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TOYOTA, Japan–(BUSINESS WIRE)–SkyDrive Inc. (“SkyDrive”), a leading Compact eVTOL (*1) aircraft developer based in Japan, has successfully accelerated its SKYDRIVE aircraft (SkyDrive Model SD-05) to a speed of 100km/h, a viable speed for the commercialization of short hop inter-urban air mobility. Through a series of high speed tests, SkyDrive has verified the aircraft’s high-speed stability, controllability, and maneuverability, as well as the performance of the propulsion systems, flight control systems and on-board avionic equipment.
The data gathered through the high-speed flight test campaign allows SkyDrive’s engineers to confirm the accuracy of the aircraft characteristics and dynamic behavior predicted in advance of actual aircraft testing through advanced design and analysis, marking another major step towards type certification and the planned commercialization of the aircraft in 2028.
The Significance of Reaching 100km/h
SkyDrive is pleased to announce this high-speed milestone. However, the significance of achieving stable flight at 100km/h goes beyond simply reaching a certain number on the airspeed indicator.
Aircraft development begins with design and analysis, proceeds through individual system tests and ground tests, and then moves on to the manufacture of a full-scale aircraft and flight testing. At the same time, simulators are used to repeatedly verify flight characteristics, propulsion systems, and flight control systems.
Simulation, analysis and ground testing are all key parts of the process, but the final flight testing stage is critical. There are some things that cannot be known until the aircraft actually flies. This is particularly true of high-speed flight, where aerodynamic forces, vibrations, structural loads, and flight control system response all change and interact in complex ways. Flight testing is the only way to verify whether the results predicted during the design phase accurately describe the aircraft’s in-flight behavior.
As SkyDrive’s aircraft is based on a completely new concept, distinct from conventional fixed-wing aircraft and helicopters, we cannot assume that existing knowledge and flight data will apply. Every new aircraft needs to collect and verify data through actual flight tests, but with a new aircraft concept, this phase becomes even more indispensable.
The Benefits of Reaching 100km/h with our Multicopter
1. Achievement of Important Technical Milestones
During high-speed flight, aerodynamic forces, vibrations, structural loads, propulsion systems and flight control all change significantly, as do the interactions between them. High speed testing is a critical stage of aircraft development as it allows us to confirm the appropriateness of our design and the precision of our prior analyses.
Flight testing also frequently reveals new challenges. If the data from actual flight testing differs significantly from the data assumed at the design and analysis stage, it can result in the need for additional testing, design changes, and even the revision of existing development plans.
Our current flight test campaign has allowed us to confirm the stability, controllability and structural integrity of the aircraft, as well as the functionality of the aircraft’s various systems. The results show that the observed flight characteristics and behavior match our expectations from the design and analysis phase.
SkyDrive is pleased to have achieved high speed forward flight, overcoming the difficulties of reaching this stage and demonstrating the appropriateness of our design, analysis and testing assumptions. We are now able to move our development forward toward the certification and commercialization of our aircraft with a higher degree of visibility and predictability.
2. Confirming the Ability of a Compact Multicopter to Enable Urban Air Mobility
The recent high speed forward flight tests conducted by SkyDrive demonstrate the utility of the compact multicopter concept that SkyDrive has pursued since the company’s founding.
SkyDrive’s multicopter design, which eschews fixed wings, is optimized for use in urban airspaces. A compact design not only allows for wider flexibility in takeoff and landing locations, it also keeps the aircraft structure and operations as simple as possible, reducing operational costs and improving maintainability.
