Patents

3D Print metal parts

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According to The Virtual Foundry, “3D Print metal parts. Our patented high-density metal filaments can be used in any 3D printer. In fact, our materials can be used without requiring specialized 3D printers or modifications.

The Virtual Foundry sells a range of metal filled filament materials including Rapid 3D Shield Tungsten Filament. In fact, Tungsten Filament has the highest density in the industry.

These materials can be used in a range of industries including manufacturing, prototyping, and radiation shielding. It protects from radiation shielding using any 3D printer and our metal filaments are affordable, easy, and safe. ”

WE ARE THE VIRTUAL FOUNDRY

Physna: Compare thousands of 3D models in seconds

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Physna: Compare thousands of 3D models in seconds,
According to Physna’s CEO Paul Powers and Glenn Warner, “Through revolutionary artificial intelligence, Physna uses advanced algorithms to dissect and analyze 3D objects in the blink of an eye.
Many companies have collectively spent billions of dollars on this problem. The reason that Physna is the first to actually fix it is that we used a fundamentally different type of technology.
Compare your IP with others in seconds, ensuring that you’re using the correct models and nobody else is using your designs. Promptly determine if a 3D object matches your standards, allowing you to get to market quicker. Find any 3D object in seconds, old or new, helping to keep department and operation costs to a minimum. Compare any two models instantly and see exactly how much they match with total accuracy and reliability. We call those facets. Everything in nature can be broken down into triangles. We basically analyze the relationship of facets to each other and to the surrounding environment.”

Physna_Logo_Color_2x.png

Don’t phear the phunny name: Physna could soon be a $1 billion software company

The Midwest is the opportunity of our lifetime

 

Physna raises $6.9 million to develop “Google of 3D models”

3D printing startup company Fortify raises $10 million

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The Fortify was founded on research on composite 3D printing by Randall Erb and Joshua Martin at Northeastern University. Their goal was to enable quick and seamless fabrication of composites with optimized microstructures. Through their research, they invented magnetic 3D printing or Fluxprint.
Fluxprint makes high-performance materials accessible. It’s a patented magnetic 3D printing process that creates optimized composites.
Fluxprint combines magnetics and digital light processing (DLP) 3D printing to produce composite parts with ideal mechanical properties”.

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Industrial 3D printing startup Fortify raises $10 million

3D Printing News Alert(For 3D printing a wonder material for the future, graphene)

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Graphene is strong, light, thin and flexible. It is the thinnest substance capable of conducting electricity, is an efficient thermal conductor and is optically transparent. Graphene is also more resistant to tearing than steel and is almost impermeable.

For 3D printing a wonder material for the future, graphene.

According to GrapheneCa Head of Business Development David Robles,” Proactive Investors to discuss the technology company that is integrating graphene into the real world using their own environmentally friendly production process.

Robles telling Proactive about the company’s revenue streams and when they are expecting to be profitable.”

According to Hodge,” Adding graphene to plastic composites can improve the tensile strength and stiffness of packaging. Graphene won’t make the material indestructible but it may be possible to reduce packaging size while maintaining the same properties. This has obvious advantages for transporting fragile goods and may also contribute to recycling. Today, recycling plastics degrades the quality of the plastic – it can be recycled an average of three times, but adding graphene to recycled plastics can improve its strength so that it can be recycled many times more. Because they are printed, [the capacitive touch sensors] can be any size or shape and printed in volume.”

According to Chris Jones, technical manager at Novalia, a partner in the EU’s Graphene Flagship, “Our mission statement is to make technology disappear into everyday items.
The ink is supplied by Researchers at the University of Cambridge, University of Manchester and produced by micro fluidization.”

According to Francesca Rosella, co-founder of CuteCircuit, “A dress was designed to illustrate the material’s strength, transparency, and conductivity. The shape and decoration of the dress represent the design of a graphene crystal. We examined graphene under a microscope to see the hexagonal structure and enlarged it to help people understand graphene’s molecular structure.”

According to the TechRadar, “Mobile warming the graphene jacket can also conduct electricity, but creator Vollebak has decided to dampen down this ability to protect wearers. Prototypes of the jacket were so conductive that the wearer could hold a battery in one hand and a light bulb in the other, and have the bulb light up, but Vollebak decided that, although interesting, it was best to play it safe and make the material a little more resistant.”

