UV-curing kinetics and performance development of in situ curable 3D printing materials

Authors
Kim, Ye ChanHong, SungyongSun, HannaKim, Meyong GiChoi, KisukCho, JungkeunChoi, Hyouk RyeolKoo, Ja ChoonMoon, HyungpilByun, DoyoungKim, Kwang J.Suhr, JonghwanKim, Soo HyunNam, Jae-Do
Issue Date
2017-08
Publisher
PERGAMON-ELSEVIER SCIENCE LTD
Citation
EUROPEAN POLYMER JOURNAL, v.93, pp.140 - 147
Abstract
As three-dimensional (3D) printing technology is emerging as an alternative way of manufacturing, the high resolution 3D printing device often requires systems such as drop jetting printing of in situ UV-curable photopolymers. Accordingly, the key issue is process control and its optimization to ensure dimensional accuracy, surface roughness, building orientation, and mechanical properties of printed structures, which are based on the time- and temperature-dependent glass transition temperature (T-g) of the resin system under UV-curing. In this study, the UV cure kinetics and T-g development of a commercially available UV-curable acrylic resin system were investigated as a model system, using a differential scanning photocalorimeter (DPC). The developed kinetic model included the limited conversion of cure that could be achieved as a maximum at a specific isothermal curing temperature. Using the developed model, the T-g was successfully described by a modified DiBenedetto equation as a function of UV curing. The developed kinetic model and T-g development can be used to determine the 3D printing operating conditions for the overlay printing and in situ UV curing, which could ensure high-resolution and high-speed manufacturing with various UV-curing materials.
Keywords
GLASS-TRANSITION TEMPERATURE; COMPOSITE METHODOLOGY; MECHANICAL-PROPERTIES; SURFACE-ROUGHNESS; PHOTO-DSC; PHOTOPOLYMERIZATION; POLYMERS; SYSTEMS; CURE; DEGRADATION; GLASS-TRANSITION TEMPERATURE; COMPOSITE METHODOLOGY; MECHANICAL-PROPERTIES; SURFACE-ROUGHNESS; PHOTO-DSC; PHOTOPOLYMERIZATION; POLYMERS; SYSTEMS; CURE; DEGRADATION; Multi-jet 3D printing; UV-curable polymer; UV-cure kinetics; Glass transition temperature; Performance development; Differential scanning photocalorimetry
ISSN
0014-3057
URI
https://pubs.kist.re.kr/handle/201004/122462
DOI
10.1016/j.eurpolymj.2017.05.041
Appears in Collections:
KIST Article > 2017
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