Toulouse, France 21 September 2021 – Airbus (OTC: EADSY) has announced plans for a new CityAirbus at the Company’s first #AirbusSummit on “Pioneering Sustainable Aerospace” as the emerging Urban Air Mobility (UAM) market begins firming up. Ushering in the next generation of CityAirbus, the fully electric vehicle is equipped with fixed wings, a V-shaped tail, and eight electrically powered propellers as part of its uniquely designed distributed propulsion system. It is designed to carry up to four passengers in a zero emissions flight in multiple applications.
CityAirbus is being developed to fly with a 80 km range and to reach a cruise speed of 120 km/h, making it perfectly suited for operations in major cities for a variety of missions.
Sound levels are a key factor for an urban mission; Airbus’ extensive expertise in noise-friendly designs is driving CityAirbus’ sound levels below 65 dB(A) during fly-over and below 70 dB(A) during landing. It is optimized for hover and cruise efficiency, while not requiring moving surfaces or tilting parts during transition. The CityAirbus NextGen meets the highest certification standards (EASA SC-VTOL Enhanced Category). Designed with simplicity in mind, CityAirbus NextGen will offer best-in-class economic performance in operations and support.
Airbus is benefitting from years of dedicated research, innovation, two electric Vertical Takeoff and Landing (eVTOL) demonstrators, and development on sound technology across its portfolio of products, as well as decades of experience in certifying aircraft. The Vahana and CityAirbus demonstrators have jointly conducted 242 flight and ground tests and have flown around 1,000 km in total. Furthermore, Airbus has used extensive subscale flight testing and wind tunnel campaigns and has leveraged its computing and modelling power. CityAirbus NextGen is in a detailed design phase right now and the prototype’s first flight is planned for 2023.
Beyond the vehicle, Airbus is working with partners, cities, and city inhabitants in order to create the ecosystem that is essential to enabling this new operating environment to emerge in a true service to society.
Melbourne, Florida, September 20, 2021 – Embraer (NYSE: ERJ) Eve Urban Air Mobility Solutions and Helipass, SAS, today announced a new collaboration to accelerate and deploy electrical vertical takeoff and landing (eVTOL) aircraft, also known in the market as EVA (Electrical Vertical Aircraft), across France and Europe. The partnership aims to fly Eve’s electric aircraft for a total of 50,000 flight hours per year. This could lead to an optional increase of 100,000 annual flight hours across Helipass’ network.
Helipass plans to open digital bookings on its platform to offer an innovative and seamless user experience to customers throughout its network. To support the expansion of this partnership, Eve will work with Helipass to develop training, on-site support, and technical publications to facilitate the launch of EVA commercial operations.
Following the commercial introduction of the EVA, which is planned for 2026, both companies will endeavor to launch Eve’s EVA aircraft across Helipass’ markets. These flights will include sightseeing, city and airport transfers, as well as a growing on-demand service.
Both parties will look into growing the service beyond this agreement to include additional use cases, as well as the requisite services needed to support the scalability of Urban Air Mobility (UAM) products in Helipass’ core markets.
Eve Urban Air Mobility Solutions (“Eve”) signed a Memorandum of Understanding (MoU) with Kenya Airways PLC, the flag carrier of Kenya, through its fully owned subsidiary Fahari Aviation. This collaboration aims to develop operational models for the wide-accessibility of Urban Air Mobility (UAM) to support Fahari Aviation’s key markets. In addition, this partnership will establish the co-creation of a foundation of concepts and procedures to safely scale electrical vertical takeoff and landing (eVTOL) aircraft, also known in the market as EVA (Electrical Vertical Aircraft).
