GPS World

Tag: Nordic Unmanned

  • Offshore deliveries, carrying people are new UAV developments

    Offshore deliveries, carrying people are new UAV developments

    A new offshore service opportunity for an already proven mini-helicopter UAV, a possible alternative to flying cars, and bulking up UAVs to carry cargo – just a few of this month’s new developments in unmanned aircraft.

    Oil Services UAV?

    S-100 Camcopter. (Photo: Schiebel)
    S-100 Camcopter. (Photo: Schiebel)

    If you’ve ever gotten close to the Schiebel Camcopter S-100, such as at a trade show, or if you’ve worked with one, you’ve probably noticed that it’s a rugged, weather-hardened vertical take-off UAV.

    It would seem that both military and maritime operations would be natural applications — so it’s not surprising that the United Arab Emirates (UAE) Army and German Navy have both bought S-100s.

    The U.S. Air Force Research Laboratory (AFRL) also investigated use of the S-100 for detection of improvised explosive devices (IED).

    The S-100 is a vertical take-off and landing, unmanned mini-helicopter with a top speed of around 138 mph, a range of just over 100 miles, with two payload bays, an electronics bay, and the ability to carry underslung loads — the all-up payload is 110 pounds. Sensors include an electro-optical/infrared (EO/IR) camera, an electronic support measures (ESM) system for detection and identification of electronic signatures, and synthetic-aperture radar (SAR).

    So it’s no surprise that a recent trial demonstrated the S-100’s long-range, high-speed capabilities to deliver parts to a Norwegian offshore oil rig.

    Nordic Unmanned and Schiebel flew a demonstration S-100 for rapid delivery of a 3D-printed replacement part from Mongstad out 55 miles to the gas production platform Troll A in the North Sea. This is said to be the first full-scale offshore UAV delivery from shore to an active oil and gas installation.

    The demonstration simulated an urgent requirement for a nozzle holder for injecting diesel fuel into the platform’s lifeboat engine. Maintaining safety regulations and production flow from these offshore platforms is essential, but both ship and helicopter emergency trips out to platforms can be risky and downright dangerous in bad North Sea stormy weather — so the UAV option may save lives, time and cost.

    Before flying back to base on the mainland, the S-100 also demonstrated its ability to closely inspect the operational platform, and even carried out a simulated search and rescue, locating a dummy in the water and providing live video and location data from its L3 Harris EO/IR camera and an Automatic Identification System (AIS).

    Do we really need flying cars?

    Where are we with people-carrying drone taxis and cars? To get them in the air for demonstration flights is tricky — there are a lot of  i’s to dot and T’s to cross before agencies like the U.S. Federal Aviation Administration (FAA) allow them to fly. There are also plenty of restrictions on where they can fly — certainly not over populated areas. It will undoubtedly happen eventually, but time is money, and regulations will likely outlast the financial supply for most start-ups.

    Because of this, one outfit with significant credentials has taken another tack — automating aircraft that have already earned their certified wings.

    The original Cessna 172 Skyhawk test flights and certifications successfully culminated in June 1955. The Cessna 208 Caravan gained FAA approval in October 1984. Both General Aviation aircraft have flown since then with established safety and reliability records. The FAA knows what makes a safe airframe, power plant and aircraft flight controls — what’s needed to qualify a remotely piloted, automated flight control system is surely a lot less than the complete aircraft and its existing systems.

    FedEx Cessna 208 Caravan. (Photo: Reliable Robotics)
    FedEx Cessna 208 Caravan. (Photo: Reliable Robotics)
    Cessna 172 Skyhawk. (Photo: Cessna)
    Cessna 172 Skyhawk. (Photo: Cessna)

    Ex-SpaceX software systems director Robert Rose decided that getting his autoflight system past FAA scrutiny would actually be an easier job. He started Reliable Robotics to get drone aircraft flying sooner.

    The company has now developed an autonomous platform that can be retrofitted into virtually any fixed-wing aircraft. The system comprises avionics, flight control software, a mechanical hook-up, and a communications system which enables remote command and control, along with a reversionary backup system.

    The autonomous system was integrated into a four-passenger Cessna 172 Skyhawk, and was used in an automated, unmanned gate-to-gate demonstration flight. The system underwent a full system safety analysis and test and the unmanned test flight included automatic taxiing, takeoff and landing.

    The Skyhawk was flown without a pilot on board over a populated area, which was an essential part of qualifying the Reliable Robotics platform for safe civil use on an already certified passenger aircraft.

    For the next test flight of a larger 14-passenger Cessna 208 Caravan, the integrated system again demonstrated full automatic remote landing of the aircraft. Reliable Robotics hopes that continuing certification efforts with the FAA will soon enable them to sell their automation system for certified unmanned passenger aircraft operations.

    Cargo UAV

    The majority of unmanned aircraft have been small. There’s even a category called small unmanned aircraft systems (sUAS) — so hanging a pizza on one for delivery by suppertime is about the most cargo you might imagine these things could carry.

    V20 and V300 cargo UAVs. (Artist's concept: Pipistrel)
    V20 and V300 cargo UAVs. (Artist’s concept: Pipistrel)

    One way to overcome this limitation — as we just saw — is to hook up a sophisticated auto-flight system to a passenger aircraft. Another way could be to build a large cargo-carrying UAV — like the Pipistrel (Slovinia) Nuuva V300, which is claimed to be able to carry up to 1000-pounds of cargo over impressive distances.

