Générer de l’innovation avec le Japon : Québec 2022

On the same subject

• 

  January 21, 2020

  Better Control Over 3D Printing

  What's going on in that printing machine? For surgical repairs to a patient's hip or skull, surgeons might use a titanium bone implant. However, metal objects such as these – with complex outer forms, or with intricate internal features such as ducts or channels – can be difficult to make using conventional processes. To create these useful devices, manufacturers are turning to 3D printing, a process that typically involves building a part layer by layer, sometimes over minutes or hours. 3D printing of metal objects is a booming industry, with the market for products and services worth more than an estimated $2.3 billion in 2015 – a nearly five-fold growth since 2010. It's increasingly popular in the medical, aerospace, and automotive industries, where it can be used to make complex components such as fuel injector nozzles for engines. But the commercial technology is still relatively new, and maintaining quality control can be challenging and time-consuming. Two supposedly identical products made in the same way on the same machine don't necessarily come out with the same dimensions. Tiny imperfections can appear in the layers, reducing the strength properties of the components. And residual stresses can build up as the layers cool, creating cracks between layers and warping the parts. The stress can be so high, in fact, that it can warp a 1-inch thick piece of steel by a millimeter. To give manufacturers more control over this process, NIST researchers have built a metal 3D printing testbed, a custom-made printer that they can use to produce tools that will allow users to monitor the process in real time. The researchers hope to answer some fundamental questions, such as: How hot does the melting metal get in each layer? How do you lower the stresses that cause cracking and warping? And what sensors would you need in order to provide better information about what's happening inside the printing machine? Eventually, the researchers hope their system will be useful beyond 3D printing of metal objects, to look at solid materials that experience extreme heat, such as the wingtips of supersonic aircraft. https://www.nist.gov/pml/about-pml/pml-working-you/better-control-over-3d-printing

• 

  July 29, 2022

  STATE SMALL BUSINESS CREDIT INITIATIVE (SSBCI)

• 

  July 10, 2020

  Additive Technologies For Future UK Air Power Advance

  Tony Osborne July 10, 2020 Bidders pushing for a role to build a technology demonstrator for the UK's Lightweight Affordable Novel Combat Aircraft (LANCA) are waiting to see if their design proposals will be approved for the next phase of the initiative. Three industry teams were selected last summer (AW&ST July 29-Aug. 18, 2019, p. 18) to take forward development of the LANCA air system, an unmanned air vehicle that could act as additive capability accompanying future combat aircraft into operations. LANCA would perform a range of tasks, including serving as a loyal wingman, gathering intelligence or acting as a weapons carrier. The Royal Air Force envisions a platform costing 1/10th of current combat aircraft and developed in one-fifth of the time. The idea is like that of the Kratos XQ-58 Valkyrie for the U.S. Air Force's Skyborg program, Australia's Boeing-led Airpower Teaming System and remote carriers for the French, German and Spanish Future Combat Air System. Since then, the industry teams—which include Boeing Phantom Works International, working with Marshall Aerospace and Defence Group and Cranfield University; consortium Team Black Dawn, Callen-Lenz and Bombardier Belfast; and Northrop Grumman UK with Team Avenger, led by Blue Bear Systems Research and yet to be disclosed partners—submitted their proposals for the £4.8 million ($6 million) Phase 1. The LANCA program is being led by the UK Defense Science and Technology Laboratories in conjunction with the Royal Air Force's Rapid Capability Office. The UK Defense Ministry is evaluating proposals in readiness for the second phase of the project, called Mosquito, which is worth £30-50 million. Mosquito would see one, possibly two of the candidates being matured into a full-size flightworthy demonstrator potentially undertaking a flight-test program. Aviation Week has been told there was stiff competition for the LANCA program: Some 45 bidders entered Phase 1 and were subsequently scaled down to nine. Around eight bids were then tendered, of which three were chosen. Few details have emerged about the proposals, although Boeing Australia confirmed through social media that it had secured a “first-of-type permit” from the Australian government to share design material for its Airpower Teaming System with the UK, suggesting the Boeing proposal may borrow heavily from that platform. Progress is also occurring on a drone swarm system announced by former Defense Secretary Gavin Williamson in February 2019: Demonstrations in March using five unmanned air vehicles proved a collaborative capability between the platforms, people close to the program told Aviation Week. https://aviationweek.com/ad-week/additive-technologies-future-uk-air-power-advance