These are quite extraordinary
claims. My problem is figuring out lift
is established, unless it is mostly a surface effect vehicle with an unusual stabilization
system. None of the forgoing helps there
at all and the pictures show nothing that makes sense.
Yet it all implies that lift is
established and it will need energy to stay aloft, thus the high powered
conventional turbine. Yet our
understanding is no further advanced had they arrived with a flying brick,
which this obviously resembles.
On the basis of their claims, we
have an efficient heavy lifter which is very good news and badly needed for
plenty of applications. By appearances
though, it is likely that horizontal velocity will be limited as a trade
off. We can live with that. Bring the cost down and have a device
cruising at a max of sixty miles per hour and plenty of tasks are available.
To start with, log extraction is
a primary application. Heli-logging is
working because of an emphasis on efficiency that is increditable. It is still barely sustainable. A heavy lifting system able to boost twenty
tons of logs and able to then shift a fair distance is a much better model. Speed has to stop been the priority.
This also promises to be a useful
device for agricultural applications allowing harvesting to feed draw points
and to thus avoid excessive land disturbance.
Even better we become less dependent on road access. Perhaps we can simply move heavy equipment to
fields as needed.
D-Dalus - an entirely new genre of aircraft arrives
By Mike Hanlon
11:27 June 21, 2011
Austrian research company IAT21 has presented a new type of aircraft at
the Paris
Air Show which has the potential to become aviation's first disruptive
technology since the jet engine.
The D-Dalus (a play on Daedalus from Greek mythology) is neither fixed
wing or rotor craft and uses four, mechanically-linked, contra-rotating
cylindrical turbines, each running at the same 2200 rpm, for its propulsion.
The key to the D-Dalus' extreme maneuverability is the facility to
alter the angle of the blades (using servos) to vector the forces, meaning that
the thrust can be delivered in your choice of 360 degrees around any of the
three axes. Hence D-Dalus can launch vertically, hover perfectly still and move
in any direction, and that's just the start of the story.
Like most cars and aircraft these days, it sounds very complex but it's
all controlled by computer algorithms, so it's simple joystick control for the
user, and far less exacting than a helicopter to fly.
Existing rotary wing aircraft offer VTOL capabilities but have
vulnerabilities which make them unsuitable for many applications. They are
challenged in bad weather, at long ranges, at high speed and in operating to
and from lurching platforms, such as boats in rough weather.
By contrast, D-Dalus is particularly suited for such conditions and can
thrust upwards and hence "glue down" on landing, which it can also do
on a moving vehicle. Indeed, landing on a moving vehicle is one of the D-Dalus'
many party tricks, and it's a natural for landing on watercraft. Not
surprisingly, since it initially broke cover at the Royal Aeronautical Society
conference a few days ago, it has already attracted a lot of interest from
military quarters.
The D-Dalus is also near-silent, and has the dynamic stability to enter
buildings and handle rough weather with ease - things which existing rotorcraft
simply cannot achieve. The aircraft also has a sense-and-avoid system which, in
conjunction with its complete lack of vulnerable external parts (such as
rotors), means it can hover in very close proximity to vertical rock faces and
walls, making it suitable for search-and-rescue operations, as a surveillance
drone with hover-and-stare capabilities and as a proactive tool for urban
battlefield situational awareness.
The lack of vulnerable external moving parts will give a small
D-Dalus-type drone the ability to fly into buildings through windows, and its
unique capabilities also offer 360 degree vision, another aspect lacking in
traditional rotor craft which have blind spots due to the rotors, and nowhere
near the same maneuverability as the D-Dalus.
IAT21 forsees many applications based on these key new criteria - apart
from being able to enter and search buildings, it could conceivably remove
radioactive contamination or explosives, extract casualties, or hold and direct
water hoses for fire fighters.
As it can lift heavy loads, and becomes even more efficient in doing so
as it scales upwards in size, it is also envisaged as a platform for loading
and unloading ships when cranes are not available.
The D-Dalus is also so simple mechanically that it needs little
maintenance and requires no more maintenance expertise than an auto mechanic.
It should be noted that all VTOL aircraft capable of carrying large payloads
are complex and very costly to maintain.
Currently, tests are being conducted using a 120 bhp KTM engine and
turbines around five feet long - and the capability of lifting a payload of 70
kg. More tests are planned over the coming weeks. IAT21 is now also working
with Cranfield University in the U.K. on a larger, more powerful motor, a new
hull shape for the craft, and advanced guidance and control systems.
The forces on the blade pivots are understandably huge, and in initial
testing it was found that all available bearings failed, so inventor Meinhard
Schwaiger, who already has more than 150 patents to his name, knuckled down and
invented (and patented) his own, near-frictionless swivel-bearing to cope with
the stresses.
The D-Dalus is
constructed of carbon fiber, and appears to be scalable for a range of
potential applications including maritime search and rescue, freight transport,
operating alongside and within buildings during fires - the long term hopes for
the platform include a passenger version for public transit.
D-Dalus is a
new aerial platform that can approach as gently and silently as a hot air
balloon, can stay in the air like a humming-bird, can rotate in any direction
like a football, can ‘glue down’ on the deck of a ship like a ‘tossed pancake’,
can see in all directions like a crystal ball, can fly as fast as a jet, is as
invisible as a 155mm shell and can be repaired by a local car mechanic. It
can lift heavy loads, and becomes even more efficient in doing so as it
scales upwards in size, it is also envisaged as a platform for loading and
unloading ships when cranes are not available.
At the heart of D-DALUS is a revolutionary propulsion system containing
a number of patented inventions, including a friction free bearing at the
points of high G force, and a system that keeps propulsion in dynamic
equilibrium, thereby allowing the guidance system to quickly restore stability
in flight.
The propulsion consists of 4 sets of contra-rotating disks, each set driven at the same rpm by a conventional aero-engine. The disks are surrounded by blades whose angle of attack can be altered by off-setting the axis of the rotating disks. As each blade can be given a different angle of attack, the resulting main thrust can be in any required direction in 360° around any axis. This allows the craft to launch vertically, remain in a fixed position in the air, travel in any direction, rotate in any direction, and thrust upwards thereby ‘gluing down’ on landing.
D-DALUS is currently in prototype stage. Over recent weeks IAT21
have conducted extensive constrained flight tests in a specially prepared
laboratory near Salzburg ,
including the transition from vertical to forward flight, and are now ready to
move to an open test range for free flight tests. In trials to date D-DALUS has
met the performance criteria placed upon it and appears to be scalable,
becoming more efficient and less complex as it increases in size. It will
therefore be ideally suited for applications that range from maritime search
and rescue, through the carriage of freight, to operating alongside and within
buildings during fires or, for example, nuclear accidents.
Currently, tests are being conducted using a 120 bhp KTM engine and turbines around five feet long - and the capability of lifting a payload of 70 kg. More tests are planned over the coming weeks. IAT21 is now also working with Cranfield University in the U.K. on a larger, more powerful motor, a new hull shape for the craft, and advanced guidance and control systems.
The forces on the blade pivots are understandably huge, and in initial testing it was found that all available bearings failed, so inventor Meinhard Schwaiger, who already has more than 150 patents to his name, knuckled down and invented (and patented) his own, near-frictionless swivel-bearing to cope with the stresses.
The D-Dalus is constructed of carbon fiber, and appears to be scalable for a range of potential applications including maritime search and rescue, freight transport, operating alongside and within buildings during fires - the long term hopes for the platform include a passenger version for public transit.
1 comment:
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