Eve will support Fahari Aviation, the Unmanned aircraft systems (UAS) division of Kenya Airways that promotes safe and secure UAS usage in the region, in establishing its UAM network and collaborate on the required Urban Air Traffic Management (UATM) procedures and UAM operating environment. This partnership will also allow Fahari Aviation to support Eve’s aircraft and product development process which will help guide the integration of UAM with Kenya Airways’ overall operations. Eve’s fully electric aircraft is designed to be accessible to all while being a community-friendly aircraft with a low noise signature and no emissions. It aims to drastically cut road travel time. It is ideally suited as a UAM aircraft bringing all traditional aviation travelers closer to their final destination efficiently and comfortably.
The partnership will deliver a robust strategy to provide Fahari Aviation’s passengers with a sustainable, accessible, and affordable transportation option. It is estimated that using UAM from the airport to downtown, EVA can reduce conventional road trips by up to 90% turning an hour and a half ride into a 6-minute flight.
Garmin International Inc. (Nasdaq: GRMN), a unit of Garmin Ltd., today announced it has received Federal Aviation Administration Supplemental Type Certificate approval for the GFC 600 digital autopilot in select Pilatus PC-12/41 and PC-12/45 aircraft. The GFC 600 digital autopilot is optimized to meet the demands of turbine aircraft, delivering superior in-flight characteristics and operational capabilities such as Vertical Navigation (VNAV), automatic Course Deviation Indicator (CDI) switching when paired with a GTN Series navigator, enhanced go-around capability and much more.
The GFC 600 certification for the PC-12 boasts superior integration with a TXi flight display configured as a primary flight display (PFD) to provide owners and operators an advanced autopilot solution that considers the wide range of speed and performance characteristics of these turbine aircraft. Further, the GFC 600 incorporates solid-state attitude with robust self-monitoring capabilities to provide superior autopilot performance, greater reliability and renowned safety benefits. Environmentally hardened autopilot servos designed for harsh operating conditions contain brushless DC motors offering improved performance and reducing maintenance requirements when compared to decades-old servo designs on the market today. Standard mark-width (6.25-inch) design of the GFC 600 mode controller ensures the autopilot controller allows for routine installation into the aircraft’s avionics stack.
Going beyond traditional autopilot capabilities such as altitude hold, vertical speed and heading modes, the GFC 600 also includes altitude preselect, VNAV, Level Mode with the LVL button, underspeed and overspeed protection and more. Pilots can also select, couple and fly various instrument approaches, including GPS, ILS, VOR, LOC and back course approaches when paired with a compatible GPS navigator.
Additional benefits of the GFC 600 digital autopilot for turbine aircraft include:
Premium functions and advanced capabilities such as altitude pre-select on a TXi flight display configured as a PFD and indicated airspeed hold mode;
Built-in GPS roll steering capability eliminates the need for external roll steering converters, allowing for smoother navigation tracking when installed with a compatible navigator;
Yaw Damping (YD) mode minimizes yawing oscillations while also helping to maintain coordinated flight;
Flight Director command bars displayed on a TXi flight display configured as a primary flight display (PFD);
Coupled ‘go-arounds’ during missed approach sequencing with a remotely-installed go-around button that commands the Flight Director to display the appropriate pitch attitude required for the missed approach procedure and activates a loaded missed approach when paired with a GTN 650/750 or GTN 650Xi/750Xi navigator;
Control wheel steering allows the pilot to adjust pitch, roll, altitude hold, vertical speed or airspeed references using the control yoke while the autopilot is engaged.
PHOENIX, March 8, 2021 /PRNewswire/ — Honeywell (NYSE: HON) announced it is developing a power source for hybrid-electric aircraft, planned for demonstration later this year. At 280 pounds, the Honeywell 1-Megawatt generator weighs about the same as a motor scooter but delivers enough energy to power an entire neighborhood block. This generator will be combined with the Honeywell HGT1700 auxiliary power unit, currently flown on every Airbus A350 XWB, to form a turbogenerator 2.5 times more powerful than the version the company unveiled in 2019.
