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Tb já esta com a dona, porém fica a dica pra interessadas em possuir um ;)
Como todos os acessórios da Maenga é HANDMADE, forrado por dentro com estampa de acordo com as cores de cada modelo, além de ter uma camada de feltro para deixa-lo firme e trazer segurança para seus objetos. Também pode servir como "cel bag".
The images you see here were all used at some stage on one of my own 3D CAD models. I made them all myself of course, and you are welcome to take whatever you like. I am a very "messy" modeler myself, and I model in order to get renderings, not necessarily perfectly crafted models. My pictures reflect that as well, and some may need editing for your purposes first. If some haven't quite got the right colour for your purpose, you know the trick, I presume: Photoshop, "Replace Colour" function.
All the best with your models.
3d animation of CAD model for addition to house.
Silver Lake Guest House
Project: The conversion of a storage shed into guest house
Location: Silver Lake, California
Designer: Jeremy Levine Design
Animated CAD model built in Vectorworks for a two story 'red box' addition to existing one story house.
Location: Eagle Rock, California.
Status: Completed 2008
Designer: Jeremy Levine
The BMW 8 Series (chassis code: E31) is a Grand Tourer built by BMW from 1989 to 1999 powered by either a V8 or V12 engine. While it did supplant the original E24 based 6 Series in 1991, a common misconception is that the 8 Series was developed as a successor. However, it was actually an entirely new class aimed at a different market, with a substantially higher price and better performance than the 6 series. It was BMW's flagship car and had an electronically limited top speed of 155 mph (250 km/h).
History of development
BMW E31 rear styling
Design of the 8 Series began in 1984, with the final design phase and production development (starting) in 1986. The 8 Series debuted at the Frankfurt Motor Show (IAA) in early September 1989. The 8 Series was designed to move beyond the market of the original 6 Series. The 8 Series however had substantially improved performance, as well as a far higher purchase price.
Over 1.5 billion Deutschemark was spent on total development (2008 USD nearly $1 billion). BMW used CAD tools, still unusual at the time, to design the car's all-new body. Combined with wind tunnel testing, the resulting car had a drag coefficient of 0.29, a major improvement from the previous BMW M6/635CSi's 0.39.
The 8 Series supercar offered the first V-12 engine mated to a 6-speed manual gearbox on a road car. It was also one of the first vehicles to be fitted with an electronic "drive-by-wire" throttle. The 8 Series was one of BMW's first cars, together with the Z1, to use a multi-link rear axle.
While CAD modeling allowed the car's unibody to be 8 lb (3 kg) lighter than that of its predecessor, the car was significantly heavier when completed due to the large engine and added luxury items—a source of criticism from those who wanted BMW to concentrate on the driving experience. Some of the car's weight may have been due to its pillarless "hardtop" body style, which lacked a "B" post. This body style, originating in the United States in the late 1940s, was abandoned by Detroit in the late 1970s.
Sales of the 8 Series were affected by the global recession of the early 1990s, the Persian Gulf War, and energy price spikes. BMW pulled the 8 Series from the North American market in 1997, having sold only 7,232 cars over seven years. BMW continued production for Europe until 1999.
850i
BMW 850i/Ci M70 V12 engine
This was the first model launched in 1990 with the 5 litre M70B50 V12 engine producing 300 PS (221 kW; 296 hp). It was available with either a 4-speed automatic or a 6-speed manual gearbox.
[Text taken from Wikipedia]
This Lego miniland-scale BMW 850i Coupe has been created for Flickr LUGNuts' 85th Build Challenge, - "Like, Totally 80s", - all about cars created during the decade of the 1980s. The BMW 850i just slips in right at the end, launching late in 1989.
3d animation of CAD model for addition to house.
Location: Silver Lake, CA
Status: Completed 2007
Designer: Jeremy Levine
Selective Laser Melting (SLM) is an additive manufacturing process that can be used for many different applications.
The SLM process starts by numerically slicing a 3D CAD model into a number of finite layers. For each sliced layer a laser scan path is calculated which defines both the boundary contour and some form of fill sequence, often a raster pattern. Each layer is then sequentially recreated by depositing powder layers, one on top of the other, and melting their surface by scanning a laser beam.
The powder is spread uniformly by a wiper. A high power-density fibre laser with a 40µm beam spot size fully melts the pre-deposited powder layer. The melted particles fuse and solidify to form a layer of the component.
For more information please visit www.twi-global.com/technologies/welding-surface-engineeri...
If you wish to use this image each use should be accompanied by the credit line and notice, "Courtesy of TWI Ltd".
