SOFC in Alaska Bring High Uptimes and Improved Efficiency

Mission requirements change – and not just by the month or year, but by the day or hour. The more flexible the uncrewed aircraft executing the mission, the greater the ability to pivot and adapt to meet these changing requirements. An effective UAS solution offers options that address long range and long endurance operations while remaining silent, light, and mobile, which is essential to overall preparedness and mission success.

Answering the Need for Options

While the logistics footprint of airborne intelligence, surveillance, and reconnaissance (ISR) grows smaller, the requirements surrounding mission needs continue to expand. Small uncrewed aircraft systems (sUAS) and Group 2 UAVs are now expected to successfully complete operations that used to be in the purview of larger aircraft.

This means that the aircraft must not only be smaller and lighter but must also have the system flexibility to meet a wide variety of mission needs. Whether this means operations in sub-artic temperatures, nighttime or low light flights, the addition of multiple payloads, long-range targets, or any of a long list of challenges, an effective sUAS platform needs to offer options that are easy from a logistics and operational standpoint.

“A more robust common operating picture is vital to mission success,” says Josh Stinson, Edge Autonomy Chief Growth Officer and Army Special Forces Veteran. “To achieve greater awareness of the operational environment, today’s warfighter needs to see farther and understand more. The mission flexibility of an uncrewed system and its ability to provide greater dwell time in that environment directly impacts the effectiveness of the warfighter.”

And what feature has a major influence on the overall endurance of an sUAS? Its power source.

In recent years, the requirement for silent propulsion systems has emerged as a must-have feature of an sUAS. The majority of ISR operations require the sUAS to remain undetected while performing its mission. Unfortunately, silent operations are effectively impossible with a traditional internal-combustion engine. Hence, most sUAS have moved towards all-electric propulsion systems and utilize high-energy batteries as their energy source. But an sUAS that relies only on batteries (including even the most advanced battery technologies) has significant limitations compared to an sUAS with a traditional propulsion solution, most notably a major reduction in range, endurance, and payload capacity.

What if a new power system could plug directly into the battery slot on an sUAS and provide four times greater endurance, range, and payload capacity while still remaining silent? And what if this product could be hot swapped with batteries from one flight to another depending on the needs of the mission? Edge Autonomy has developed this technology and is currently flying with it across six continents, performing flight operations in the most austere and harsh conditions.

TRL 9 flight proven through successful operations, our micro-tubular solid-oxide fuel cell (MT-SOFC) runs on propane, unlike common fuel cells that run on hydrogen. And with our advanced onboard filtration system, the MT-SOFC can consume the dirtiest propane you can find. This means that you can grab a propane canister from a military kitchen, a local BBQ stand, or a rundown gas station in the middle of nowhere. Best of all, propane is used in every city and village on earth, so a fresh (or dirty) can of propane is always available without special logistics.

Moving Beyond Just the Battery

With nearly four decades of aeronautical innovation, Edge Autonomy has seen the battlefield evolve, and with that evolution we have pioneered breakthroughs in technology that move in lock step with our customers’ missions. While continuously pushing the limits of long endurance and long-range reconnaissance, our uncrewed aircraft systems have remained adaptable for each unique intelligence, surveillance, and reconnaissance mission we fly.

As the original equipment manufacturer (OEM) of the VXE30 Stalker UAS and its advanced Havoc configuration, Edge Autonomy has equipped these aircraft with state-of-the-art batteries that can achieve a flight time of six hours on electric power alone. When the mission calls for even longer range or greater endurance, batteries can be swapped with our MT-SOFC that is not only easily accessible and field swappable, but capable of extending mission parameters by up to four times farther in terms of distance, flight time, and payload capacity. And because the system remains all electric even under fuel cell power, the VXE30 Stalker and Havoc configuration maintain silent operations throughout the entire flight.

We have spent the last 25 years honing our MT-SOFC technology by testing it across a variety of operational areas around the world in harsh weather conditions. Powered by propane, this technology increases the flight time of our battery-powered UAS and has already proven effective in long-range operations with hundreds of thousands of hours flown across six continents.

The result? The VXE30 provides maximum mission flexibility by allowing the operator to choose between battery and fuel cell on every flight. If you have a few batteries charged up and only need to fly 4-6 hours, then plug a battery into the aircraft and takeoff. However, if your mission demands significantly greater range and endurance, then plug the fuel cell into the aircraft and takeoff. A fuel cell is not a replacement for the batteries on a VXE30, it’s just an additional tool available to the operator to dramatically boost endurance and range on the missions that require it.