The new turbogenerator from Honeywell will be able to run on aviation biofuel, including Honeywell Green Jet Fuel, which is chemically similar to fossil fuel but made from more sustainable alternatives, as well as conventional jet fuel and diesel. Honeywell’s turbogenerator can be used to operate high-power electric motors or charge batteries and can satisfy missions from heavy-lift cargo drones to air taxis, or commuter aircraft. The first demonstration of this turbogenerator system will occur in the third quarter of 2021, with ongoing development and qualification to follow.
Traditionally, aircraft use fuel-burning engines to mechanically turn rotors, propellers or fans. Many new designs, however, use a distributed electric propulsion architecture, in which many electric motors can be tilted or turned off for vertical takeoff and horizontal flight. A Honeywell turbogenerator can provide electric power for multiple electric motors anywhere on an aircraft.
In December, Honeywell signed a memorandum of understanding with British startup Faradair Aerospace to collaborate on systems and a turbogeneration unit that will run on sustainable aviation fuel to power Faradair’s Bio Electric Hybrid Aircraft (BEHA). Faradair intends to deliver 300 hybrid-electric BEHAs into service by 2030, of which 150 will be in a firefighting configuration. Honeywell is in advanced discussions with several other potential turbogenerator customers, working to help define power requirements based on mission profiles required by various manufacturers.
Honeywell unveiled its first turbogenerator for urban air mobility (UAM) at the 2019 HAI HELI-EXPO in Atlanta. It combined Honeywell’s HTS900 turboshaft engine with two 200-kilowatt generators. Since then, the company continues to grow its role in the UAM segment, highlighted by advancements in electric and hybrid-electric propulsion systems.
Honeywell is a major player in the emerging UAM segment, offering a full line of avionics, propulsion and operational systems—all tailored for piloted and autonomous vertical take-off and landing UAM and cargo vehicles. Honeywell also offers aerospace integration and certification expertise for enabling the commercialization of these vehicles.
Honeywell pioneered the sustainable aviation fuel market with its UOP Ecofining process. Honeywell Green Jet Fuel produced by this process is blended seamlessly with petroleum-based jet fuel at commercial scale. When used in up to a 50% blend with petroleum-based jet fuel, Honeywell Green Jet Fuel requires no changes to aircraft technology and meets all critical specifications for flight.
OLATHE, Kan./Feb. 10, 2020/Business Wire – Garmin® International, Inc., a unit of Garmin Ltd. (NASDAQ: GRMN), today announced a long-term agreement to provide the state-of-the-art Garmin G3000® integrated flight deck to Joby Aviation for their revolutionary all-electric vertical takeoff and landing (eVTOL) aircraft, which is expected to commence commercial operations in 2024. Garmin has decades of experience deploying certified avionics solutions to new markets and this is continued with the touchscreen G3000 integrated flight deck for eVTOL aircraft in the Urban Air Mobility (UAM) market. The G3000 integrated flight deck has amassed extensive field service history, and with this derivation of the system into the eVTOL segment, it leverages that proven experience while offering advanced integration functionality in a compact design with unparalleled capabilities.
The modular Garmin G3000 integrated flight deck boasts light weight and vibrant high-resolution flight displays that support navigation, communication and flight sensor solutions and integrates seamlessly with Joby’s aircraft systems. Specifically tailored to meet the needs of eVTOL aircraft, the G3000 system that will be featured in Joby’s eVTOL aircraft delivers enhanced capabilities to optimize their air mobility service through tight integration with the vehicle mission computer and tailoring of flight guidance display indications. Further, the G3000 will be architected to provide the ability to efficiently facilitate future system upgrades as the Advanced Aerial Mobility (AAM) industry continues to evolve.
Joby Aviation is a California headquartered company developing an all-electric vertical takeoff and landing aircraft. After more than a decade of engineering and development, Joby intends to operate the aircraft as a fast, quiet and affordable air mobility service as early as 2024. The piloted, zero-emissions aircraft, will be capable of transporting four passengers up to 150 miles on a single charge, with a top cruising speed of 200 mph. It is designed to help reduce urban congestion and accelerate the shift to sustainable modes of transit. Designed for daily life, the aircraft lands vertically and provides flexibility and versatility to serve nearly any community.
