engine Archives - FLYING Magazine https://cms.flyingmag.com/tag/engine/ The world's most widely read aviation magazine Thu, 22 Aug 2024 20:05:30 +0000 en-US hourly 1 https://wordpress.org/?v=6.6.1 Lilium Begins Testing Electric Jet Power Systems https://www.flyingmag.com/modern/lilium-begins-testing-electric-jet-power-systems/ Thu, 22 Aug 2024 20:05:26 +0000 https://www.flyingmag.com/?p=213998&preview=1 The manufacturer put the aircraft’s electrical power system, comprising 30 engines within flaps on the main wing and canard, through a series of simulations and tests.

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At a purpose-built laboratory on the outskirts of Munich, German manufacturer Lilium has begun testing the electrical power systems that will juice up its vertical takeoff and landing (VTOL) jet.

The company on Wednesday announced it completed the first stage of power system integration testing, during which the technology was put through a series of simulated flights in a controlled environment.

As the firm works to manufacture its first two Lilium Jets, which it began assembling in December, these tests will help it demonstrate the aircraft’s powertrain performance and safety to the European Union Aviation Safety Agency (EASA). It seeks to certify the design under the regulator’s Special Condition for VTOL (SC-VTOL) rules by 2026 before rolling it out to customers worldwide.

The Lilium Jet’s powertrain comprises 30 battery-electric engines within flaps on the main wing and canard, which stow during cruise flight. Honeywell and Japan’s Denso are the main suppliers for the engine components.

The unique configuration is designed to give the aircraft the speed of a jet—about 154 mph (134 knots)—with the vertical takeoff and hover capabilities of a helicopter. Fully charged, Lilium expects it to be able to carry six passengers plus a pilot on city-to-city trips as long as 109 sm (95 nm).

The company’s electrical power system lab, located at its headquarters and test campus, was developed with help from aerospace testing specialist EN4 using software and hardware from test equipment provider NI.

According to the manufacturer, it has the ability to replicate the entire Lilium Jet powertrain from battery pack to engine. The lab’s low voltage systems can power the aircraft’s avionics and cabin systems. In addition, it boasts a functioning charging station and structures to mitigate the release of energy.

In the words of Gianluca Franchi, business development director of EN4, the facility is a “cutting-edge test rig, which has been designed to be a long-term asset supporting the Lilium Jet through certification and beyond.”

Lilium engineers are using a specially tailored software to chart flight profiles and run tests on the system. The company is collecting real-time data on those simulations, which will be shared with airworthiness authorities as evidence of compliance with its type certification requirements, it said.

“In this new lab, we test flights, charging, and simulate failure scenarios to ensure that our powertrain meets stringent aviation safety and reliability standards,” said Stephen Vellacott, chief technology officer of Lilium. “From first flight to certification and product launch, the lab enables us to demonstrate that our aircraft will be a world-leading product.”

Once power system testing is complete, the next major step for Lilium will be to fly the entire aircraft. The first jet off its production line will be deployed solely for ground testing, but the second is expected to make the model’s debut flight in early 2025.

The company so far has flown two Phoenix test aircraft, a full-scale, five-seat design intended to mirror the aerodynamics and hardware of its flagship model, and reached a cruise speed of 136 knots.

In June, it fired up the Lilium Jet’s engine to full throttle, marking another step toward crewed flight.

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Report: Boeing Grounds 777X Test Fleet https://www.flyingmag.com/aircraft/report-boeing-grounds-777x-test-fleet/ Tue, 20 Aug 2024 14:51:40 +0000 https://www.flyingmag.com/?p=213815&preview=1 The company suspended certification flight testing after it discovered problems with engine attachments in three test aircraft.

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The Air Current is reporting that Boeing has suspended certification flight testing of its new flagship 777X airliner after it found problems with the engine attachments in all three test aircraft.

The publication said a thrust link that helps secure the engine to its mounting structure was discovered to be broken after a flight from Kona, Hawaii, to Seattle.

