TY - JOUR
T1 - Effect of print orientation on microstructural features and mechanical properties of 3D porous structures printed with continuous digital light processing
AU - Navarro, Javier
AU - Din, Matthew
AU - Janes, Morgan Elizabeth
AU - Swayambunathan, Jay
AU - Fisher, John P.
AU - Dreher, Maureen L.
PY - 2019/7/8
Y1 - 2019/7/8
N2 - PurposeThis paper aims to study the effects of part orientation during the 3D printing process, particularly to the case of using continuous digital light processing (cDLP) technology.Design/methodology/approachThe effects of print orientation on the print accuracy of microstructural features were assessed using microCT imaging and mechanical properties of cDLP microporous scaffolds were characterized under simple compression and complex biaxial loading. Resin viscosity was also quantified to incorporate this factor in the printing discussion.FindingsThe combined effect of print resin viscosity and the orientation and spacing of pores within the structure alters how uncrosslinked resin flows within the construct during cDLP printing. Microstructural features in horizontally printed structures exhibited greater agreement to the design dimensions than vertically printed constructs. While cDLP technologies have the potential to produce mechanically isotropic solid constructs because of bond homogeneity, the effect of print orientation on microstructural feature sizes can result in structurally anisotropic porous constructs.Originality/valueThis work is useful to elucidate on the specific capabilities of 3D printing cDLP technology. The orientation of the part can be used to optimize the printing process, directly altering parameters such as the supporting structures required, print time, layering, shrinkage or surface roughness. This study further detailed the effects on the mechanical properties and the print accuracy of the printed scaffolds.
AB - PurposeThis paper aims to study the effects of part orientation during the 3D printing process, particularly to the case of using continuous digital light processing (cDLP) technology.Design/methodology/approachThe effects of print orientation on the print accuracy of microstructural features were assessed using microCT imaging and mechanical properties of cDLP microporous scaffolds were characterized under simple compression and complex biaxial loading. Resin viscosity was also quantified to incorporate this factor in the printing discussion.FindingsThe combined effect of print resin viscosity and the orientation and spacing of pores within the structure alters how uncrosslinked resin flows within the construct during cDLP printing. Microstructural features in horizontally printed structures exhibited greater agreement to the design dimensions than vertically printed constructs. While cDLP technologies have the potential to produce mechanically isotropic solid constructs because of bond homogeneity, the effect of print orientation on microstructural feature sizes can result in structurally anisotropic porous constructs.Originality/valueThis work is useful to elucidate on the specific capabilities of 3D printing cDLP technology. The orientation of the part can be used to optimize the printing process, directly altering parameters such as the supporting structures required, print time, layering, shrinkage or surface roughness. This study further detailed the effects on the mechanical properties and the print accuracy of the printed scaffolds.
UR - http://dx.doi.org/10.1108/rpj-10-2018-0276
U2 - 10.1108/rpj-10-2018-0276
DO - 10.1108/rpj-10-2018-0276
M3 - Article
SN - 1355-2546
VL - 25
SP - 1017
EP - 1029
JO - Rapid Prototyping Journal
JF - Rapid Prototyping Journal
IS - 6
ER -