TY - GEN
T1 - Software tool for detection and filling of voids as a part of tool-path strategy development for droplet generating 3D printers
AU - Prsa, Jelena
AU - Sobreviela, Javier
AU - Irlinger, Franz
AU - Lueth, Tim C.
N1 - Publisher Copyright:
© 2015 IEEE.
PY - 2015/10/12
Y1 - 2015/10/12
N2 - This paper presents a new method for filling the arbitrarily shaped closed contours with identical circles, as a part of the slicing software for droplet-generating 3D printers. 3D printers, as a part of Rapid prototyping technology, offer engineers and designers the possibility of producing models and prototypes layer wise in a fast way and directly from a CAD model. A Rapid prototyping process can be roughly divided into two stages: software and fabrication. The software stage has in turn different phases as well, and one of them is of interest in this paper: the slice filling phase, with the focus on the droplet deposition fabrication technology. Available filling methods typically include one or more boundaries (contours), which are followed by more repetitive boundary lines or zig-zag hatching. While filling the interior, inevitable voids arise. Different filling methods produce different kinds of voids. In the process of building a final part, accumulated layer wise voids result in an undesired uneven surface and brittle final parts. In order to reduce the amount and size of the voids, a study has been conducted and different standard infill methods have been simulated and visualised. As an extension to the standard infill methods, a novel software tool based on Voronoi diagrams that detects and fills the existing voids on each slice has been developed in MATLAB. With our software, we achieved an automatised tool which prevents defects whereat distinct areas are treated individually and a trade off between underfill and overfill is adjustable. In order to test the new detect-and-fill-voids approach we conducted several experiments. Different objects have been printed with and without applying our new approach on the standard infill methods. After measuring the surface roughness and fracture toughness, our new approach and its implementation proved to be very effective.
AB - This paper presents a new method for filling the arbitrarily shaped closed contours with identical circles, as a part of the slicing software for droplet-generating 3D printers. 3D printers, as a part of Rapid prototyping technology, offer engineers and designers the possibility of producing models and prototypes layer wise in a fast way and directly from a CAD model. A Rapid prototyping process can be roughly divided into two stages: software and fabrication. The software stage has in turn different phases as well, and one of them is of interest in this paper: the slice filling phase, with the focus on the droplet deposition fabrication technology. Available filling methods typically include one or more boundaries (contours), which are followed by more repetitive boundary lines or zig-zag hatching. While filling the interior, inevitable voids arise. Different filling methods produce different kinds of voids. In the process of building a final part, accumulated layer wise voids result in an undesired uneven surface and brittle final parts. In order to reduce the amount and size of the voids, a study has been conducted and different standard infill methods have been simulated and visualised. As an extension to the standard infill methods, a novel software tool based on Voronoi diagrams that detects and fills the existing voids on each slice has been developed in MATLAB. With our software, we achieved an automatised tool which prevents defects whereat distinct areas are treated individually and a trade off between underfill and overfill is adjustable. In order to test the new detect-and-fill-voids approach we conducted several experiments. Different objects have been printed with and without applying our new approach on the standard infill methods. After measuring the surface roughness and fracture toughness, our new approach and its implementation proved to be very effective.
KW - Filling
KW - Printers
KW - Printing
KW - Rough surfaces
KW - Solid modeling
KW - Surface roughness
KW - Three-dimensional displays
UR - http://www.scopus.com/inward/record.url?scp=84949657784&partnerID=8YFLogxK
U2 - 10.1109/CITS.2015.7297725
DO - 10.1109/CITS.2015.7297725
M3 - Conference contribution
AN - SCOPUS:84949657784
T3 - IEEE CITS 2015 - 2015 International Conference on Computer, Information and Telecommunication Systems
BT - IEEE CITS 2015 - 2015 International Conference on Computer, Information and Telecommunication Systems
A2 - Caballero, Daniel Cascalado
A2 - Hsiao, Kuei-Fang
A2 - Nicopolitidis, Petros
A2 - Obaidat, Mohammad S.
A2 - Garcia, Daniel F.
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - International Conference on Computer, Information and Telecommunication Systems, IEEE CITS 2015
Y2 - 15 July 2015 through 17 July 2015
ER -