Cracks in the thrust links on the other two aircraft were also discovered, prompting the grounding of the fleet.

The Air Current said Boeing confirmed the testing pause, saying it “identified a component that did not perform as designed” and that after replacement the company “will resume flight testing when ready.”

After a series of manufacturing and quality control issues, the announcement of certification flight testing of the new 777 variant was viewed as a boon for the troubled company. It’s not clear how long it will take to fix.

Thrust links help distribute loads within the mounting structure of the engine.


Editor’s Note: This article first appeared on AVweb.

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Lilium Prepares to Ramp Up Production of Electric Jet Propulsion Units https://www.flyingmag.com/lilium-prepares-to-ramp-up-production-of-electric-jet-propulsion-units/ Mon, 26 Feb 2024 20:37:19 +0000 https://www.flyingmag.com/?p=196355 The manufacturer of the seven-seat Lilium Jet begins to install a serial production line for the aircraft’s electric propulsion system, which powers 36 electric ducted fans.

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Lilium, the manufacturer behind the design of the seven-seat electric vertical takeoff and landing (eVTOL) Lilium Jet, is ramping up production of its flagship model.

The German firm on Monday said it has begun installing a serial production line for the Jet’s electric propulsion units at its manufacturing facility in Wessling, Germany. The company expects the first prototype propulsion systems—which will support for-credit type certification testing with the European Union Aviation Safety Agency (EASA)—to roll off its production line in the second quarter of 2024.

The production of electric propulsion systems for Lilium’s flagship Jet marks another key milestone in the commercialization of the aircraft, which the company began building in December. It hopes to achieve type certification in 2025 ahead of a global launch in 2026.

Lilium’s propulsion assembly line was designed in partnership with automation and robotics supplier Schnaithmann Maschinenbau GmbH, with which the manufacturer has worked for years to develop production plans. Schnaithmann will also provide workflow design, jogs, and tools for Lilium’s aerostructures assembly and final assembly line.

“The electric jet engine is a unique, core Lilium technology, critical for aircraft performance and for which we have secured not only a team of highly qualified system suppliers but also important intellectual property,” said Jan Nowacki, senior vice president of manufacturing for Lilium. “With the support of Schnaithmann, we look forward to implementing state-of-the-art manufacturing solutions capable of being scaled up and replicated for high-volume production.”

Lilium and Schnaithmann developed initial production plans several years ago in anticipation of this week’s announcement. The manufacturer’s aerostructures assembly line—located in the same building as the newly announced propulsion system assembly line—already uses Schnaithmann equipment to handle the Jet’s wings and canards.

The Wessling site also comprises a testing and manufacturing center, propulsion and aerostructures facility, final assembly building, and battery assembly building and logistics hub.

“With nearly 40 years of experience in supplying automation technology to global industries, we are proud to participate in the industrialization of the Lilium Jet,” said Gerd Maier, member of the Schnaithmann management board. “The eVTOL industry has the potential to change aviation in a positive, sustainable way, and we are delighted to be able to play a key role in helping Lilium scale up towards high-volume production.”

Lilium delivered the first of seven Jet fuselages to Wessling in December. The company will manufacture seven aircraft to use for EASA type certification validation, which it expects will begin late this year.

The manufacturer’s all-electric seven-seater is expected to fly passengers between towns and inner cities, cruising at 162 knots on trips spanning 25 to 125 sm (22 to 109 nm). The firm said the aircraft’s propulsion unit will be key in providing performance, unit economics, and comfort for regional air mobility (RAM) services.

RAM is a subset of advanced air mobility (AAM) that involves connecting cities across a broader region, as Lilium plans to do. It contrasts with the urban air mobility (UAM) approach adopted by many competitors, which intend to concentrate flights within a single city or metropolitan area, such as New York or Los Angeles.

The Lilium Jet propulsion unit consists of electric jet engines (or e-motors) integrated into a propulsion mounting system, which forms the rear part of the aircraft’s wings and front aerofoils. The company said the system will improve payload and aerodynamic efficiency, reduce noise, and provide thrust vector control to maneuver the Jet through all phases of flight.