The 3D-Bioplotter® System is a versatile rapid prototyping tool for processing a great variety of biomaterials for computer-aided tissue engineering (CATE), from 3D CAD models and patient CT data to the physical 3D scaffold with a designed and defined outer form and an open inner structure. The 3D-Bioplotter® has the capacity of fabricating scaffolds using the widest range of materials of any singular rapid prototyping machine, from soft hydrogels over polymer melts up to hard ceramics and metals. Complex inner patterns can easily be designed using the 3D-Bioplotter® software to control the mechanical properties, increase cell adhesion, as well as improve the flow of nutrient media throughout the interconnecting pores of the printed implants.
3D-Bioplotter®
envisiontec.com/3d-printers/3d-bioplotter/
About Center for Biomaterials at Rutgers, The State University of New Jersey
Center for Biomaterials is a Multidisciplinary Center of Excellence for Tissue Engineering, Regenerative Medicine, Drug Delivery, Medical Devices, and Workforce Development based at Rutgers, The State University of New Jersey - that spans academia, industry and government.
As biomaterials scientists, our goal is to conduct state-of-the-art research in biomaterials science and engineering and to improve health care and the quality of life by developing advanced biomedical products for tissue repair and replacement, and the delivery of pharmaceutical agents. Our advanced research projects with licensing or partnering opportunities are in bone, nerve, drug delivery and X-ray visible medical implants. Our technologies have been translated into pre-clinical and clinical products, including a fully resorbable and x-ray visible coronary stent, an antimicrobial implant for the prevention of pacemaker infections, a surgical mesh for hernia repair, a bone regeneration scaffold and an ocular drug delivery system for the treatment of inflammatory eye disorders.
We have collaborations using additive manufacturing (3D printing), polymer processing, and scale-up of polymer synthesis. Our major facilities include certified class 10,000 (EN/ISO-14644 Class 7 US federal Standard 209) cleanroom. We have a large network of 60+ Industry collaborators and 30+ National and International Institutions. NJCBM also provides educational and workforce training for scientists and students in biomaterials and regenerative medicine and hosts Annual Symposia on "Biomaterials Science."
About Rutgers, The State University of New Jersey
Rutgers, The State University of New Jersey, is a leading national research university and the state of New Jersey's preeminent, comprehensive public institution of higher education. Established in 1766, the university is the eighth oldest higher education institution in the United States. Nearly 69,000 students and 22,000 full- and part-time faculty and staff learn, work, and serve the public at Rutgers locations across New Jersey and around the world. The university belongs to the Big Ten Academic Alliance, comprised of 14 world-class research universities, and is among the top 20 public U.S. universities for total R&D funding. Rutgers University-New Brunswick is the state's only public institution in the prestigious Association of American Universities.
As the premier public research university in the state, Rutgers is dedicated to teaching that meets the highest standards of excellence, to conducting cutting-edge research that breaks new ground and aids the state's economy, businesses, and industries, and to providing services, solutions, and clinical care that help individuals and the local, national, and global communities where they live. ored.rutgers.edu
Animated CAD model built in Vectorworks for a guest house.
Location: South Royalton, Vermont
Status: Completed 2005
Designer: Jeremy Levine
Selective Laser Melting (SLM) is an additive manufacturing process that can be used for many different applications.
The SLM process starts by numerically slicing a 3D CAD model into a number of finite layers. For each sliced layer a laser scan path is calculated which defines both the boundary contour and some form of fill sequence, often a raster pattern. Each layer is then sequentially recreated by depositing powder layers, one on top of the other, and melting their surface by scanning a laser beam.
The powder is spread uniformly by a wiper. A high power-density fibre laser with a 40µm beam spot size fully melts the pre-deposited powder layer. The melted particles fuse and solidify to form a layer of the component.
For more information please visit www.twi-global.com/technologies/welding-surface-engineeri...
If you wish to use this image each use should be accompanied by the credit line and notice, "Courtesy of TWI Ltd".
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40 designs chronologically ordered. It was immense fun to create these for various outlets, including my own creative outlet.
Camión Pegaso Europa con matrícula de 1977. Cada modelo de Pegaso tiene su encanto, pero ahora pienso que el Europa alcanzó nada menos que el Clasicismo en toda la gama.
Foto: 2012, Iurreta (BI).
I really love this model. The next step after the "Comet".
Coe, Brian. “Kodak Cameras - The first Hundred Years". Hove Books; 2ª Edición, 2009. 310 páginas. Idioma: Inglés. ISBN-10: 1874707375 / ISBN-13: 978-1874707370.
Este libro es imprescindible para cualquier interesado en conocer la práctica totalidad de los modelos que la Kodak produjo a lo largo de sus primeros 100 años de existencia.
El conocimiento del autor y su contrastado rigor está fuera de toda duda, convirtiendo esta guía en una eficaz herramienta de consulta para coleccionistas que deseen identificar y/o documentar cualquiera de los más de 600 modelos producidos y comercializados por la que fue la mayor organización de la industria fotográfica y también líder en ventas durante dos tercios del siglo XX.
