![]() ![]() First, the use of parametric open-source designs using an open-source computer aided design package is described to customize the optics hardware for any application. This library operates as a flexible, low-cost public-domain tool set for developing both research and teaching optics hardware. To assist in this aim, this paper introduces a library of open-source 3-D-printable optics components. Just as the power of the open-source design paradigm has driven down the cost of software to the point that it is accessible to most people, the rise of open-source hardware is poised to drive down the cost of doing experimental science to expand access to everyone. Finally, conclusions are drawn on the potential for open source 3-D printers to assist in driving sustainable development. Then, a methodology for quantifying the properties of printed parts and a research trajectory is outlined to extend the existing technology to provide complete village-level fabrication of OSATs. The current capabilities of open source 3-D printers is reviewed and a new classification scheme is proposed for OSATs that are technically feasible and economically viable for production. This study critically examines how open source 3-D printers, such as the RepRap and enable the use of designs in the public domain to fabricate open source appropriate technology (OSAT), which are easily and economically made from readily available resources by local communities to meet their needs. The technological evolution of the 3-D printer, widespread internet access and inexpensive computing has made a new means of open design capable of accelerating self-directed sustainable development. 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. The results show that utilizing a multi-polymer head system for multi-component manufacturing reduces manufacturing time and reduces the embodied energy of manufacturing. Composite parts are evaluated from the technical viability of manufacturing and quality. 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. This study describes a manufacturing technology that enables a constrained set of polymer-metal composite components. Please stop by the Library Prototype lab located in the Library lower level to pick up your poster at your earliest convenience.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. You will receive an email when your poster is printed.Whether the poster orientation is portrait or landscape, at least one edge of your poster cannot exceed 36 inches due to printer size restraints. The standard poster paper size we print is 24 by 36 inches depending on your template used.Please check with the Rapid Prototype Lab if you have any questions or concerns through email at or in person by visiting the MLK Library located in the lower level of the building during open hours (Monday thru Thursday). The preferred file formats are PowerPoint (.ppt) and Adobe PDF (.pdf).If you create a poster on a Mac, please check the file on a PC to make sure there are not any conversion problems.All posters received for printing are expected to be complete and ready to print 'as is'. Submit your poster to the prototype through the following link: Poster Print request according to the timeline schedule below. ![]()
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