Several components for the propulsion unit are provided by suppliers such as Honeywell, which is working with partners Denso, Aeronamic, and SKF to deliver e-motors, fans, and electric motor bearings, respectively.

The system powers 36 electric ducted fans embedded in the Jet’s wings. The unique architecture differs from competitors such as Joby Aviation or Archer Aviation, which are using tilt rotors that reorient themselves during the transition between vertical and forward flight.

In 2023, Lilium assembled the first complete electric engine for the Jet on a pre-series line. The engine is designed to deliver what the manufacturer claims is an industry-leading power density of over 100 kilowatts, despite the system weighing just less than 9 pounds.

Crewed flights of the Lilium Jet are expected to begin later this year as the company eyes for-credit testing with EASA. But Lilium is also the only eVTOL manufacturer with certification bases from both EASA and the FAA.

Earlier this month, the company designated Orlando International Airport (KMCO) as a key hub for its RAM service in Florida, which it announced in 2020. Fractional aircraft ownership company NetJets agreed tentatively to purchase 150 Lilium Jets and operate them across the Florida network, which will be supported with maintenance services from Bristow Group. FlightSafety International has agreed to train an initial cohort of Florida eVTOL pilots.

Lilium further announced support for Florida Legislature House Bill 981, which would designate Orlando International Airport as Florida’s official AAM test site. The legislation would also create a pathway for safe, efficient vertiport permitting in the state.

Last week, Lilium placed an order for 120 Star Charge electric aircraft charging systems, intended to juice up its ground and flight test aircraft. The manufacturer will also deliver chargers to customers investing in vertiports, further supporting its RAM ecosystem.

In addition, Lilium last week partnered with private and commercial operator PhilJets—which agreed to purchase 10 aircraft—to explore RAM networks in the Philippines, Cambodia, and across Southeast Asia.

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Loss of Thrust on Takeoff https://www.flyingmag.com/loss-of-thrust-on-takeoff/ Tue, 06 Feb 2024 16:06:40 +0000 https://www.flyingmag.com/?p=194690 I have written far too many stories about fatal accidents that were attributed to an uncommanded loss of engine power.

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“We have a problem, and we’re returning to the airport.”

These were the words of Richard McSpadden Jr., who was aboard the Cessna 177RG Cardinal belonging to former NFL tight end turned FBO owner Russ Francis. The pair launched from the airport in Lake Placid, New York, on October 1 for a photo flight for the Aircraft Owners and Pilots Association. McSpadden, the senior vice president of the AOPA Air Safety Institute, was a commercially rated pilot who had flown with the Air Force Thunderbirds.

Per protocol on these flights, Francis, as the owner of the airplane, would do the takeoff and landing, and Spad would take the controls for the air-to-air portion of the flight.

According to witnesses, the engine of the Cardinal surged during the takeoff and did not sound like it was making full power, yet the takeoff continued. The aircraft was in the air and out of usable runway when it turned and headed back to the airport. The runway is on top of a berm—the airplane came down in the ravine below its edge. Both men were alive and talking to rescuers, then moments later, they had passed away. The National Transportation Safety Board is still investigating the accident.

This hit me hard because I often talked with McSpadden about aircraft accidents and the importance of teaching and practicing the loss of thrust on takeoff. Although we still don’t know what caused the problem aboard the aircraft, there is a strong takeaway from this accident: if it could happen to Spad—Thunderbird Number One with all his training and experience—it could happen to any of us.

Briefing for LOTOTO

I have written far too many stories about fatal accidents that were attributed to an uncommanded loss of engine power. Often the accident happens because the pilot fails to maintain the appropriate speed as indicated on the aircraft’s emergency checklist—or worse yet, pulls back on the stick or yoke trying to stretch the glide, resulting in a stall-spin-die scenario.