Achieving Mission Success with Any Propane, Anywhere

When executing a successful ISR mission, every second counts and every gram of payload weight matters.

“Imagine a drone operator flying a long-range mission in a remote environment,” says Dr. Tom Westrich, VP of Technology at Edge Autonomy. “The combination of a battery and fuel cell – like we see in the VXE30 Stalker – extends the flight, but if refueling means the need to carry specialized fuel then the mission is ultimately made less efficient.”

By equipping aircraft with a small, lightweight, and proven fuel filtration system, Edge Autonomy ensures that soldiers in the field have the autonomy to refuel the Stalker with any available propane, whether from a petrol station, a convenience store, or a kitchen in a nearby village. With no need to source specialized propane, mission operations can continue without the inconveniences of added time and expense.

How does this innovative fuel cell filtration system work?

Sulfur and other odorants are added to most propane and natural gas sources, but over time these inhibit the electrochemical reaction needed to generate power from a fuel source.

The unique filtration system within Edge Autonomy’s fuel cell captures these additives, resulting in a clean, immediately usable fuel for optimal operational efficiency.

Fuel cells that rely on other energy sources—such as hydrogen—must depend on the creation of metal hydrides, a complex chemical process that cannot be completed easily in the field, which gives hydrogen-based fuel a much larger logistical footprint.

“But a soldier can locate propane in almost any environment,” says Westrich. “And because of our unique filtration system, it doesn’t matter how dirty that propane is—the UAV operator can simply fill a tank from ANY source and use that to directly power the VXE30 Stalker. They’ll be flying again in minutes.”

How long does this refueling process take?

“To hot swap a single tank on a fuel cell for the VXE30 Stalker, you need about 20 seconds—at most 60 seconds if you’re taking your time,” Westrich explains.

Switching out the two fuel tanks and filters on the VXE30 advanced Havoc configuration doesn’t take much longer, as both are located externally on the aircraft’s wings, making them easily accessible.

Innovations That Take ISR Missions Farther

The long-term mission benefits and potential savings of a UAV with a proven dual power source are significant.

“Longer flight times and more range increase overall mission efficiency, as well as the likelihood of success,” says Stinson. “Buying the operator the time and flexibility needed to accurately assess each situation provides the opportunity to respond to the most immediate needs of the battlespace.”

And increased flight time and range aren’t the only advantages when it comes to in-field operations.

“Every piece of equipment and pound of weight makes a difference to the warfighter,” Stinson explains. “When you don’t have to account for additional batteries or specialized fuel with your supplies you have room for other essentials like food, water, and ammunition.”

The VXE30 Stalker’s dual power source gives it greater range and endurance compared to similar sUAS on the market, and the flexibility the aircraft offers in fuel sourcing means greater efficiency as well.

“We consider our customers’ missions to be our missions as well, and we are constantly innovating toward greater success and efficiency for them,” says Stinson. “I’ve been there myself, as have many of our researchers and engineers, and we appreciate the technology that goes into battlefield operations.”

Learn more about our VXE30 Stalker, the Havoc configuration, and the technology behind our innovations.

FLY FARTHER. FLY LONGER. CARRY MORE.

SOFC are being adopted in one of the country’s harshest environments because they deliver on reliable uptimes and incredible fuel efficiency

With temperatures as low as –40°F during winter, frequent hurricane-force winds so strong they can break wind turbines, and weeks to months of the year with virtually no sunlight, Alaska has some of the harshest weather in the United States.

And it also has some of the remotest areas. Several villages are accessible only by plane or dogsled; in fact, more than 75% of communities lack access to roads and rely on aviation for food, mail, jobs and more.

Solar & Wind Unable to Provide 100% Uptimes in Alaska

This harsh environment can be difficult for common offgrid power sources, such as solar panels or wind turbines, to accommodate.

Because of the extended periods of darkness in Alaska, solar panels must have auxiliary power to keep the equipment running at night. Batteries are common, but some can fail in extreme cold, such as Flooded and Valve-Regulated (VRLA) batteries, because they freeze.

