If you have been reading the Blog for a while you will know that Festo is not a stranger to this Blog. They have been making the news pretty regularly every year with their Bionic Learning Networks flying animals which they develop as eye catchers for the Hannover Messe each year. After the flying manta ray called Air_ray in 2007 and the flying jellyfish called AirJelly in 2008 this year it's penguins and you guessed it they are appropriately named AirPenguin. The Air_ray did make it onto YouTube a while after it was presented at the Hannover Messe, the AirJelly was uploaded by Airshipworld to YouTube directly when it was published on Festos website, the result was that the AirJelly got a tremendous publicity all over the web with over 380.000 views of it's video. This year Festo decided to start their own YouTube Channel called FestoHQ and they added all the Videos of the things that they will be presenting at the Hanover Messe 2009 which starts tomorrow April 20th 2009. So here you go watch the graceful AirPenguins fly, and also watch the second video with some more of Festos projects that they will be presenting, the second Video also contains an explanation of the AirPenguins. Unfortunately Festo disabled the embedding of the videos which is a shame. If you aren't into the videos to much, just below we have added the whitepaper that you can get from Festo which explains the Airpenguins technology, its an interesting read especially for those building small remote conrtolled airships themself.
AirPenguin A group of autonomously flying penguins Info Flying through the sea of air with collective behaviour AirPenguin – technology-bearers for adaptive flapping-wing mechanisms The AirPenguin is an autonomously flying object that comes close to its natural archetype in terms of agility and manoeuvrability. It comprises a helium-filled ballonett, which has a capacity of approx. 1 cubic metre and thus generates approx. 1 kg of buoyant force; at each end of the ballonett is a pyramid-shaped flexible structure of four carbon fibre rods, which are connected at joints by a series of rings spaced approx. 10 cm apart. The rings together with the carbon fibre rods yield a 3D Fin Ray ® structure that can be freely moved in any spatial direction. The Fin Ray ® structure was derived from the anatomy of a fish’s fin and extended here for the first time to applications in three-dimensional space. Each pair of spatially opposed carbon fibre rods is connected via bowden wires and a double pulley, and can be extended and retracted in contrary motion by means of an actuator. This gives rise to rotation free of play both at the tip of the AirPenguin’s nose and at the end of its tail. By superimposing two perpendicular planes of rotation, any desired spatial orientation can be realised. A strut to which the two wings are attached passes through the helium-filled ballonett. This new type of wing design can produce either forward or reverse thrust. Each wing is controlled by two actuators: a flapping actuator for the up-and-down movement of the wings, and a further unit that displaces the wing strut to alter the pressure point of the wings. There is also a central rotational actuator for the two flapping wings that directs their thrust upwards or downwards, thus making the AirPenguins rise or descend. All three actuators are proportionally controlled. This makes for continuously variable control of the flapping frequency, forward and reverse motion, and ascent and descent. Penguins are fascinating creatures which have lost their ability to fly in the course of their phylogenetic development as marine birds. With the AirPenguins, the engineers have created artificial penguins and taught them “autonomous flight in the sea of air”. The knowledge acquired from this research project of Festo’s Bionic Learning Network is to be put to use for future requirements in the automation of production processes. The entire wing complex comprises a strut with flat flexible wings of extruded polyurethane foam. The wing strut, which is supported at the pivot point of the torso, can be moved either towards the front or rear edge of the wing. Displacing the strut towards the front, for example, causes the wing’s pressure point to migrate forwards. The pressure of the airstream bends the cross-section of the wing in such a way as to produce a profile that generates forward thrust. If the wing strut is moved towards the rear edge of the wing, the pressure point is likewise moved to the rear, and the AirPenguin flies backwards. With this design a self-regulating, wing pressure-controlled, passively twisting adaptive wing has been realised for the first time. 2 Rear section with 3D Fin Ray ® structure AirPenguin – autonomous self-regulating systems with collective behaviour The AirPenguins are also equipped with complex navigation and communication facilities that allow them to explore their “sea of air” on their own initiative, either autonomously or in accordance with fixed rules. The underlying project: A group of three autonomously flying penguins hovers freely through a defined air space that is monitored by invisible ultrasound “transmitting stations”. The penguins can move freely within this space; a microcontroller gives them free will in order to explore it. The microcontroller also controls a total of nine digital actuators for the wings and for the head and tail sections. By means of XBee, based on ZigBee, large volumes of data can be transmitted between the penguins and the transmitting stations by 2.4-GHz band radio. The penguins recognise each other on the basis of their distances to the transmitting stations. The rapid, precise control allows the AirPenguins to fly in a group without colliding, while also mastering height control and positional stability. As an alternative, they can act synchronously as a group. A comprehensive central surveillance system provides security in case of sensor failure and reports low energy supply. Whenever necessary, it prompts the penguins to return to the charging station. Technology-bearers for the automation technology of tomorrow If the 3D Fin Ray ® structure of the head and tail sections is transferred to the requirements of automation technology, it can be used for instance in a flexible tripod with a very large scope of operation in comparison with conventional tripods. Fitted with electric drive mechanisms, the BionicTripod from Festo for example makes for precise, rapid movements, just like the AirPenguin. Autonomous, versatile, adaptive self-regulating processes will acquire increasing significance in future for automation in production. The animal kingdom can provide insights here which, when implemented by resourceful engineers, lead to astounding new applications. The ongoing development of sensor and control technology is thus also being promoted along the road to decentralised, autonomously self-controlling and self-organising systems thanks to inspiration from nature. The transfer to automation technology is also to be found by analogy in regulating technology from Festo, for example in the new VPPM and VPWP proportional-pressure regulators for servo-pneumatics. 