the mechanical performance behavior of scaffold.Refference:
I. Ala’aldin A, Ala Q, Buraaq A, and Arturo G (2017). Experimental
optimization of fused deposition modelling processing Parameters: design for
manufacturing approach mechanical engineering, Procedia Manufacturing,
Vol 10, 791-803.
II. Heechang K, Eunju P, Suhyun K, Bumsoo P, Namhun K, and Seungchul L
(2017). Experimental study on mechanical properties of single and Dualmaterial
3D printed product, Procedia Manufacturing, Vol 10, 887-897.
III. Kalita SJ, Bose S, Hosick HL, Bandyopadhyay A (2003). Development of
controlled porosity polymer-ceramic composite scaffolds via fused deposition
modeling. Mater SciEng 26:611-620.
IV. Michael M, Shad R, Dan O, Paul K. W, and Sung-Hoon A (2001). Material
Characterization of Fused Deposition Modeling (FDM) ABS by Designed
Experiments, Proceedings of Rapid Prototyping & Manufacturing
Conference.
V. Zein I, Dietmar WH, Tan KC, Teoh SH (2002). Fused deposition modeling
of novel scaffold architectures for tissue engineering applications.
Biomaterials 23:1169-1185.