And if there’s no excess energy produced by the solar array during daytime, the batteries can’t power the load at night. Solar panels can also get covered with hoarfrost or rime ice that completely blocks sunlight from hitting the panels — even during the day.

Turbines are often paired with solar panels since they require little maintenance and no fuel, but they can ice over and freeze or even break in Alaska’s gale-force winds, causing them to fail in such a harsh climate.

SOFC Offer Greater Reliability And Lower Fuel Burn

Solid Oxide Fuel Cells are becoming more popular in Alaska, especially as part of hybrid energy systems, because they provide backup or offgrid power that is highly dependable and efficient. In fact we have seen remarkable success with our customers who have implemented our SOFC solutions.

Strong Market Acceptance in Alaska With Federal Agencies & Commercial Customers
These SOFC have been tried and field-proven over years of use in Alaska’s harsh and remote terrain, providing major uptime boosts to federal agencies and commercial customers.

To date, Alaska Railroad has deployed 40 systems as offgrid power for signals, switches and crossings since 2015 across its 650 miles of track; AT&T uses SOFC as backup power on towers; the Federal Aviation Administration supplements solar with SOFC in their weather camera program; and the USDA Forest Service relies on 24 SOFC as offgrid power for remote radio networks, with plans to add 50 more sites in 2022.

“This ultimately saves money, time, and risk.”

– Stacy Griffith, Alaska Forest Service Region Radio Manager

Benefits of Adaptive Energy’s SOFC in Extreme Harsh Weather

No unscheduled or emergency site visits because SOFC need no routine maintenance
Highly fuel-efficient at 80 run hours on just 20 pounds of propane, with many sites only needing to refuel every two years
Reliable even in frigid temperatures thanks to propane’s low freezing point and a system that’s uniquely engineered to excel in temps as low as -40°C
Designed to integrate with renewables such as solar, wind or rechargeable batteries – read more about that here
At just 19 pounds, SOFC are lightweight enough to be hand-carried into the field
Have a small footprint in an aircraft when being flown to a remote site

Case Studies of SOFC Performance in Alaska

USDA Forest Service’s Hybrid Offgrid Power System
SOFC provided highly reliable power at about $30 per year in fuel, compared to $7000 fuel costs for a generator

Rangers with the USDA Forest Service rely on remote radio networks to maintain vital communication — especially during emergencies. Stacy Griffith, the Alaska Region Radio Manager, shared in an interview that they faced a major hurdle in finding an offgrid power solution that would keep the 100W radio stations powered, regardless of weather conditions.

What was causing the problem? At offgrid and high-altitude sites, equipment and fuel had to be airlifted. The agency was spending thousands of dollars per year just on maintaining the radio networks. And the solar arrays frequently lost power due to harsh weather and low sunlight — compromising critical communications.

After several other solutions were tried and failed, Forest Service turned to Adaptive Energy to help. Unlike other technologies, our SOFC excel in extreme cold because they are engineered to store, start and operate in temperatures from -40°C to 50°C. They produce no liquid water and are made of heat-resistant ceramic tubes that will not freeze. So, the radio stations will stay up even in the harshest weather.

“Before the fuel cells, the region’s radio towers used legacy generators that ran 24/7 off natural gas, costing about $90,000 a year for refueling. Another cost observation showed the SOFC needing only $30 of fuel compared to the generator that averaged more than $7,000 per season.”

– The USDA

Auxiliary Power to A Solar Array for the Federal Aviation Administration

Weather camera stations along critical aviation paths experienced previously unachievable uptimes thanks to SOFC.

The FAA maintains three solar-powered weather cameras along Lake Clark Pass that are critical for the safe air transport of people and cargo. However, the area’s harsh winter weather, hurricane-force winds and low sunlight caused frequent power outages.

The FAA needed reliable backup that would keep the cameras up even in the harshest weather, but all the standard options failed. Wind power, a typical backup for solar arrays, wasn’t viable due to freezing temperatures and hurricane-force winds that were breaking the turbines. And generators like TEGs were too inefficient – demanding six 100-pound bottles of propane per year in order to run.

The team installed a Performer Series 250W SOFC system as a trial. Through this, they saw a massive difference. Of the three weather camera sites, the only one to experience zero outages for the entire winter was the one running the SOFC. This is on top of the dramatic savings in the total cost of energy, which has led the FAA to work towards using SOFC on more of their remote sites.