A variation of this is when the pilot, trying to return to the runway, puts the aircraft into a steep bank resulting in a loss of vertical lift and a knife-edge impact in the ground.

While the procedure for engine loss at altitude is taught as an emergency usually before first solo, many pilots are not taught to brief the takeoff. That means a review of rotation speed, calling airspeed alive, and procedures if there is a loss of power on takeoff, until they begin their multi-engine training. This is a disservice to the aviation community.

Granted, in a twin, the loss of engine power on one side is dramatic in a different way, as it results in asymmetrical thrust, and the nose yaws and toward the dead engine. If the aircraft has lifted off, the asymmetrical thrust results in an uncommanded and often unrecoverable roll toward the sick engine resulting in a crash. Unless you bring the power on both engines back immediately and pitch for the appropriate V speed, you probably won’t live to tell the story.

In a single engine aircraft, a loss of engine power isn’t necessarily going to be fatal—as long as the pilot takes prompt and corrective action to maintain airspeed and has someplace to put it down.

Know the Speed You Need

There have been fledgling pilots who ask with some trepidation if a loss of engine power during takeoff is common. The answer is no, but knowing what to do if it does happen is like knowing how to put out a grease fire in your kitchen—you do not have time to experiment and an improper procedure like using water on the fire—or pulling back on the yoke or stick—can make a bad situation worse.

In the aircraft, you need to know what airspeed to pitch for. This is critical.

This speed will vary by make, model, and configuration. This information comes from the pilot’s operating handbook or aircraft flight manual and may even be placarded in the aircraft.

The pilot should also note rotation speed, and do the takeoff calculation before getting into the airplane, noting runway condition, temperature, and pressure.

Knowing what performance to expect helps you determine when a takeoff is going poorly and should be aborted. Identify an abort point. For example, if you calculate based on given conditions that you will need 1,130 feet to lift off from that 3,600-foot runway and you’re approaching 2,000 feet and you’re not up yet and the tachometer shows less than full power, abort.

Quick Reference Cards

If you fly multiple aircraft you may find it handy to make notes for each one and keep them with you for review before a flight in a particular airplane.

The first flight school I worked at had more than 10 Cessna 172s of varying models. The older models had airspeed indicators in miles per hour, the rest of the fleet was in knots. This could and did result in confusion that came back to bite a few pilots. I didn’t want to be one of them, so I wrote out the emergency speeds and V speeds for each aircraft on 3 x 5 notecards and carried them in a pouch worn around my neck that also held my airport ID. I did a quick review of the speeds for the aircraft I was assigned before each flight. 

The speed to maintain during a loss of engine power on takeoff was the big one—a knot or two could make a difference in the outcome of a situation, and I had no desire to be Junior Test Pilot in the event of an uncommanded loss of engine power, especially when I had someone sitting next to me counting on me to keep them safe.

Verbalize the Procedures

The loss of thrust or control on takeoff is part of my pre-takeoff briefing. It is concise and to the point:

If during the takeoff roll there is anything abnormal, be it an issue with controllability or engine power, we will bring the power to idle and come to a stop on the runway, then assess.

If the aircraft has lifted off and there is usable runway ahead, we will pitch for (insert speed here after verifying with checklist), land on the runway, and assess.

If the aircraft has lifted off and is out of usable runway, we will pitch for (insert speed here) and aim straight ahead or a gentle turn of no more than 30 degrees off the runway centerline aiming for someplace unpopulated, soft, and inexpensive.

Should You Turn Back?

Turning back to the runway can be a dicey situation. It is one of those scenarios I frequently practice in the ATD. If the aircraft is at least 1,000 feet agl, and the aircraft is light enough, it may be possible. It might even be doable at 800 to 700 feet. Always have an idea of where you will put it down if getting back to the runway is not an option—is there an open area of the extended centerline you could land in? An empty parking lot? Trees? A swamp? A road or street? To be clear: I am not a big fan of trying to put it down on a road or street because of power poles, cars, and street signs, however, the law of gravity cannot be denied, so do your best not to endanger anyone else.

