Development and Characterizations of a Projection Stereolithography

Pornsak Srisungsitthisunti; Thossaporn Kaewwichit

doi:10.4028/www.scientific.net/KEM.751.160

Paper Titles

Effect of Post-Curing Temperature and Mechanical Surface Treatment on Shear-Bond Strength of Asbestos-Free Brake Pad
p.131

Effects of Air Exposure Time and Annealing Temperature on Superhydrophobic Surface of Titanium Dioxide Films
p.137

Meta-Heuristics for Engineering Optimisation - Applications to Metal Forming Processes
p.145

Development of a Regression Model of Stk₅₀Eu for a Hydrocyclone
p.151

Development and Characterizations of a Projection Stereolithography
p.160

Formability Analysis of Fukui Stretch-Drawing and Square Cup Drawing Using Strain and Stress Based Forming Limit Curves
p.167

Effect of Feed-Flow Rate in a Solid-Liquid Hydrocyclone Based on Total Solid Recovery Equation
p.173

Bending Limit Curves in Sheet Metal Bending Evaluation
p.180

Fastenerless-Riveting Utilizing Friction Stir Forming for Dissimilar Materials Joining
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 751Development and Characterizations of a Projection...

Development and Characterizations of a Projection Stereolithography

Abstract:

Stereolithography is a manufacturing process capable of building a truly high resolution 3D structure by solidifying the liquid monomer in a layer by layer fashion. Currently, there are many developments toward new 3D printing techniques leading to needs for methods of characterization to improve printing process for higher performance. In this study, we propose to create a bottom-up projection stereolithography to accommodate a 3D printing technique. Our system was designed for combining with a regular fused deposition modeling (FDM) process for multi-material application. In addition, we developed a method for characterizations different specifications of a custom-made projection stereolithography. Our 3D printer can create an object up to 25 mm x 25 mm x 15 mm of length, width and height, respectively. We minimized the layer thickness error by modifying a screw and spring components in order to precisely control the movement of the vertical stepping. The light source distance and the calibration factor were also importance factors to obtain the better precision of finished parts. Based on the proposed characterization method, the 3D printer was able to achieve the lateral resolution of 0.05 mm and a vertical step resolution of 0.01 mm. The average percentage error of built part were 0.32 % on X-axis and 0.25 % on Y-axis laterally and 0.60 % error on the layer thickness.

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Periodical:

Key Engineering Materials (Volume 751)

Pages:

160-166

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.751.160

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Online since:

August 2017

Authors:

Pornsak Srisungsitthisunti, Thossaporn Kaewwichit*

Keywords:

3D Printing, Additive Manufacturing, Machine Design, Projection Stereolithography

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* - Corresponding Author

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