RAPID prototyping, ENGINEERING design, THREE-dimensional printing, MATERIALS, 3-D printers, and DIGITAL printing presses
An interview with Nadav Goshen, chief executive officer (CEO) of MakerBot Industries, is presented. Topic include the platform was designed for engineers who need immediate access to a 3D printer that can deliver industrial performance but at a significantly lower cost, and also providing engineers with more material options by working with filament suppliers to offer a wider range of materials.
RAPID prototyping, TECHNOLOGICAL innovations, MANUFACTURING processes, THREE-dimensional printing, 3-D printers, and DIGITAL printing
The article focuses on the evolution and improvements on 3D printer, one of the most important tools for product development as it helps prototypers build parts in a matter of hours, when machining or molding can take days or weeks. Information on some of the innovations include high-performance filaments, multi-material printing, and metal printing.
The article offers information related to ProtoSpace at the University of Technology, Sydney (UTS) facility aimed to provide a sandbox for manufacturing industry to come and experiment with what three dimensional (3D) printing. It further explores how 3D printing known as additive manufacturing, can mean for the Australian manufacturing industry.
We present an interactive design system for designing free-formed bamboo-copters, where novices can easily design free-formed, even asymmetric bamboo-copters that successfully fly. The designed bamboo-copters can be fabricated using digital fabrication equipment, such as a laser cutter. Our system provides two useful functions for facilitating this design activity. First, it visualizes a simulated flight trajectory of the current bamboo-copter design, which is updated in real time during the user's editing. Second, it provides an optimization function that automatically tweaks the current bamboo-copter design such that the spin quality—how stably it spins—and the flight quality—how high and long it flies—are enhanced. To enable these functions, we present non-trivial extensions over existing techniques for designing free-formed model airplanes [UKSI14], including a wing discretization method tailored to free-formed bamboo-copters and an optimization scheme for achieving stable bamboo-copters considering both spin and flight qualities. [ABSTRACT FROM AUTHOR]
RAPID prototyping, THREE-dimensional printing, 3-D printers, COMPUTER graphics, and COMPUTER art
We present a pipeline of algorithms that decomposes a given polygon model into parts such that each part can be 3D printed with high (outer) surface quality. For this we exploit the fact that most 3D printing technologies have an anisotropic resolution and hence the surface smoothness varies significantly with the orientation of the surface. Our pipeline starts by segmenting the input surface into patches such that their normals can be aligned perpendicularly to the printing direction. A 3D Voronoi diagram is computed such that the intersections of the Voronoi cells with the surface approximate these surface patches. The intersections of the Voronoi cells with the input model's volume then provide an initial decomposition. We further present an algorithm to compute an assembly order for the parts and generate connectors between them. A post processing step further optimizes the seams between segments to improve the visual quality. We run our pipeline on a wide range of 3D models and experimentally evaluate the obtained improvements in terms of numerical, visual, and haptic quality. [ABSTRACT FROM AUTHOR]
RAPID prototyping, MASS production, THREE-dimensional printing, 3-D printers, and THERMOPLASTIC composites
The article reports that AREVO has appointed AGC Inc. as its strategic manufacturing partner in Japan. It mentions that the firm will provide MaaS for the on-demand production of ultra-strong, lightweight three-dimensional-printed composite parts for the Japanese market. It also mentions the comments of Hemant Bheda, Co-Founder and Chairman of AREVO.
RAPID prototyping, ELASTOMERS, 3-D printers, and THREE-dimensional printing
The article discusses the company Stratasys which is bringing to market advanced elastomers and enhanced materials for its leading Fused Granular Manufacturing (FDM) and Polyjet machines that are used in three-dimensional printing. It states that the FDM elastomer solution provides manufacturers with new levels of elasticity, durability with true soluble support, while advanced colors for Polyjet drive enhanced realism in transforming legacy design and prototyping processes.
RAPID prototyping, AIR quality, EMISSIONS (Air pollution), 3-D printers, and PHYSIOLOGICAL effects of nanoparticles
3D printers are currently widely available and very popular among the general public. However, the use of these devices may pose health risks to users, attributable to air-quality issues arising from gaseous and particulate emissions in particular. We characterized emissions from a low-end 3D printer based on material extrusion, using the most common polymers: acrylonitrile-butadiene-styrene (ABS) and polylactic acid (PLA). Measurements were carried out in an emission chamber and a conventional room. Particle emission rates were obtained by direct measurement and modeling, whereas the influence of extrusion temperature was also evaluated. ABS was the material with the highest aerosol emission rate. The nanoparticle emission ranged from 3.7·108 to 1.4·109 particles per second (# s−1) in chamber measurements and from 2.0·109 to 4.0·109 # s−1in room measurements, when the recommended extruder temperature was used. Printing with PLA emitted nanoparticles at the rate of 1.0·107 # s−1 inside the chamber and negligible emissions in room experiments. Emission rates were observed to depend strongly on extruder temperature. The particles' mean size ranged from 7.8 to 10.5 nanometers (nm). We also detected a significant emission rate of particles of 1 to 3 nm in size during all printing events. The amounts of volatile organic and other gaseous compounds were only traceable and are not expected to pose health risks. Our study suggests that measures preventing human exposure to high nanoparticle concentrations should be adopted when using low-end 3D printers. [ABSTRACT FROM AUTHOR]