CHICAGO, Feb. 10, 2021 /PRNewswire/ — United Airlines (Nasdaq: UAL) today announced that it has completed an agreement to work with air mobility company Archer as part of the airline’s broader effort to invest in emerging technologies that decarbonize air travel. Rather than relying on traditional combustion engines, Archer’s electric vertical takeoff and landing (eVTOL) aircraft are designed to use electric motors and have the potential for future use as an ‘air taxi’ in urban markets.
Under the terms of the agreement, United will contribute its expertise in airspace management to assist Archer with the development of battery-powered, short-haul aircraft. Once the aircraft are in operation and have met United’s operating and business requirements, United, together with Mesa Airlines, would acquire a fleet of up to 200 of these electric aircraft that would be operated by a partner and are expected to give customers a quick, economical and low-carbon way to get to United’s hub airports and commute in dense urban environments within the next five years.
Working with Archer is another example of United’s commitment to identifying and investing in innovative technology that can reduce carbon emissions while also improving the customer experience and earning a strong financial return. The airline was an early stage investor in Fulcrum BioEnergy and recently partnered with 1PointFive, a joint venture between Oxy Low Carbon Ventures and Rusheen Capital, to jumpstart the establishment of direct air capture and sequestration technology.
With today’s technology, Archer’s aircraft are designed to travel distances of up to 60 miles at speeds of up to 150 miles per hour and future models will be designed to travel faster and further. Not only are Archer’s aircraft capable of saving individuals time on their commute, United estimates that using Archer’s eVTOL aircraft could reduce CO2 emissions by 47% per passenger on a trip between Hollywood and Los Angeles International Airport (LAX), one of the initial cities where Archer plans to launch its fleet.
Led by co-founders and co-CEOs Brett Adcock and Adam Goldstein, Archer’s mission is to advance the benefits of sustainable air mobility at scale. Archer plans to unveil its full scale eVTOL aircraft in 2021, begin aircraft production in 2023, and launch consumer flights in 2024. To drive this fourth transportation revolution and transform how people approach everyday life, work and adventure, Archer has built a highly accomplished team of top engineering and design talent, with a collective 200+ years of eVTOL experience.
HARWELL, Oxford, Feb. 8, 2021 – Lockheed Martin [NYSE: LMT] has contracted ABL Space Systems, of El Segundo, California, a developer of low-cost launch vehicles and launch systems for the small satellite industry, to supply a rocket and associated launch services for the company’s first UK vertical satellite launch.
The project known as UK Pathfinder Launch is planned to be the first ever vertical small satellite launch from UK soil, from Scotland in 2022. It will also be the first UK commercial launch for U.S.-based ABL Space Systems’ new RS1 rocket.
Nik Smith, Regional Director, Lockheed Martin Space, said: “We are absolutely committed to the success of this programme and the world class capability that ABL Space Systems brings will allow us to build on our long-standing partnership with the UK and strengthen the growth of the UK space sector, aligned to the UK Government’s prosperity and industrial strategy.”
ABL Space Systems’ flexible, integrated GSO launch system, and RS1 rocket, allows for a rapid and cost-effective deployment with outstanding launch performance.
Lockheed Martin’s UK Pathfinder Launch supports the UK Space Agency’s commercial spaceflight programme – Launch UK. In October, the UK Space Agency confirmed Lockheed Martin’s plans to move its programme to the Shetland Space Centre and in January, planning proposals were submitted for the space launch facility in Unst.
Ian Annett, Deputy CEO, UK Space Agency said: “We want the UK to be the first in Europe to launch small satellites into orbit, attracting innovative businesses from all over the world, accelerating the development of new technologies and creating hundreds of high-skilled jobs across the whole of the UK. Lockheed Martin’s selection of ABL Space Systems for their UK Pathfinder launch brings us one step closer to realising this ambition – putting the UK firmly on the map as Europe’s leading small satellite launch destination.