In a Two-Pilot Situation

When flying with another pilot, the loss of thrust or controllability on takeoff briefing needs to include who will be pilot flying, because two pilots fighting over the controls is not going to help. One pilot should be pilot flying, the other should be making the radio calls if appropriate and time permits. “I will be pilot flying, you will back me up on the radio,” is the phrase to use.

Oddly, there are some CFIs that say this loss of thrust/control briefing is unnecessary and doesn’t do anything but scare the learners. I disagree—and so do the learners, like the one with the Cessna 150 who noted a lack of rpm on takeoff despite the throttle set to full power and aborted before he ran out of runway and options at the same time. Airport Mom was proud.

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DeltaHawk Adds 2 More Engines https://www.flyingmag.com/deltahawk-adds-2-more-engines/ Fri, 02 Feb 2024 17:48:13 +0000 https://www.flyingmag.com/?p=194439 The company’s family of jet-fueled piston engines is growing.

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Congratulations, it’s twins! DeltaHawk has added two new higher-horsepower models to its family of jet-fueled piston engines. According to the company, the new engines follow the same family lineage as the DHK180, which was FAA certified in May 2023 and is now heading toward production.

The new models are the DHK200 and the DHK235. Both will share the same dimensions and weight of the DHK180, which has a rated takeoff power (RTP) and maximum continuous power (MCP) of 180 horsepower.

The DHK200 will produce RTP and MCP of 200 horsepower, while the DHK235 will produce  RTP and MCP of 235 horsepower.

DeltaHawk anticipates the certification and availability of the DHK200 in the third quarter of 2024, followed by certification and availability of the DHK235 in the first half of 2025.

Company officials are hopeful the momentum created by the introduction and certification of the DHK180 will be mirrored by the DHK200 and DHK235. The DHK180 went into production last summer.

“Following FAA certification of the DHK180, customer interest and reservation deposits from aircraft OEMs and individual owners in both certified and experimental markets has been extremely high,” said Christopher Rudd, CEO of DeltaHawk Engines. “Our two new engine models build upon the same innovative, pilot-focused technology as the DHK180, while offering even more capability for higher power applications—as will additional engine models yet to be announced.”

About the Engines

DeltaHawk Engines, founded in 1996 and based in Racine, Wisconsin, designs and builds FAA-certified, jet-fueled piston engines for general aviation aircraft and hybrid-power systems.

All the DeltaHawk engines are based upon a clean-sheet design and feature an inverted-V engine block, turbocharging and supercharging, mechanical fuel injection, liquid cooling, direct drive, and, according to the company, 40 percent fewer moving parts than other engines in their category.

DeltaHawk notes the engines produce more usable torque than traditional aircraft engines in their class, all while burning significantly less fuel.

NASA recently selected the DeltaHawk DHK180 engine for its Subsonic Single Aft Engine project, known as SUSAN. Additionally, Ampaire has selected it for a hybrid proof-of-concept aircraft.

DeltaHawk is also working on a new program to develop additional variants of its engine family that will utilize hydrogen fuel in a wide variety of applications, including aviation, commercial road vehicles, and military mobility.

For more information, please visit the DeltaHawk website.

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ZeroAvia Completes $116 Million Series C to Support Hydrogen-Electric Engine Tech https://www.flyingmag.com/zeroavia-completes-116-million-series-c-to-support-hydrogen-electric-engine-tech/ Mon, 27 Nov 2023 22:02:12 +0000 https://www.flyingmag.com/?p=188974 The hydrogen-electric propulsion developer raised funds, including from the U.K. Infrastructure Bank, to support certification and scaling of its technology.

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When it comes to decarbonizing aviation, investors largely view hydrogen as a key ingredient in the quest for sustainable aviation, with some investing in companies developing fuel from hydrogen in its pure form.

ZeroAvia, a developer of hydrogen-electric propulsion systems, on Monday announced it completed a $116 million Series C funding round to support certification of its ZA600 engines and the scaling of its technology for larger aircraft.