This paper first reviews manufacturing technologies for realizing air-filled metal-pipe rectangular waveguides (MPRWGs) and 3-D printing for microwave and millimeter-wave applications. Then, 3-D printed MPRWGs are investigated in detail. Two very different 3-D printing technologies have been considered: low-cost lower-resolution fused deposition modeling for microwave applications and higher-cost high-resolution stereolithography for millimeter-wave applications. Measurements against traceable standards in MPRWGs were performed by the U.K.’s National Physical Laboratory. It was found that the performance of the 3-D printed MPRWGs were comparable with those of standard waveguides. For example, across X-band (8–12 GHz), the dissipative attenuation ranges between 0.2 and 0.6 dB/m, with a worst case return loss of 32 dB; at W-band (75–110 GHz), the dissipative attenuation was 11 dB/m at the band edges, with a worst case return loss of 19 dB. Finally, a high-performance W-band sixth-order inductive iris bandpass filter, having a center frequency of 107.2 GHz and a 6.8-GHz bandwidth, was demonstrated. The measured insertion loss of the complete structure (filter, feed sections, and flanges) was only 0.95 dB at center frequency, giving an unloaded quality factor of 152—clearly demonstrating the potential of this low-cost manufacturing technology, offering the advantages of lightweight rapid prototyping/manufacturing and relatively very low cost when compared with traditional (micro)machining. [ABSTRACT FROM PUBLISHER]
Contribution: The NEWTON fabrication laboratory (Fab Lab) Education Initiative assesses the effectiveness of Fab Lab-based learning on K–12 students’ attitude toward learning science, technology, engineering, art, and mathematics (STEAM). It considers two aspects: 1) students’ motivation and affective state and 2) students’ observations and perception of Fab Lab-based learning. Background: Fab Labs are described as small workshops equipped with a set of computer-controlled tools (e.g., 3-D printers) that offer personalized digital fabrication. They have been shown to have a positive impact on learners’ academic and personal growth when used in extracurricular activities, but little research examines whether integrating Fab Labs into school curricula can help raise student interest in STEAM education. Research Question: Can Fab Lab-based learning foster students’ interest in STEM in primary and secondary schools? Would students be keen to use Fab Labs in their science classes? Methodology: Two case studies were carried out in two different schools as part of the European Horizon 2020 NEWTON project. The study had 39 participants; three different surveys were used to assess different constructs. Findings: Results show that after using the Fab Lab-based learning: 1) students felt more interested in science classes as well as more engaged and less bored and 2) while some students struggled at first when manipulating Fab Lab tools, they adapted quickly and reported that they would like to use Fab Labs as part of their science classes. [ABSTRACT FROM AUTHOR]
The article discusses British-led advances in three-dimensional (3D) printing that could lead to techniques able to quickly produce entire electronic devices. Topics covered include the role of additive techniques in complementing manufacturing processes, progress in multifunctional 3D printing or 4D printing, Nottingham University researchers' focus on technology with less immediate commercial relevance, and the advantages of advanced jetting technologies.
RAPID prototyping, INDUSTRIAL safety, ELECTRIC drills, GLUE guns, 3-D printers, and EQUIPMENT & supplies
The article offers information on several tools used in a prototyping shop. Topics discussed include features of a standard rotary tool, uses of a hot glue gun and importance of a table saw. Also mentioned are the different types of three-dimensional (3D) printers and safety precautions when setting up a workspace for prototyping purposes.
The article presents questions and answers related to prototyping, including what is the most user-friendly 3D printers, what is the best way to prototype electronic components and how to provide recognizable proof of concept over aesthetic design.
RAPID prototyping, THREE-dimensional printing, 3-D printers, PRESSURE sensors, and DIGITAL printing
The article discusses the advantage for manufacturers to consider using 3D metal printing for flow and pressure sensors. Brief overview of the history of 3D printing and different industrial applications is explored. The development of quality standards for may of the 3D-metal printing alloys and processes, as well as its emerging methods, is also mentioned.
TECHNOLOGICAL innovations, RAPID prototyping, and 3-D printers
The article offers information on the ProMaker PI000 X SLS 3D printer developed by France-based Prodways Technologies, and notes that it is equipped to fabricate manufacturing jigs, brackets, and end-use components.
The article focuses on three dimensional (3D) printing in 2014 and discusses how it will impact manufacturing and design. Topics include how 3D printing has revolutionized the manufacturing of customizable components, increased accessibility to 3D printing by consumers, and how 3D printing will lessen industrial waste.
RAPID prototyping, THREE-dimensional printing, and 3-D printers
The article reports that R.D. Abbott Co. Inc., a California-based supplier of elastomer products and technical services, uses the liquid silicone rubber 3D printing technology, developed by German RepRap GmbH and Dow Performance Silicones, to cut down prototyping process. Topics discussed include remarks from Rick Ziebell, R.D. Abbott's vice president of technology, and potential benefit of the liquid additive manufacturing (LAM) 3D printing process.
Bulletin of the Association for Information Science & Technology. Oct/Nov2015, Vol. 42 Issue 1, p12-15. 4p.
RAPID prototyping, LIBRARIES, TECHNOLOGICAL innovations, COMMUNITY development, and 3-D printers
EDITOR'S SUMMARY Makerspaces are environments where crafters and techies can come together to create, share and learn. Many libraries support the maker movement by providing access to a variety of technologies from sewing machines and looms to recording equipment and production tools, an expansion of services that is in line with promoting literacy, community and lifelong learning. About one third of makerspaces charged a fee or required membership in 2013, though some, including libraries and museums, are supported by major funding agencies. Digital fabrication technology or 3D printers are increasingly available through library-based makerspaces and extend opportunities for STEM education, but libraries face challenges from high initial and ongoing costs, user training and even encouraging users in 3D thinking and design. 3D printers can be a powerful stimulus for creativity, learning and sharing, even promoting jobs and community development. [ABSTRACT FROM AUTHOR]