The addition of ABL Space Systems as a partner completes Lockheed Martin’s UK Pathfinder Launch programme team. On launch day, ABL Space Systems’ RS1 rocket will lift off from Shetland Space Centre, in Unst, Shetland, the UK’s most northerly island. Once in orbit, the rocket will release a small launch orbital manoeuvring vehicle, an agile platform built by MOOG, in Reading, UK, which can carry and deploy up to six 6U CubeSats, optimising orbital placement and timing for each small satellite’s respective missions.
To demonstrate the full value of this new UK space transportation capability, two of the CubeSats deployed will be Lockheed Martin’s own technology demonstration spacecraft.
In 2019, ABL Space Systems announced that it had received a strategic investment from Lockheed Martin Ventures to advance the launch provider’s development and test programme.
OLATHE, Kan./Jan. 21, 2020/ – Garmin® International Inc., a unit of Garmin Ltd., today announced it has received Federal Aviation Administration (FAA) Supplemental Type Certificate (STC) approval for the GFC™ 600 digital autopilot in select Beechcraft King Air C90 aircraft and E90 aircraft1. The GFC 600 digital autopilot is optimized for turbine aircraft, delivering superior in-flight characteristics and new operational capabilities such as Vertical Navigation (VNAV), automatic Course Deviation Indicator (CDI) switching when paired with a GTN Series navigator, enhanced go-around capability and much more.
The GFC 600 certification for the Beechcraft King Air C90 and E90 provides owners and operators an autopilot upgrade that boasts superior integration potential with G600 and G600 TXi™ flight displays, the GI 275 electronic flight instrument, as well as the GTN™ and GTN Xi Series of navigators. The self-contained autopilot controller incorporates backlit keys and a bright, sunlight readable display that depicts autopilot status and mode selection. An intuitive built-in control wheel also provides convenient adjustment of aircraft pitch, airspeed and vertical speed modes. When the level button is selected, the aircraft automatically returns to straight-and-level flight.
Environmentally hardened autopilot servos designed for harsh operating conditions contain brushless DC motors offering improved performance and reducing maintenance requirements when compared to decades-old servo designs on the market today. In addition, these servos are optimized for turbine aircraft by offering more torque to help better command and respond to control demands required of turbine aircraft.
Standard mark-width (6.25-inch) design of the GFC 600 mode controller ensures the autopilot controller allows for routine installation into the aircraft’s avionics stack. Autopilot mode annunciation is available on the G600 TXi touchscreen glass flight display, as well as the G600 flight display. The addition of an optional autopilot annunciator panel also displays the selected autopilot mode in the pilot’s primary field of view and retains an identical footprint of third-party autopilot annunciators on the market.
– New courses include helicopter specific eLearning courses for G1000H NXi
Garmin® International Inc., a unit of Garmin Ltd., is pleased to announce two new eLearning training courses for the G1000® NXi, as well as two separate eLearning courses for the G1000H NXi integrated flight deck for helicopters. These training courses are available in a virtual eLearning format allowing pilots to learn at their own pace, with the G1000 NXi Fundamentals eLearning Course providing a foundational understanding of the system, while the G1000 NXi Essentials eLearning Course is focused on systems installed in high-performance piston and turbine engine aircraft. The two comprehensive eLearning courses for the G1000H NXi integrated flight deck titled G1000H NXi Fundamentals, and G1000H NXi Advanced-IFR, use scenario-based training to highlight helicopter-specific operations and are tailored for pilots new to the G1000H NXi system, in addition to those with experience wanting a deeper understanding of the system.