The round was co-led by previously announced financiers Airbus, Barclays Sustainable Impact Capital, and NEOM Investment Fund, as well as the U.K. Infrastructure Bank (UKIB), which joined as a “cornerstone-level” investor. Bill Gates’ Breakthrough Energy Ventures, Amazon’s Climate Pledge Fund, Horizons Ventures, Alaska Airlines, and several others were named as participants.

“This is a great example of the bank supporting a first-of-a-kind technology that has real potential to have a telling impact on carbon emissions and help position the U.K. at the forefront of a developing green hydrogen ecosystem,” said Ian Brown, head of banking and investments at UKIB.

According to ZeroAvia, the bank’s financing will promote the company’s growth plans in the U.K., where it has been predicted that one-quarter of carbon emissions will come from aviation by 2050.

“ZeroAvia has grown rapidly in the U.K. as we have worked to deliver two major historic milestones in aerospace engineering, as we look to preserve the benefits of flight through clean propulsion,” said Val Miftakhov, founder and CEO of ZeroAvia. “This backing by such a preeminent investor as [UKIB] will help us deliver the first commercial zero-emission flights and help the U.K. realize substantial export potential.”

UKIB, meanwhile, has the opportunity to become a market leader in the country’s quest to eliminate aviation emissions by the 2050 timeframe. Founded in 2021, the bank’s mandate is to back emerging technologies and crowd in private investment while driving regional growth and taking on climate change. It said a successful rollout of hydrogen engines in aviation could catalyze the development of wider hydrogen infrastructure.

“Aviation and hydrogen are sectors that need significant private investment to get to net zero,” said Brown. “By providing confidence to investors, our equity has helped to crowd in the private investment needed for the continued development of this cutting-edge technology and should help stimulate the development and deployment of hydrogen technology across other hard-to-decarbonise sectors.”

ZeroAvia’s latest funding comes three years after a series A investment led by Breakthrough Energy, the Climate Pledge Fund, and other participants in November’s round netted it $21.4 million. It followed that up last year with a Series B from Barclays, Neom, International Airlines Group, and American Airlines, bringing its total raised to $150 million.

The company is starting small: Its ZA600 engine, a 600-kilowatt, hybrid-electric powertrain, will be retrofitted on regional turboprops with nine to 19 seats and a range of 300 sm (260 nm) by the end of 2025. Two years later, the ZA2000, a 2-5 megawatt model, is expected to support aircraft with 40 to 80 seats and a 700 sm (608 nm) range.

So far, ZeroAvia has secured experimental certificates to test its engines with the FAA and the U.K.’s Civil Aviation Authority (CAA) using three separate testbed aircraft.

The company has already hit several flight test milestones, most notably using a Dornier 228 equipped with one ZA600 engine and one conventional stock engine. Since completing its maiden voyage in January, the aircraft has gone through a range of tests, including flying at 5,000 feet, weathering a 23-minute endurance test, and operating in just-above-freezing temperatures.

ZeroAvia says it has a number of engineering partnerships with key aircraft OEMs, such as Cessna, Beechcraft, and de Havilland Canada. It claims to have nearly 2,000 preorders from major global airlines, including United Airlines, which in 2021 signed on as an investor and agreed to purchase up to 100 engines.

Simultaneously, the manufacturer is working on several projects. The most recent is a collaboration with Airbus to explore certification for hydrogen-powered systems. The partners also intend to examine liquid hydrogen fuel storage, fuel cell propulsion testing, and the development of hydrogen refueling infrastructure.

Another venture involves Textron, with which ZeroAvia will collaborate to install the ZA600 on a Cessna Grand Caravan turboprop. The company is also working with European airport operator AGS Airports to develop hydrogen fuel infrastructure and zero-emission routes, while a partnership with autonomous cargo aircraft developer Natilus will see it add its engines to the company’s Kona model.