3 Technical data Overall length: Max. torso diameter: Helium volume: Wing span: Weight: Control of wings, head and tail segments: Materials Buoyancy body: Head and tail segments: Wings: Wing strut: Accumulator battery for wing drive and torso orientation: Receiver sensors: 3.70 m 0.88 m 0.980 cbm 2.48 m 1.0 kg 9 digital actuators, range 180° aluminium-metallised foil, 22 g/qm 3D Fin Ray Effect ® structure of carbon-fibre rods extruded polyurethane foam carbon-fibre rod Project partners Project initiator: Dr. Wilfried Stoll, Chairman of the Supervisory Board, Festo AG Project manager: Dipl.-Ing. (FH) Markus Fischer, Corporate Design, Festo AG & Co. KG AirPenguin concept and realisation: Rainer and Günther Mugrauer, Clemens Gebert Effekt-Technik GmbH, Schlaitdorf, Germany Autonomous control concept and realisation: Dipl.-Ing. Agalya Nagarathinam, Dipl.-Ing. Kristof Jebens Ingenieurbüro Jebens & Nagarathinam GbR, Gärtringen, Germany Photos: Walter Fogel, Angelbachtal, Germany Graphic design: Atelier Frank, Berlin, Germany Li-Po battery, 2000 mAh, 4.2 V 32-bit microcontroller @ 50 MHz MCU 2x LM3S811 64 kbyte flash, 8 kbyte RAM SCP 1000 pressure sensor ultrasound receiver capsules Altitude measurement: Distance measurement: Measurement of rotation rate about vertical axis: Lisy 300-AL gyroscope Directional and positional sensors: positionally compensated 3-axis compass with accelerometer Temperature measurement: temperature sensor 2.4 GHz radio transmission: based on ZigBee Current and voltage monitoring for Li-Po cell Overvoltage protection: DS2764 Li-Po protector Charging controller for Li-Po cell: Max1555 charging controller Accumulator battery: Li-Po battery, 2000 mAh, 4.2 V Base stations/ transmitting stations: Altitude measurement: Distance measurement: Temperature measurement: 2.4 GHz radio transmission: Current and voltage monitoring for Li-Po cell Overvoltage protection: Charging controller for Li-Po cell: Energy reserve for approx. 50 h continuous operation: Brands: 32-bit microcontroller @ 50 MHz MCU LM3S811 64 kbyte flash, 8 kbyte RAM SCP 1000 pressure sensor ultrasound transmitters temperature sensor based on ZigBee Festo AG & Co. KG Corporate Design Plieninger Straße 50 73760 Ostfildern Germany www.festo.com/bionic Phone +49 711/347- 38 80 Fax +49 711/347- 38 99 fish@ de.festo.com DS2764 Li-Po protector Max1555 charging controller Li-Po battery, 2000 mAh, 4.2 V Fin Ray Effect ® is a brand of EvoLogics GmbH, Berlin, Germany 54709/EN
I don't want to leave you completely without videos so here the Air_ray and the AirJelly videos from 2007 and 2008.
I stumbled last month across a really great article from the Blog Dark Roasted Blend, called Airship Dreams. It really wakes the dreamer in all of us and illustrates why Airships have and will always inspire and fascinate people. The article talks about the past the present and of course the future of airships. Mentioning the Festo Airray, the Aeroscraft and our friends from Airshipventures. It's worth a read even if it is just for all the great pictures of past concepts, the glory days of the Graf Zeppelin or the great rigid airships of the Navy. The article has been online for a while but I just wanted to share it because it is really great. Do you think the airship industry is on the right path to make a comeback? What does it take for airships to make the break through from niche to mainstream?
Some time ago there has been an Article circulating the web about "Airships that «swim» through the atmosphere" the idea is to use so called electro active polymers to bend and airships body so that it moves like a fish. This Airship is constructed by the Empa a materials science and technology research institution that is part of the ETH Domain. But this is not the only fish in the sky. Prospective Concepts another Company from Switzerland developed the Flying Stingray an ultralight lifting body in the shape of a stingray but still using propellers as propulsion. You can read some more background info at MyAirship.com But wait isn't there more? Of course there is. We proudly present the Festo Air Ray, a manta ray shaped helium filled rc airship that flies by flapping it's wings rather than using a propeller. Watch the stunning video of the Air Ray literally swimming through the air. A really innovative new concept that actually works. You can also check out the animation and a PDF with more detailed information and contact info. But the story about new and revolutionary concepts doesn't stop here. Last but by no means least, the Festo b-IONIC Airfish a remote controlled airship that uses an ion beam propulsion system. Yes you read correct those ion beam drives that are used in space missions are now applied to propulsion systems or aircraft. But besides using this just for propulsion the engineers at Festo also discovered that the effect created could also be used to reduce and even eliminate drag if the whole vessel would be enclosed by a ionized plasma bubble. When one thinks about airships and their huge surface area and the aerodynamic drag they produce this might be a solution that could change how we look at airships. Check out the video of the Airfish and the PDF going into detail and also containing some more pictures. We will continue to look at Festo in the future, since they are an active supporter of the Lighter-Than-Air community, right now also supporting GEFA-Flug in the development of the new 6 seater Hot Airship by donating their Envelope for tests. But more about that in a different post. Do you know of any other revolutionary concepts, and research projects that try to copy nature or just try to go new ways in Airship design? Please send us a link or write a comment we are eager to hear what is currently developed out there. I have to thank Paul Bloch a friend of Airshipworld at openartist.net who send me the links about the Festo Air Ray and the b-IONIC Airfish, he is also involved in the Airship League activities, so expect to hear more from him and the League soon. Additional credits also go to Paul for his comment on the Aeroplume post who inspired the title.
© Festo