Estructurado en 7 capítulos de acuerdo con el tipo de cámara (*). Incluye una introducción histórica y descriptiva sobre el tipo, formato o gama en particular, ofreciendo para cada modelo de cámara una ficha técnica que, acompañada de la imagen, indica el lugar de producción, los años de comercialización, ópticas y mecanismos de obturación implementados así como, en bastantes de ellas, hasta el número de unidades producidas. Todo ello complementado con unas sucintas reseñas para cada una y unos útiles apéndices finales con la codificación y fecha de aparición de cada tipo de formato de película y sus dimensiones.
(*) El libro contiene los siguientes apartados o capítulos: * Kodak Box and Solid Body Cameras * Brownie Box Cameras * Kodak Folding Cameras * Brownie Folding Cameras * Kodak 35mm Cameras - Kodak Retina Cameras * Kodak Cartridge Loading Film Cameras –Kodak Instamatic 126 Cameras - Kodak Pocket 110 Cameras – Kodak Disc Cameras * Kodak Instant Cameras * Kodak Plate Cameras * Kodak Special and Curiosities. Glosario Appendix I: Hawk Eye Cameras, Premo cameras, Folmer and Schwing Cameras y Appendix II: Rollfilm sizes, Autographic Films, Film Packs.
Finalmente, reseñar que su autor, el inglés Brian Coe (1930-2007), entró con solo 17 años a trabajar para Kodak, convirtiéndose años más tarde en conservador de su museo, desempeñando tiempo después idénticas funciones para la Royal Photographic Society. Era un erudito historiador de la tecnología fotográfica y un insigne divulgador y apasionado de la misma, siendo autor de libros de referencia entre los que cabe destacar The Birth of Photography (1976), Colour Photography (1978), The History of Movie Photography (1981) o la excelente y quizás obra cumbre de la historiografía fotográfica "CAMERAS From Daguerreotypes to Instant Pictures" (1978). Esta labor como escritor la simultaneó también como narrador para la BBC de la serie Pioneers of Photography (1975) y como comisario de infinidad de exposiciones. Lamentablemente, falleció victima de un infarto a los 76 años en octubre de 2007 pero nos ha dejado en sus libros el conocimiento y la pasión por las cámaras.
Animated CAD model built in Vectorworks for a 'green' remodel and addition to a house.
Location: Eagle Rock, California.
Status: Completed 2008
Designer: Jeremy Levine
A Hey é um coletivo de cinco designers paulistanos que produzem uma quantidade limitada de bottons em uma coleção variada, original e única.
Os Bottons são impressos em qualidade fotográfica e possuem suporte metálico (para os bottons de 3,5cm de diâmetro).
De tempos em tempos novas coleções serão lançadas e o nosso flickr será o primeiro a ser atualizado.
COMO COMPRAR?
1 - Anote o nome e a quantidade desejada de cada modelo de botton. (OBS: A quantidade mínima de cada pedido é de 5 Bottons)
2 - Mande um email com os códigos, quantidades e SEU ENDEREÇO COMPLETO para hey.bottons@gmail.com
3 - Você receberá um email com o preço do pedido (O valor de cada botton é R$3,00) e o preço do frete. Assim como os dados para o depósito bancário.
O Pedido será enviado em no máximo 3 dias úteis após a confirmação do pagamento. Para pedidos em quantidades maiores, favor consultar o prazo.
...................
Participam da Hey:
Rômulo Castilho - flickr.com/photos/romully
Natasha Weissenborn - flickr.com/photos/findela
Samantha Capatti - flickr.com/photos/samanthacapatti
Laura Mascarenhas - flickr.com/photos/lauramascarenhas
Halinni Lopes - flickr.com/photos/halinnilopes
The 3D-Bioplotter® System is a versatile rapid prototyping tool for processing a great variety of biomaterials for computer-aided tissue engineering (CATE), from 3D CAD models and patient CT data to the physical 3D scaffold with a designed and defined outer form and an open inner structure. The 3D-Bioplotter® has the capacity of fabricating scaffolds using the widest range of materials of any singular rapid prototyping machine, from soft hydrogels over polymer melts up to hard ceramics and metals. Complex inner patterns can easily be designed using the 3D-Bioplotter® software to control the mechanical properties, increase cell adhesion, as well as improve the flow of nutrient media throughout the interconnecting pores of the printed implants.
3D-Bioplotter®
envisiontec.com/3d-printers/3d-bioplotter/
About Center for Biomaterials at Rutgers, The State University of New Jersey
Center for Biomaterials is a Multidisciplinary Center of Excellence for Tissue Engineering, Regenerative Medicine, Drug Delivery, Medical Devices, and Workforce Development based at Rutgers, The State University of New Jersey - that spans academia, industry and government.