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DeltaHawk High on Testing of Hydrogen Engine https://www.flyingmag.com/deltahawk-high-on-testing-of-hydrogen-engine/ Fri, 17 Nov 2023 22:18:10 +0000 https://www.flyingmag.com/?p=188364 Variants of DeltaHawk’s FAA-certified piston engine for GA aircraft are being developed for use in hydrogen-powered aviation, commercial road vehicles, and military mobility applications.

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DeltaHawk Engines, the Wisconsin-based builder of an FAA-certified, jet-fueled piston engine for GA aircraft, is encouraged by preliminary testing of its new hydrogen-fueled variant using simulations and computer-based trials.

According to the company, the test results indicate the new engine will have applications in  multiple markets in addition to aviation, such as commercial power applications, defense platforms, and zero-emission vehicles.

“Environmental responsibility is a foundational pillar of our company” said Christopher Ruud, CEO of DeltaHawk. “In the general aviation industry, our family of engines are creating a highly reduced net-carbon footprint coupled with airborne lead removal, thanks in large part to their fuel efficiency and capability to burn next-generation sustainable aviation fuels [SAFs]. Now with our planned ability to expand our engine family to include variants that will utilize hydrogen fuel in aviation, commercial, and military applications, we’ve taken another major step toward environmental sustainability, climate neutrality, and a zero-emissions future.”

About the Company

Since its founding in 1996, DeltaHawk said it has been striving to create a cleaner, more efficient, engine for the GA market. The company holds numerous patents for its clean-sheet engine designs.

According to the company, the use of proven internal combustion engine (ICE) technology with hydrogen fuel replaces more expensive, highly infrastructure-reliant fuel cell systems. That allows for a significantly reduced power degradation curve over time compared to current fuel cell technology, providing better fuel economy than fuel cells after the initial period.

DeltaHawk said its compact, lightweight, and durable design, based on patented two-stroke technology, makes this new engine family an ideal solution for hydrogen fuel. 

More information on the company website is available here.

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EAGLE Initiative Shows Measured Progress, Fuel Contenders Say at Oshkosh https://www.flyingmag.com/eagle-initiative-shows-measured-progress-fuel-contenders-say-at-oshkosh/ Wed, 26 Jul 2023 15:11:34 +0000 https://www.flyingmag.com/?p=176586 With four candidate fuels pursuing fleet authorization, OEMs, distributors, and airports are ready to test them.

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The EAGLE Initiative moves forward at a measured pace, according to a panel of constituents that presented an update at the Theater in the Woods on Monday at EAA AirVenture at Oshkosh. 

EAGLE—which stands for Eliminate Aviation Gas Lead Emissions—includes partners from aviation industry associations, the FAA, fuel producers and distributors, airport operators, and local community and environmental experts. With the aim to transition away from leaded avgas—100LL—by 2030, EAGLE has the twin missions of supporting development of replacement fuels and advocating for the continued supply of current fuels until the OEMs, operators, and pilots feel secure in the safety and security of the new fuel source(s).

It’s a tall order. Though four entities reported significant progress with their specific candidate fuel, there are varying degrees of confidence in both the composition and distribution prospects of each one.

The EPA’s Next Step Lies Ahead

And time is of the essence—though it’s not prudent to panic yet, according to leaders like Chris D’Acosta, founder and CEO of Swift Fuels, which is currently working on one candidate fuel. What would trigger that response? The Environmental Protection Agency announced its proposed endangerment finding on leaded avgas last October, and it stands to finalize that this October, on schedule.

What does that mean? It doesn’t mean that leaded avgas will be banned immediately. At the briefing, General Aviation Manufacturers Association (GAMA) president and CEO Pete Bunce outlined the steps that would follow the finding. “The people that have to implement the rules are [at] the FAA,” said Bunce of the next steps following the endangerment finding. “There’s a very structured process.” He estimated that there would be about two or three years to completely field the transition fuel. That’s part of the reasoning behind the 2030 goal EAGLE set, to work through this “very methodical process.”

