An automated Multiple Material Stereolithography (MMSL) machine was developed by integrating components of a 3D Systems 250/50 stereolithography (SL) machine in a separate stand-alone system and adapting them to function with additional components required for MMSL operation. We previously reported retrofitting a 250/50 SL machine with multiple vats to accommodate multiple material fabrication for building a wide variety of multi-material models (Wicker et al., 2004). In the MMSL retrofit, spatial constraints limited the multiple vats located circumferentially on a vertical rotating vat carousel to cross-sectional areas of approximately 4.5-inches by 4.5-inches. The limited build size of the retrofitted 250/50 motivated the full development of a new system with multiple material build capabilities comparable to the build envelope of the original 250/50 machine. The new MMSL machine required fabrication of a large system frame, incorporating various 250/50 components and software, and adding a variety of new components and software. By using many existing components and software, the previous engineering development of 3D Systems could be directly applied to this new technology. Components that were transferred from an existing 250/50 to the MMSL machine included the complete optical system (including the optics plate with laser, mirrors, beam expander, scanning mirrors, and focusing lens), the rim assembly (including the laser beam profilers), the associated controllers (computer system, scanning mirror controller, power supply-vat controller) and the wiring harness. In addition to the new frame, the MMSL machine required the development of a new rotating vat carousel system, platform assembly, multi-pump filling/leveling system, and a custom LabVIEW control system to provide automated control over the MMSL process. The overall operation of the MMSL system was managed using the LabVIEW program, which also included controlling a new vat leveling system and new linear and rotational stages, while the 3D Systems software (Buildstation 4.0) was retained for controlling the laser scanning process. As a demonstration of MMSL technology, simple multi material parts were fabricated with vertically and horizontally oriented interfaces. The fully functional MMSL system offers enormous potential for fabricating a wide variety of multiple material functional devices.
[1]
Dan Qiu,et al.
Virtual Simulation for Multi-material LM Process
,
1998
.
[2]
Mohsen A. Jafari,et al.
A novel system for fused deposition of advanced multiple ceramics
,
2000
.
[3]
Pranav Kumar,et al.
Direct‐write deposition of fine powders through miniature hopper‐nozzles for multi‐material solid freeform fabrication
,
2004
.
[4]
R. Wicker,et al.
Multiple Material Micro-Fabrication: Extending Stereolithography to Tissue Engineering and Other Novel Applications
,
2004
.
[5]
Ryan B. Wicker,et al.
Stereolithography of PEG Hydrogel Multi-Lumen Nerve Regeneration Conduits
,
2005
.
[6]
R. Wicker,et al.
Hydrogels in Stereolithography
,
2005
.
[7]
Ryan B. Wicker,et al.
Nanotailoring stereolithography resins for unique applications using carbon nanotubes
,
2005
.
[8]
Ryan B. Wicker,et al.
Hybrid manufacturing: Integrating direct write and stereolithography
,
2005
.
[9]
Ryan B. Wicker,et al.
Stereolithography of Three-Dimensional Bioactive Poly(Ethylene Glycol) Constructs with Encapsulated Cells
,
2006,
Annals of Biomedical Engineering.
[10]
Eric MacDonald,et al.
Expanding rapid prototyping for electronic systems integration of arbitrary form
,
2006
.