As biomaterials scientists, our goal is to conduct state-of-the-art research in biomaterials science and engineering and to improve health care and the quality of life by developing advanced biomedical products for tissue repair and replacement, and the delivery of pharmaceutical agents. Our advanced research projects with licensing or partnering opportunities are in bone, nerve, drug delivery and X-ray visible medical implants. Our technologies have been translated into pre-clinical and clinical products, including a fully resorbable and x-ray visible coronary stent, an antimicrobial implant for the prevention of pacemaker infections, a surgical mesh for hernia repair, a bone regeneration scaffold and an ocular drug delivery system for the treatment of inflammatory eye disorders.
We have collaborations using additive manufacturing (3D printing), polymer processing, and scale-up of polymer synthesis. Our major facilities include certified class 10,000 (EN/ISO-14644 Class 7 US federal Standard 209) cleanroom. We have a large network of 60+ Industry collaborators and 30+ National and International Institutions. NJCBM also provides educational and workforce training for scientists and students in biomaterials and regenerative medicine and hosts Annual Symposia on "Biomaterials Science."
About Rutgers, The State University of New Jersey
Rutgers, The State University of New Jersey, is a leading national research university and the state of New Jersey's preeminent, comprehensive public institution of higher education. Established in 1766, the university is the eighth oldest higher education institution in the United States. Nearly 69,000 students and 22,000 full- and part-time faculty and staff learn, work, and serve the public at Rutgers locations across New Jersey and around the world. The university belongs to the Big Ten Academic Alliance, comprised of 14 world-class research universities, and is among the top 20 public U.S. universities for total R&D funding. Rutgers University-New Brunswick is the state's only public institution in the prestigious Association of American Universities.
As the premier public research university in the state, Rutgers is dedicated to teaching that meets the highest standards of excellence, to conducting cutting-edge research that breaks new ground and aids the state's economy, businesses, and industries, and to providing services, solutions, and clinical care that help individuals and the local, national, and global communities where they live. ored.rutgers.edu
The images you see here were all used at some stage on one of my own 3D CAD models. I made them all myself of course, and you are welcome to take whatever you like. I am a very "messy" modeler myself, and I model in order to get renderings, not necessarily perfectly crafted models. My pictures reflect that as well, and some may need editing for your purposes first. If some haven't quite got the right colour for your purpose, you know the trick, I presume: Photoshop, "Replace Colour" function.
All the best with your models.
Available on the Turbosquid 3D marketplace: highly detailed and accurate 3D model of the Samsung Galaxy S10E.
File formats included:
3dsmax 2014 (native)
3dsmax 2010
C4DR18
Maya 2016
OBJ + 3DS + FBX
with Vray 3.4 shaders for 3dsmax 2014 and Maya 2016 versions
Download link:
www.turbosquid.com/3d-models/samsung-galaxy-s10e-3d-model...
The images you see here were all used at some stage on one of my own 3D CAD models. I made them all myself of course, and you are welcome to take whatever you like. I am a very "messy" modeler myself, and I model in order to get renderings, not necessarily perfectly crafted models. My pictures reflect that as well, and some may need editing for your purposes first. If some haven't quite got the right colour for your purpose, you know the trick, I presume: Photoshop, "Replace Colour" function.
All the best with your models.
Available on the Turbosquid 3D marketplace: highly detailed and accurate 3D model of the Samsung Galaxy S10E.
File formats included:
3dsmax 2014 (native)
3dsmax 2010
C4DR18
Maya 2016
OBJ + 3DS + FBX
with Vray 3.4 shaders for 3dsmax 2014 and Maya 2016 versions
Download link:
www.turbosquid.com/3d-models/samsung-galaxy-s10e-3d-model...
Highly detailed 3D CAD models of the new Samsung Galaxy S10.
Included in the pack:
- galaxy S10 lite
- galaxy S10
- galaxy S10 plus
File formats:
- 3dsmax 2014
- Maya 2016
- C4D R18
- 3ds + fbx + obj + textures
with vray 3.4 versions
Download it here:
Selective Laser Melting (SLM) is an additive manufacturing process that can be used for many different applications.
The SLM process starts by numerically slicing a 3D CAD model into a number of finite layers. For each sliced layer a laser scan path is calculated which defines both the boundary contour and some form of fill sequence, often a raster pattern. Each layer is then sequentially recreated by depositing powder layers, one on top of the other, and melting their surface by scanning a laser beam.
The powder is spread uniformly by a wiper. A high power-density fibre laser with a 40µm beam spot size fully melts the pre-deposited powder layer. The melted particles fuse and solidify to form a layer of the component.
For more information please visit www.twi-global.com/technologies/welding-surface-engineeri...
If you wish to use this image each use should be accompanied by the credit line and notice, "Courtesy of TWI Ltd".