Core training topics All four training courses build on a common core of training topics. These topics are common to all G1000 NXi and G1000H NXi systems but are tailored to the audience for each course. The topics include:
Primary Flight Display (PFD) and Multifunction Display (MFD) function
Audio Panel Features
Automatic Flight Control System
Hazard Avoidance Features
Safety Features
Abnormal Operations
Managing Databases
Operational Flight Scenario
Learn best-practices for G1000 NXi operational use
For those that are new to Garmin avionics, transitioning to advanced avionics, or perhaps want to refresh their understanding of the system, the G1000 NXi Fundamentals eLearning Course provides comprehensive training on the system designed for piston engine equipped aircraft. This course describes features of the system in detail and use a scenario to demonstrate how particular features function in different phases of flight in order to see this advanced system in action. In order to practice what you learned during this course, the Garmin G1000 NXi PC Trainer software is available for purchase online.
G1000 NXi for high-performance piston and turbine aircraft
For those operating high-performance piston or turbine-engine equipped aircraft, the G1000 NXi Essentials course presents best-practices for the G1000 NXi integrated flight deck by providing detailed training for pilots wanting to get the most out of the system. In addition to describing features in detail and showing how they can be used effectively in flight, scenario-based training demonstrates typical high-performance piston and turbine-engine aircraft operations, providing an opportunity to see the G1000 NXi system in full effect. For your specific or similar aircraft, the Garmin G1000 NXi PC Trainer software is available for purchase online, and provides the opportunity to take what you learned throughout the course and apply it. In addition to the core training topics, the G1000 NXi Essentials eLearning Course includes additional instruction on:
Vertical Navigation
Automatic Flight Control System
Advanced Features
User Waypoints
Managing Databases
Multiple Operational Flight Scenarios with different performance profiles
Build helicopter-specific system knowledge
The G1000H NXi Fundamentals course is designed for VFR helicopter pilots who are new to Garmin avionics, transitioning to advanced avionics, or perhaps want a refresher on the G1000H NXi. This allows the pilot to be comfortable with the avionics and maximize learning during valuable flight time. Learn how to take full advantage of the capabilities of the G1000H NXi system while gaining experience with operational use best practices. This virtual course allows pilots to learn at their own pace, details system features and provides a VFR flight scenario to show how these features are used in various phases of flight. Those that sign up for this course receive an additional scripted scenario for more practice through the Bell 407GXi G1000H NXi PC Trainer software, available for purchase online. The core training topics in the G1000H NXi Fundamentals eLearning Course have been tailored to helicopter-specific features and functionality, including differences for:
PFD and MFD function
Audio Panel Features
Hazard Avoidance Features
Operational Flight Scenario
Scenario-Based Exercise
Enhance IFR helicopter skills with G1000H NXi
The G1000H Advanced-IFR course provides a detailed look at the G1000H NXi system and illustrates best practices for operational use of the flight deck, with a focus on Instrument Flight Rules (IFR). The course uses phase of flight scenarios to demonstrate typical IFR helicopter operation, and depicts common practices to maximize the benefits of system features and capabilities. For helicopter pilots who fly search-and-rescue missions, emphasis on user waypoints are included in the course scenarios. Pilots can further practice what they learned throughout the course with one of the additional scripted scenarios provided for use with the purchase of the Bell 407GXi G1000H NXi PC Trainer software. Some helicopter-tailored training topics covered in the Advanced IFR eLearning Course include:
PFD and MFD function
Automatic Flight Control System
Hazard Avoidance Features
Advanced Features
User waypoints
Operational Flight Scenarios
Proceed through the course at a pace that works best
Available immediately after purchase using a computer or tablet device with internet access, pilots can navigate through the virtual course at their own pace. Assessments throughout the course validate knowledge obtained of critical items while documenting the learning process. With the ability to pause lessons as needed to return to the lesson later, this is a convenient option for any pilot. Also, pilots can retake specific lessons or even the entire course during the subscription period.
The G1000 NXi Fundamentals eLearning course is available now for $94.95 USD, and the G1000 NXi Essentials eLearning Course is now available for $145.95 USD. Also available is the G1000H NXi Fundamentals eLearning Course for $74.95 USD, as well as the G1000H NXi Advanced IFR eLearning Course is available for $94.95 USD. For aviation training needs, including purchasing one of these eLearning courses, please visit www.fly.garmin.com/training.
