The Airbus Quantum Computing Challenge (AQCC) was initiated by the Toulouse-based aerospace corporation to bring quantum computing out of laboratories and apply it directly to challenges facing the aviation industry. The global competition is open to post-graduate students, academics, researchers, and professionals.
Originally published in 1995, now updated and expanded with new specifications, this seminal work focuses on the development of Allied aircraft engines that helped turn the tide of World War II.
ARCONIC-THOR –designed for higher temperature applications in next generation aero engines and adjacent structures. The ARCONIC-THOR alooy is nearly 50 percent lighter than incumbent nickel-based superalloys.
Boeing collaborates with Assembrix to manage and protect intellectual property shared with vendors across its global supply chain for additive manufacturing.
At the convergence of 3D-printing and lithium battery technology, Hong Kong researchers develop a promising textile-based, foldable battery that may find its way onto IoT-connected fabrics within automotive, aerospace, and medical industries.
The collaborative development of digital twins will inform additive manufacturing (also known as 3D printing), advanced composites, assembly, and industry 4.0 processes at GKN Aerospace's Global Technology Centre in order to enable the high rate production of aircraft structures.
EOS StainlessSteel CX, EOS Aluminium AlF357, EOS Titanium Ti64 Grade 5, and EOS Titanium Ti64 Grade 23 have been tailored to suit a broad array of applications, ranging from automotive, medical, and aerospace applications.
Equispheres will use the investment to conduct the research and development needed to build reactors that will produce powders of higher-strength materials, such as steels, cobalt, chrome, and Inconel.
Boeing and Airbus forecast a worldwide demand for up to 40,000 new aircraft over the next two decades. With a 10-year production backlog and new aircrafts increasingly counting on lightweight composites, manufacturing companies are developing advanced sandwich-structure composite solutions to fill the production gap.
Aerospace manufacturers walk a metaphorical balance beam to continually develop and produce stronger, more efficient materials and components, while addressing all potential failure modes. This is true for safety-critical aircraft components like landing gear systems. Fokker Landing Gear B.V./GKN Aerospace recently equipped its mechanical laboratory with three creep testing machines to verify its manufacturing process control of zinc-plated bolts for aircraft landing gear systems.
By integrating all of the drivetrain components normally found under the hood of a car into the wheel of an EV, the platform optimizes freedom of design, multiple body configurations on a single platform, reduced vehicle size and weight, and increased energy and operational efficiency.
Together, the companies will develop customized lightweight material systems and advanced manufacturing processes, such as metal additive manufacturing – also known as 3D printing – to advance current and next-generation aerospace and defense solutions, including new structures and systems not currently in existence.
Four of these technologies – smart coatings for corrosion detection and protection, aluminum alloys for high temperature applications, particle contamination mitigation technologies, and thermal and environmental barrier coating systems – are among NASA’s most in-demand technologies and have been applied to mainstream engineering projects.
Battery weight and power density is a major design consideration when it comes to electric and hybrid-electric vehicles. To reduce platform weight for next-generation electric vehicles, Atlanta-based Novelis, Inc. (Novelis) has used direct feedback from industry partners and automotive design engineers to develop the first aluminum sheet battery enclosure.
Orbex, a developer of small satellite (smallsat) launch vehicles based in Forres, Scotland, has unveiled its “Prime” launch vehicle. The rocket utilizes several novel technologies, including the world’s largest metal rocket engine produced as a single piece through additive manufacturing (AM).
Sciaky, a Chicago-based subsidiary of Phillips Service Industries, Inc. (PSI), will contribute its novel Electron Beam Additive Manufacturing (EBAM) wire-fed metal 3D printing technology to a new traditional/additive hybrid process to manufacturing titanium alloy aircraft components.
In contrast to the stiff, rigid wings found on most commercial aircraft, flexible wing technology is considered essential to next generation, fuel efficient aircraft. However, flexible wings are susceptible to “flutter,” or highly destructive aeroelastic instability. To better understand and mitigate flutter, engineers at NASA’s Armstrong Flight Research Center (AFRC) equipped the X-56 with fiber optic sensing (FOS) technology.