The 3D-Bioplotter® System is a versatile rapid prototyping tool for processing a great variety of biomaterials for computer-aided tissue engineering (CATE), from 3D CAD models and patient CT data to the physical 3D scaffold with a designed and defined outer form and an open inner structure. The 3D-Bioplotter® has the capacity of fabricating scaffolds using the widest range of materials of any singular rapid prototyping machine, from soft hydrogels over polymer melts up to hard ceramics and metals. Complex inner patterns can easily be designed using the 3D-Bioplotter® software to control the mechanical properties, increase cell adhesion, as well as improve the flow of nutrient media throughout the interconnecting pores of the printed implants.
3D-Bioplotter®
envisiontec.com/3d-printers/3d-bioplotter/
About Center for Biomaterials at Rutgers, The State University of New Jersey
Center for Biomaterials is a Multidisciplinary Center of Excellence for Tissue Engineering, Regenerative Medicine, Drug Delivery, Medical Devices, and Workforce Development based at Rutgers, The State University of New Jersey - that spans academia, industry and government.
As biomaterials scientists, our goal is to conduct state-of-the-art research in biomaterials science and engineering and to improve health care and the quality of life by developing advanced biomedical products for tissue repair and replacement, and the delivery of pharmaceutical agents. Our advanced research projects with licensing or partnering opportunities are in bone, nerve, drug delivery and X-ray visible medical implants. Our technologies have been translated into pre-clinical and clinical products, including a fully resorbable and x-ray visible coronary stent, an antimicrobial implant for the prevention of pacemaker infections, a surgical mesh for hernia repair, a bone regeneration scaffold and an ocular drug delivery system for the treatment of inflammatory eye disorders.
We have collaborations using additive manufacturing (3D printing), polymer processing, and scale-up of polymer synthesis. Our major facilities include certified class 10,000 (EN/ISO-14644 Class 7 US federal Standard 209) cleanroom. We have a large network of 60+ Industry collaborators and 30+ National and International Institutions. NJCBM also provides educational and workforce training for scientists and students in biomaterials and regenerative medicine and hosts Annual Symposia on "Biomaterials Science."
About Rutgers, The State University of New Jersey
Rutgers, The State University of New Jersey, is a leading national research university and the state of New Jersey's preeminent, comprehensive public institution of higher education. Established in 1766, the university is the eighth oldest higher education institution in the United States. Nearly 69,000 students and 22,000 full- and part-time faculty and staff learn, work, and serve the public at Rutgers locations across New Jersey and around the world. The university belongs to the Big Ten Academic Alliance, comprised of 14 world-class research universities, and is among the top 20 public U.S. universities for total R&D funding. Rutgers University-New Brunswick is the state's only public institution in the prestigious Association of American Universities.
As the premier public research university in the state, Rutgers is dedicated to teaching that meets the highest standards of excellence, to conducting cutting-edge research that breaks new ground and aids the state's economy, businesses, and industries, and to providing services, solutions, and clinical care that help individuals and the local, national, and global communities where they live. ored.rutgers.edu
The 3D-Bioplotter® System is a versatile rapid prototyping tool for processing a great variety of biomaterials for computer-aided tissue engineering (CATE), from 3D CAD models and patient CT data to the physical 3D scaffold with a designed and defined outer form and an open inner structure. The 3D-Bioplotter® has the capacity of fabricating scaffolds using the widest range of materials of any singular rapid prototyping machine, from soft hydrogels over polymer melts up to hard ceramics and metals. Complex inner patterns can easily be designed using the 3D-Bioplotter® software to control the mechanical properties, increase cell adhesion, as well as improve the flow of nutrient media throughout the interconnecting pores of the printed implants.
3D-Bioplotter®
envisiontec.com/3d-printers/3d-bioplotter/
About Center for Biomaterials at Rutgers, The State University of New Jersey
Center for Biomaterials is a Multidisciplinary Center of Excellence for Tissue Engineering, Regenerative Medicine, Drug Delivery, Medical Devices, and Workforce Development based at Rutgers, The State University of New Jersey - that spans academia, industry and government.
As biomaterials scientists, our goal is to conduct state-of-the-art research in biomaterials science and engineering and to improve health care and the quality of life by developing advanced biomedical products for tissue repair and replacement, and the delivery of pharmaceutical agents. Our advanced research projects with licensing or partnering opportunities are in bone, nerve, drug delivery and X-ray visible medical implants. Our technologies have been translated into pre-clinical and clinical products, including a fully resorbable and x-ray visible coronary stent, an antimicrobial implant for the prevention of pacemaker infections, a surgical mesh for hernia repair, a bone regeneration scaffold and an ocular drug delivery system for the treatment of inflammatory eye disorders.
We have collaborations using additive manufacturing (3D printing), polymer processing, and scale-up of polymer synthesis. Our major facilities include certified class 10,000 (EN/ISO-14644 Class 7 US federal Standard 209) cleanroom. We have a large network of 60+ Industry collaborators and 30+ National and International Institutions. NJCBM also provides educational and workforce training for scientists and students in biomaterials and regenerative medicine and hosts Annual Symposia on "Biomaterials Science."