    The vehicle has eight identical electric motors for vertical take-off and landing, and a gas engine powers a pusher propeller for cruise. The vertical lift electric motor has apparently been certified for airborne use by the European Aviation Safety Agency (EASA).

    If the V300 cargo is reduced to 110lb, it looks feasible for it to fly over 1500 miles at up to 8,000ft. Pipistrel claims this operational cargo envelope to be 10 times more efficient than for an equivalent helicopter. Pipistrel has also launched a smaller V20 cargo version with the same offset wing set up and smaller electric lift and cruise propulsion — aimed at last-mile deliveries.

    Seems the V20 is available fairly soon, but the V300 still has work to do — presumably certification effort – and won’t be available till 2023.

    Until next time

    So potential oil-platform service deliveries for the S-100 Camcopter, turning already certified aircraft into passenger carrying unmanned vehicles, and UAVs coming for cargo carrying — all are new, promising and different UAV exploits. Let’s hope they all become commonplace in the coming years.

  • UAVs monitor marine emissions, string powerlines

    UAVs monitor marine emissions, string powerlines

    A couple of interesting drone applications came up this month — marine smoke emission monitoring and studies from a little known European drone manufacturer.

    Monitoring marine emissions

    Climate change: Some might say these are words we don’t really need to hear. Such a big to-do about how much human activity is affecting the weather changes that we are now seeing globally. Or is it all part of a natural cycle that the Earth is going through as many might say?

    I don’t really want to get into that argument, but it would seem useful that someone is doing something to reduce the use of dirty fuels by ships. After all, we seemed to readily acquiesce to unleaded fuel for our vehicles without a lot of protest; why would we accept this as the norm when marine transport still uses dirty bunker fuel, belching out a significant amount of pollution?

    If it’s good for people and their cars, and we quite possibly incurred some costs getting there, why not stick it on the marine industry too?

    So that’s what the International Maritime Organization (IMO) did in January this year, reducing the allowable sulphur content in marine fuel from 3.5 to 0.5%. Enforced under the international convention for the prevention of pollution from ships, this is aimed at cutting sulphur oxide emissions from ships by 77%, equivalent to a reduction of about 8.5  million metric tons annually.

    That’s the tricky bit – enforcement. Ships spend most of their time miles away from land, so knowing what their smoke emissions contain is somewhat difficult. Now (this is where I manage to tie things back to what I’m supposed to be reporting on) its useful that Schiebel, along with its partner operator Nordic Unmanned, thought about enforcement of the new regulations.

    Schiebel Camcopter S-100. (Photo: Schiebel)
    Schiebel Camcopter S-100. (Photo: Schiebel)

    With a range of up to 200 kilometers (~125 miles) the Camcopter S-100 can get out to the shipping lanes to check on what’s coming out of the smokestacks. Equipped with an automatic identification system (AIS), a sulphur sniffing sensor and an L3 Harris Wescam MX-10 real-time electro-optical/infrared (EO/IR) camera, the “enforcement drone” can determine which ship it’s flying over, what the smoke plume sulphur content might be, and even take geo-coded pictures to show in which jurisdiction the ship is sailing. If necessary, it can even take pictures of who’s throwing what at the overflying UAV.

    In recent tests, the Camcopter flew out of Gniben, Denmark, where European regulations on emissions applied, and marine exhaust fumes are limited to contain no more than 0.1 percent sulphur oxide. The Camcopter S-100 performed two 4- hour flights and provided real-time readings of the sulphur level in ships’ exhaust plumes.

    With these successful tests in the bag, Nordic Unmanned has indicated its capabilities to worldwide maritime authorities that they are ready and able to help enforce the new IMO regulations.

    European-built multi-rotor drone

    Acecore Technologies in the Netherlands makes multi-rotor drones which have found some unique applications:

    The NEO 8-rotor UAV. (Photo: Acecore)
    The NEO 8-rotor UAV. (Photo: Acecore)

    Stringing power-lines using NEO (SPIE website)

    In order to extend power transmission line capacity, the approach used is often to first pull a lead cable. This  normally involves several power company personnel and a whole bunch of specialized equipment.

    However, in a first-of-its-kind test, SPIE Nederland used an Acecore NEO drone to pull a lead cable over 150 meters between high-voltage pylons.

    Equipped with suitable cameras and other sensors, Acecore drones have also been used for power-line and gas-plant thermal inspection, movie making (including Game of Thrones), live broadcasts, autonomous aerial surveying, and tethered security applications. They also make crop health monitoring possible.

    Designed with durability in mind, Acecore drones are weather-proof, built with strong carbon-fiber frames, have triple redundant autopilots, and are ADS-B-ready to broadcast GPS position to support sense-and-avoid capability.

    Acecore is also promoting the fact that its drones and controllers are manufactured entirely with European parts. In other words, they would like to grab a chunk of DJI’s huge market share by jumping on an apparent global move to switch over from Chinese sourced goods and equipment.

    So, drones are taking on environmental monitoring. They’re reducing the environmental impact of transmission-line build-out. And they’re moving  toward building drones locally — all are interesting new applications of unmanned aircraft systems.

    Tony Murfin
    GNSS Aerospace