Inexpensive electric rotors will allow for a lot of aeronautical innovation and this is a great example.
Think in terms of a multiseat array been opened forward while the rotor are set up forward on either wing position with a balancing rotor on the tail. Now add in axis rotation to all three rotors as well and let as computer control it all as it is far to complex for human intervention..
The defaults will still have to auto-rotate to allow a successful descent been possible. Otherwise it will never be deemed airworthy. And by the way i would never fly that machine you see. One failure and you will somersault all over the country and it will not be survivable.
I strongly suggest that they put a remote system on board forthwith and master power off scenarios.
First manned flight for Flike personal tricopter
The Flike concept demonstrator in a controlled flight in Hungary
http://www.gizmag.com/flike-personal-flight-manned-flying-bike/37779/
Despite always generating plenty of interest, getting a personal flight vehicle off the
ground can be a huge undertaking – just ask Malloy Aeronautics, which has been
forced to scale its Hoverbike down, selling a one-third-scale drone to raise
funds to continue development of the larger, manned Hoverbike. But a Hungarian
team is looking onwards and upwards after
having achieved the first manned flight of its Flike tricopter concept
demonstrator.
In under a year, the team of flight
enthusiasts at Bay Zoltan Nonprofit Ltd., a state-owned applied research
institute in Hungary, has taken the concept of a personal flight tricopter from
the drawing board to its first manned flight at Miskolc Airfield in northeast
Hungary on March 7.
On the manned flight, the Flike (think fly-bike) concept
demonstrator had a takeoff weight of 210 kg (463 lb) and only made it off the
ground for a few seconds, but took off and landed safely. In a subsequent
manned test flight, the Flike fly meters off the ground, and was able to
demonstrate hovering and maneuvering capabilities while compensating for wind
in a controlled flight lasting one and a half minutes.
The aircraft demonstrator features a Y6 layout, with six
rotors paired in a coaxial arrangement that are directly driven by individual
electric disc motors. These are powered by lithium polymer batteries, which the
team says allow for around 15 to 20 minutes of hover flight or 30 to 40 minutes
of cruise flight.
Control is provided by altering the
rotation speed of the individual rotors, allowing the Flike to perform in the
air like a conventional helicopter, including the ability to hover, roll, bank,
drift, yaw, climb, turn, sidle and dive. The team also hints at other flight
capabilities that are "yet to be named".
Thanks to its flight management computer that takes care of the craft's stability, lateral position and altitude, the development team claims flying the Flike will be as easy as riding a bike. They also claim the Flike is able to provide emergency lift to prevent a crash if one of the electric motors fails.
Having successfully completed the first
flight, the team now plans to build a second prototype that would boast a
similar design and features to that envisioned for the planned
commercial model. And commercialization is the ultimate goal, with the
team aiming to
spin off into a startup company for which it is actively seeking
investors.
Videos of the first flight and subsequent
controlled flight can be viewed below.
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