About Rutgers, The State University of New Jersey
Rutgers, The State University of New Jersey, is a leading national research university and the state of New Jersey's preeminent, comprehensive public institution of higher education. Established in 1766, the university is the eighth oldest higher education institution in the United States. Nearly 69,000 students and 22,000 full- and part-time faculty and staff learn, work, and serve the public at Rutgers locations across New Jersey and around the world. The university belongs to the Big Ten Academic Alliance, comprised of 14 world-class research universities, and is among the top 20 public U.S. universities for total R&D funding. Rutgers University-New Brunswick is the state's only public institution in the prestigious Association of American Universities.
As the premier public research university in the state, Rutgers is dedicated to teaching that meets the highest standards of excellence, to conducting cutting-edge research that breaks new ground and aids the state's economy, businesses, and industries, and to providing services, solutions, and clinical care that help individuals and the local, national, and global communities where they live. ored.rutgers.edu
This project deals with parts reduction in automobiles. As it stands, this car consists of 114 parts - total. Feel free to count them in my CAD model, and that even includes 20 wheel nuts. Making this possible has been an exercise in unconventional thinking, as you can well imagine just by looking at the pictures. This car has almost nothing other cars have. I've found ways to do away with differentials, doors, and hundreds of single components normally required in a car. This effort even extends to the controls side. It is an electric 3-wheeler with purely mechanical control mechanisms and a drive setup I believe to have invented entirely myself. This could be the cheapest car ever.
Selective laser melting is an AM process that uses a laser to selectively melt and fuse sections of a layer of powder onto a substrate. After each layer is fused, the substrate is retracted vertically, another even layer of powder is spread across the top, and the process repeats.
The path of the laser is determined by a CAD model that is sliced into layers less than 100µm thick using specialist software. Selective laser melting takes place in a vacuum chamber filled with inert gas, to prevent oxidisation of the powder. Unused powder can be recycled and used for the next build.
For more information please visit www.twiadditivemanufacturing.com/capabilities/metal-proce...
If you wish to use this image each use should be accompanied by the credit line and notice, "Courtesy of TWI Ltd".
Selective Laser Melting (SLM) is an additive manufacturing process that can be used for many different applications.
The SLM process starts by numerically slicing a 3D CAD model into a number of finite layers. For each sliced layer a laser scan path is calculated which defines both the boundary contour and some form of fill sequence, often a raster pattern. Each layer is then sequentially recreated by depositing powder layers, one on top of the other, and melting their surface by scanning a laser beam.
The powder is spread uniformly by a wiper. A high power-density fibre laser with a 40µm beam spot size fully melts the pre-deposited powder layer. The melted particles fuse and solidify to form a layer of the component.
For more information please visit www.twi-global.com/technologies/welding-surface-engineeri...
If you wish to use this image each use should be accompanied by the credit line and notice, "Courtesy of TWI Ltd".
Selective Laser Melting (SLM) is an additive manufacturing process that can be used for many different applications.
The SLM process starts by numerically slicing a 3D CAD model into a number of finite layers. For each sliced layer a laser scan path is calculated which defines both the boundary contour and some form of fill sequence, often a raster pattern. Each layer is then sequentially recreated by depositing powder layers, one on top of the other, and melting their surface by scanning a laser beam.
The powder is spread uniformly by a wiper. A high power-density fibre laser with a 40µm beam spot size fully melts the pre-deposited powder layer. The melted particles fuse and solidify to form a layer of the component.
For more information please visit www.twi-global.com/technologies/welding-surface-engineeri...
If you wish to use this image each use should be accompanied by the credit line and notice, "Courtesy of TWI Ltd".
Selective Laser Melting (SLM) is an additive manufacturing process that can be used for many different applications.
The SLM process starts by numerically slicing a 3D CAD model into a number of finite layers. For each sliced layer a laser scan path is calculated which defines both the boundary contour and some form of fill sequence, often a raster pattern. Each layer is then sequentially recreated by depositing powder layers, one on top of the other, and melting their surface by scanning a laser beam.
The powder is spread uniformly by a wiper. A high power-density fibre laser with a 40µm beam spot size fully melts the pre-deposited powder layer. The melted particles fuse and solidify to form a layer of the component.
For more information please visit www.twi-global.com/technologies/welding-surface-engineeri...
If you wish to use this image each use should be accompanied by the credit line and notice, "Courtesy of TWI Ltd".