According to Researchers at Osaka Universities co-author Kazuhiko Matsumoto,” Our biosensor enables highly sensitive and quantitative detection of bacteria that cause stomach ulcers and stomach cancer by limiting its reaction in a well-defined microvolume. They have invented a new biosensor using graphene, which is a material that consists of a one-atom-thick layer of carbon, to detect bacteria like those that attack the stomach lining and that have been linked to stomach cancer. When the bacteria interact with the biosensor, chemical reactions are triggered which are detected by graphene. To enable detection of the chemical reaction products, the researchers used microfluidics to contain the bacteria in tiny droplets that are close to the surface of the sensor.”

https://wp.me/p64ptu-2qz

 

https://youtu.be/IesIsKMjB4Y

 

 

https://eandt.theiet.org/content/articles/2019/06/graphene-what-is-it-good-for/

https://www.techradar.com/news/with-this-graphene-jacket-youll-never-be-too-hot-too-cold-or-too-smelly

https://www.sciencetimes.com/articles/22914/20190622/using-graphene-and-tiny-droplets-to-detect-stomach-cancer-causing-bacteria.htm

Titomic 3D prints well-positioned to provide largest titanium UAV

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Titomic is innovating Australian manufacturing. According to Australian metal AM company Titomic’s Managing Director Jeff Lang reports,” Titomic’s formation, and why Titomic is well-positioned to provide advanced, digital manufacturing solutions now and in the future. ” that it has 3D printed the largest titanium unmanned aerial vehicle (UAV). The drone, which measures over 1.8 meters in diameter, was manufactured using the company’s rapid Titomic Kinetic Fusion technology—specifically, it’s large-format TKF 9000, which itself spans 9 x 3 x 1.5 meters. Titomic machines have build rates that are exponentially faster than conventional metal 3D printers currently available”.

https://www.titomic.com/beyond-3d-printing.html

The hearing aids 3D printing devices market

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According to Yahoo Finance,” 3D print, hearing aids with a rigid interior channel for sound to bounce through the hearing canal, while the exterior is coated with soft, flexible material for a comfortable fit. This will lead the hearing aids 3D printing devices market to witness considerable growth in the upcoming years. Analysts have predicted that the hearing aids 3D printing devices market will register a CAGR of over 18% by 2023″.

https://finance.yahoo.com/news/hearing-aids-3d-printing-devices-220300787.html

https://www.reportlinker.com/p05772592/?utm_source=PRN

3D Bio-printing Patent

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Accordingly, Poieskin® dermal compartment results from studies dealing with fibroblasts 3D self-organization over time, “The European Patent Office, Patent No. EP3233499 is entitled “Laser printing method and device for implementing said method.”.Bioprinting platform at single cell resolution. Dedicated to industrial and R&D applications, the new Poietis bioprinting platform enables companies and researchers to design and produce biological tissue at single-cell resolution.
3D Imaging by SPIM shows the precise positioning of cells over layers”.

Researchers:

Rodrigo Alvarenga Rezende, Ph.D. (rodrigo.rezende@cti.gov.br)
Janaina Dernowsek, Ph.D. (janaina.dernowsek@cti.gov.br)
Hermano Peixoto de Oliveira Junior, MSc
Jorge Vicente Lopes da Silva, Ph.D. (jorge.silva@cti.com)

www.european-patent.biz

http://poietis.com


3D Printing News Alert(3D printed ‘Silicon Valley’ of Africa)

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According to jpost.com,” About 40% of 3D printers worldwide are manufactured by Israeli companies. The new facility is the first of its kind in Africa—it relies on the latest 3D software for prototyping and includes twenty-three advanced 3D printing machines”.
The inauguration of the facility, Cameroon’s Education Minister Jacques Fame Ndongo thanked Israel and praised “the product of its ingenuity known since ancient times.” Israel’s Ambassador to Cameroon Ran Gidor expressed the hope that Cameroon will become “the Silicon Valley of Africa.”

https://www.cameroon-tribune.cm/article.html/25143/fr.html/cameroon-israeli-cooperation-cameroon-acquires-first-ever-3d-printing-facility

https://www.jpost.com/Jpost-Tech/Israel-and-Cameroon-inaugurate-3D-printing-facility-in-Yaound%C3%A9-587162