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==Source== | ==Source== | ||
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You can help Appropedia by contributing to the next step in this [[OSAT]]'s [[:Category:Status|status]]. | |||
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* John J. Laureto and Joshua M. Pearce. [http://dx.doi.org/10.3390/technologies5020036 Open Source Multi-Head 3D Printer for Polymer-Metal Composite Component Manufacturing] ''Technologies'' 2017, 5(2), 36; doi:10.3390/technologies5020036 [https://www.academia.edu/33578996/Open_Source_Multi-Head_3D_Printer_for_Polymer-Metal_Composite_Component_Manufacturing open access] | * John J. Laureto and Joshua M. Pearce. [http://dx.doi.org/10.3390/technologies5020036 Open Source Multi-Head 3D Printer for Polymer-Metal Composite Component Manufacturing] ''Technologies'' 2017, 5(2), 36; doi:10.3390/technologies5020036 [https://www.academia.edu/33578996/Open_Source_Multi-Head_3D_Printer_for_Polymer-Metal_Composite_Component_Manufacturing open access] | ||
** open hardware source code https://osf.io/jvhqt/ | ** open hardware source code https://osf.io/jvhqt/ | ||
** ini file http://www.mdpi.com/2227-7080/5/2/36/s1 | |||
** [[Franklin]] firmware, [[Franklin_Firmware_on_GigabotHX:MOST]] | ** [[Franklin]] firmware, [[Franklin_Firmware_on_GigabotHX:MOST]] | ||
** Re:3D. Gigabot http://shop.re3d.org/ | ** Re:3D. Gigabot http://shop.re3d.org/ | ||
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** Arduino Mega Board 2560. https://www.arduino.cc/en/Main/ArduinoBoardMega2560 | ** Arduino Mega Board 2560. https://www.arduino.cc/en/Main/ArduinoBoardMega2560 | ||
** KiCad–PcbNew. http://kicad-pcb.org/discover/pcbnew/ | ** KiCad–PcbNew. http://kicad-pcb.org/discover/pcbnew/ | ||
** Slic3r. http://slic3r.org/ | ** Slic3r. http://slic3r.org/ | ||
==Abstract== | ==Abstract== | ||
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* [[Franklin Firmware on GigabotHX:MOST]] | * [[Franklin Firmware on GigabotHX:MOST]] | ||
* [[GigabotHX]] | * [[GigabotHX]] | ||
* [[Metal wire embedding in fused filament 3-D printing]] | |||
* [[Experimental Characterization of Heat Transfer in an Additively Manufactured Polymer Heat Exchanger]] | * [[Experimental Characterization of Heat Transfer in an Additively Manufactured Polymer Heat Exchanger]] | ||
* [[Expanded microchannel heat exchanger]] | * [[Expanded microchannel heat exchanger]] | ||
* [[Towards Low-Cost Microchannel Heat Exchangers: Vehicle Heat Recovery Ventilator Prototype]] | * [[Towards Low-Cost Microchannel Heat Exchangers: Vehicle Heat Recovery Ventilator Prototype]] | ||
* [[ | * [[Design Optimization of Polymer Heat Exchanger for Automated Household-Scale Solar Water Pasteurizer]] | ||
[[Category:MOST completed projects and publications]] | [[Category:MOST completed projects and publications]] | ||
Revision as of 17:29, 21 April 2018
Source
Template:Statusboxtop Template:Status-design Template:Status-model Template:Status-prototype Template:Status-verified You can help Appropedia by contributing to the next step in this OSAT's status. Template:Boxbottom
- John J. Laureto and Joshua M. Pearce. Open Source Multi-Head 3D Printer for Polymer-Metal Composite Component Manufacturing Technologies 2017, 5(2), 36; doi:10.3390/technologies5020036 open access
- open hardware source code https://osf.io/jvhqt/
- ini file http://www.mdpi.com/2227-7080/5/2/36/s1
- Franklin firmware, Franklin_Firmware_on_GigabotHX:MOST
- Re:3D. Gigabot http://shop.re3d.org/
- OpenSCAD: http://www.openscad.org/
- IC3D Digital Platform. https://www.ic3dprinters.com/index.html
- RAMPS 1.4. http://reprap.org/wiki/RAMPS_1.4
- Pololu A4988 Stepper Motor Drive Carrier. https://www.pololu.com/product/1182
- Arduino Mega Board 2560. https://www.arduino.cc/en/Main/ArduinoBoardMega2560
- KiCad–PcbNew. http://kicad-pcb.org/discover/pcbnew/
- Slic3r. http://slic3r.org/
Abstract
As low-cost desktop 3D printing is now dominated by free and open source self-replicating rapid prototype (RepRap) derivatives, there is an intense interest in extending the scope of potential applications to manufacturing. This study describes a manufacturing technology that enables a constrained set of polymer-metal composite components. This paper provides (1) free and open source hardware and (2) software for printing systems that achieves metal wire embedment into a polymer matrix 3D-printed part via a novel weaving and wrapping method using (3) OpenSCAD and parametric coding for customized g-code commands. Composite parts are evaluated from the technical viability of manufacturing and quality. The results show that utilizing a multi-polymer head system for multi-component manufacturing reduces manufacturing time and reduces the embodied energy of manufacturing. Finally, it is concluded that an open source software and hardware tool chain can provide low-cost industrial manufacturing of complex metal-polymer composite-based products.
Keywords
open source; 3D printing; RepRap; composite; manufacturing; heat exchangers
See Also
- Franklin Firmware on GigabotHX:MOST
- GigabotHX
- Metal wire embedding in fused filament 3-D printing
- Experimental Characterization of Heat Transfer in an Additively Manufactured Polymer Heat Exchanger
- Expanded microchannel heat exchanger
- Towards Low-Cost Microchannel Heat Exchangers: Vehicle Heat Recovery Ventilator Prototype
- Design Optimization of Polymer Heat Exchanger for Automated Household-Scale Solar Water Pasteurizer