The 3D-Bioplotter® System is a versatile rapid prototyping tool for processing a great variety of biomaterials for computer-aided tissue engineering (CATE), from 3D CAD models and patient CT data to the physical 3D scaffold with a designed and defined outer form and an open inner structure. The 3D-Bioplotter® has the capacity of fabricating scaffolds using the widest range of materials of any singular rapid prototyping machine, from soft hydrogels over polymer melts up to hard ceramics and metals. Complex inner patterns can easily be designed using the 3D-Bioplotter® software to control the mechanical properties, increase cell adhesion, as well as improve the flow of nutrient media throughout the interconnecting pores of the printed implants.
3D-Bioplotter®
envisiontec.com/3d-printers/3d-bioplotter/
About Center for Biomaterials at Rutgers, The State University of New Jersey
Center for Biomaterials is a Multidisciplinary Center of Excellence for Tissue Engineering, Regenerative Medicine, Drug Delivery, Medical Devices, and Workforce Development based at Rutgers, The State University of New Jersey - that spans academia, industry and government.
As biomaterials scientists, our goal is to conduct state-of-the-art research in biomaterials science and engineering and to improve health care and the quality of life by developing advanced biomedical products for tissue repair and replacement, and the delivery of pharmaceutical agents. Our advanced research projects with licensing or partnering opportunities are in bone, nerve, drug delivery and X-ray visible medical implants. Our technologies have been translated into pre-clinical and clinical products, including a fully resorbable and x-ray visible coronary stent, an antimicrobial implant for the prevention of pacemaker infections, a surgical mesh for hernia repair, a bone regeneration scaffold and an ocular drug delivery system for the treatment of inflammatory eye disorders.
We have collaborations using additive manufacturing (3D printing), polymer processing, and scale-up of polymer synthesis. Our major facilities include certified class 10,000 (EN/ISO-14644 Class 7 US federal Standard 209) cleanroom. We have a large network of 60+ Industry collaborators and 30+ National and International Institutions. NJCBM also provides educational and workforce training for scientists and students in biomaterials and regenerative medicine and hosts Annual Symposia on "Biomaterials Science."
About Rutgers, The State University of New Jersey
Rutgers, The State University of New Jersey, is a leading national research university and the state of New Jersey's preeminent, comprehensive public institution of higher education. Established in 1766, the university is the eighth oldest higher education institution in the United States. Nearly 69,000 students and 22,000 full- and part-time faculty and staff learn, work, and serve the public at Rutgers locations across New Jersey and around the world. The university belongs to the Big Ten Academic Alliance, comprised of 14 world-class research universities, and is among the top 20 public U.S. universities for total R&D funding. Rutgers University-New Brunswick is the state's only public institution in the prestigious Association of American Universities.
As the premier public research university in the state, Rutgers is dedicated to teaching that meets the highest standards of excellence, to conducting cutting-edge research that breaks new ground and aids the state's economy, businesses, and industries, and to providing services, solutions, and clinical care that help individuals and the local, national, and global communities where they live. ored.rutgers.edu
Printed on the EnvisionTEC 3D Bioplotter by Shah Lab at Northwestern University for tissue and organ regeneration.
The 3D-Bioplotter® System is a versatile rapid prototyping tool for processing a great variety of biomaterials for computer-aided tissue engineering (CATE), from 3D CAD models and patient CT data to the physical 3D scaffold with a designed and defined outer form and an open inner structure. The 3D-Bioplotter® has the capacity of fabricating scaffolds using the widest range of materials of any singular rapid prototyping machine, from soft hydrogels over polymer melts up to hard ceramics and metals. Complex inner patterns can easily be designed using the 3D-Bioplotter® software to control the mechanical properties, increase cell adhesion, as well as improve the flow of nutrient media throughout the interconnecting pores of the printed implants.
3D-Bioplotter®
envisiontec.com/3d-printers/3d-bioplotter/
Shah TEAM lab
The images you see here were all used at some stage on one of my own 3D CAD models. I made them all myself of course, and you are welcome to take whatever you like. I am a very "messy" modeler myself, and I model in order to get renderings, not necessarily perfectly crafted models. My pictures reflect that as well, and some may need editing for your purposes first. If some haven't quite got the right colour for your purpose, you know the trick, I presume: Photoshop, "Replace Colour" function.
All the best with your models.
The images you see here were all used at some stage on one of my own 3D CAD models. I made them all myself of course, and you are welcome to take whatever you like. I am a very "messy" modeler myself, and I model in order to get renderings, not necessarily perfectly crafted models. My pictures reflect that as well, and some may need editing for your purposes first. If some haven't quite got the right colour for your purpose, you know the trick, I presume: Photoshop, "Replace Colour" function.
All the best with your models.
Shortly after building my TSB-2555B Alice microphone I added a high frequency EQ mod according to Ricardo Lee's document from groups.yahoo.com/neo/groups/micbuilders
A couple of months after that I started looking into voice acting. I have no aspirations of changing careers at this point, but I've been reading to my kids for close to eighteen years now, and one by one they're starting to leave the nest. By the end of the summer the only way I'll be able to read to my oldest is if I record each session and email the file. Hence the interest in voice acting.
Turns out the Alice makes a really nice voice mic. And turns out I might need the option to turn the HF EQ off for certain voices.
So I contacted Ricardo Lee to ask if I could wire his HF EQ mod through a switch, letting me have it as an option rather than a default. He said the circuit isn't particularly noise sensitive, and that he didn't think there would be any problems.
So I picked a switch that let me have three configurations: no HF EQ, Ricardo's HF EQ to make the mic sound more like a U87, and one more that I haven't committed to yet. (I'll figure out how to wire that once I figure out which voices I need to EQ for.)
The fun part about adding the switch to the BM-800 Alice was how to mount it. I went back to the 3D CAD model I made of the mic, added the switch, and found I could fit some aluminum angle across the mounting holes on the opposite side from the PCB.
But how to make the top round? And how to get the 2.3 degree taper?
I wound up building a lathe fixture to cut the profile. It worked like a charm.
The switch isn't the most convenient thing in the world, since I have to take the body tube off the mic to change its position. But it's not something you want to switch on the fly, so I think it'll work out ok.
Now I want to build a couple more of these!
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Available on the Turbosquid 3D marketplace: highly detailed and accurate 3D model of the Samsung Galaxy S10E.
File formats included:
3dsmax 2014 (native)
3dsmax 2010
C4DR18
Maya 2016
OBJ + 3DS + FBX
with Vray 3.4 shaders for 3dsmax 2014 and Maya 2016 versions
Download link:
www.turbosquid.com/3d-models/samsung-galaxy-s10e-3d-model...
Highly detailed 3D CAD models of the new Samsung Galaxy S10.
Included in the pack:
- galaxy S10 lite
- galaxy S10
- galaxy S10 plus
File formats:
- 3dsmax 2014
- Maya 2016
- C4D R18
- 3ds + fbx + obj + textures
with vray 3.4 versions
Download it here:
3D CAD Model drawn in Vectorworks
Silver Lake Guest House
Project: The conversion of a storage shed into guest house
Location: Silver Lake, California
Designer: Jeremy Levine
The 3D-Bioplotter® System is a versatile rapid prototyping tool for processing a great variety of biomaterials for computer-aided tissue engineering (CATE), from 3D CAD models and patient CT data to the physical 3D scaffold with a designed and defined outer form and an open inner structure. The 3D-Bioplotter® has the capacity of fabricating scaffolds using the widest range of materials of any singular rapid prototyping machine, from soft hydrogels over polymer melts up to hard ceramics and metals. Complex inner patterns can easily be designed using the 3D-Bioplotter® software to control the mechanical properties, increase cell adhesion, as well as improve the flow of nutrient media throughout the interconnecting pores of the printed implants.
3D-Bioplotter®
Printed on the EnvisionTEC 3D Bioplotter by Shah TEAM lab at Northwestern University.
The 3D-Bioplotter® System is a versatile rapid prototyping tool for processing a great variety of biomaterials for computer-aided tissue engineering (CATE), from 3D CAD models and patient CT data to the physical 3D scaffold with a designed and defined outer form and an open inner structure. The 3D-Bioplotter® has the capacity of fabricating scaffolds using the widest range of materials of any singular rapid prototyping machine, from soft hydrogels over polymer melts up to hard ceramics and metals. Complex inner patterns can easily be designed using the 3D-Bioplotter® software to control the mechanical properties, increase cell adhesion, as well as improve the flow of nutrient media throughout the interconnecting pores of the printed implants.
3D-Bioplotter®
envisiontec.com/3d-printers/3d-bioplotter/
Shah TEAM lab
Se pueden hacer pedidos de cada modelo y con cambio en los colores.
No hay más botones iguales, se cambiará por parecido.
La calidad de las fotos es bastante mala, si teneis dudas sobre el color u otra cosa podeis consultarmelo.
Consultar precios y demás enviadme un e-mail a:
brochestitare@yahoo.es o en jaione_00@hotmail.com
Highly detailed 3D CAD models of the new Samsung Galaxy S10.
Included in the pack:
- galaxy S10 lite
- galaxy S10
- galaxy S10 plus
File formats:
- 3dsmax 2014
- Maya 2016
- C4D R18
- 3ds + fbx + obj + textures
with vray 3.4 versions
Download it here:
The images you see here were all used at some stage on one of my own 3D CAD models. I made them all myself of course, and you are welcome to take whatever you like. I am a very "messy" modeler myself, and I model in order to get renderings, not necessarily perfectly crafted models. My pictures reflect that as well, and some may need editing for your purposes first. If some haven't quite got the right colour for your purpose, you know the trick, I presume: Photoshop, "Replace Colour" function.
All the best with your models.