“We have smart people working in these four companies, and we’re going to have a solution,” said Bunce.

Four Fuels

Representatives from each of the companies or partnerships working on those fuels presented their progress, starting with D’Acosta. 

Swift Fuels

Eight years ago, Swift Fuels began delivering the first batches of its UL94 unleaded avgas, and it can now be found in roughly 81 locations across the U.S. The current fuel serves as a drop-in replacement for 130,000 aircraft on the registry—for which FLYING awarded Swift its 2023 Innovation Award. The success of UL94 sets the stage for its higher octane 100R fuel that will serve the remainder of the GA fleet. Swift followed a dual certification program with UL94, acquiring ASTM acceptance as well as supplemental type certificate approval from the FAA. It is pursuing the same path with 100R.

Swift offers a “forever STC” that covers the UL94 as well as future fuels, along with all of the placarding and any changes in documentation. The underlying goal is to establish a sense of security among those who will put the fuel into their tanks—both at the airport and on the airplane. “The emotional uncertainty at this time is really counterproductive to everybody’s interests,” said D’Acosta.

GAMI

George Braly of General Aviation Modifications Inc. presented next, reporting on the nearly 14 years since GAMI began development on its unleaded avgas replacement—and culminating with the issuance of its blanket STC for all aircraft powered by spark-ignition engines in September 2022. “GAMI has fixed the problem,” said Braly, summarizing what had been the general feeling at the time of the STC’s debut. GAMI is working with OEMs like Robinson (for rotorcraft implementation) and Cirrus in its SR22T, considered one of the most complex powerplant installations to accept the new fuel. 

While the STC has been available for nearly a year, GAMI is still struggling to supply the fuel to the market. To this end, Braly announced it had partnered with “an extremely large producer of aviation jet fuel,” VTOL, to produce the G100UL in quantity. That Houston-based company has finished its 4 million-gallon tank toward making that happen.

LyondellBassell and VP Racing

Two of the fuel developers are pursuing approvals through the Piston Aviation Fuels Initiative (PAFI), established by Congress to achieve fleet authorization through a collaborative industry-government process. LyondellBassell/VP Racing is the first of these. VP Racing is a Texas-based developer of fuels and additives for the automotive racing industry, and LyondellBassell produces high-octane lead components for automobiles. In his remarks at the briefing, Dan Perot of LyondellBassell admitted the partnership was “relative latecomers to this race,” as it started in 2018 to develop its answer to the high-octane avgas question.

“We chose to stay with the PAFI program despite delays during the COVID period,” said Perot, “because we felt that it provided the best mechanism for us to learn what the industry needed, communicate with the FAA and OEMs, and secondly, and maybe most importantly, it required ASTM certification for the fuel.” 

According to Mark Walls of VP Racing, the partnership’s fuel meets all D910 specs, is of the same density as 100LL, and is poised to be cost-competitive. The company is about to enter “full-scale” testing after preliminary work in Lycoming and other engines. Like other fuels in development, Walls said its avgas is fully compatible with 100LL in case of mixing in aircraft tanks.

Afton Chemical and Phillips 66

The second partnership pursuing PAFI-based authorization is between Afton Chemical, headquartered in Richmond, Virginia, and Phillips 66. The pair are also working on new lubricants to accompany the high-octane unleaded fuels. Enrico Lodrigueza with Phillips 66 updated on its progress, detailing the candidate fuel, which uses manganese—a coenzyme used in the human body to break down carbohydrates and proteins, a transition metal—to replace the tetraethyl lead in 100LL. The fuel has an ASTM specification in place, ASTM 28434, according to Lodrigueza, which is “substantially similar” to the D910 spec for 100LL.

Lodrigueza characterized the manganese-based octane booster in use. “Manganese is not a heavy metal. That’s one major difference…it’s an essential nutrient.” As far as testing, the partnership has had “a lot of vetting” by subject matter experts and is ready to proceed with detonation testing at the Tech Center on a Lycoming engine. As with all of the potential replacement additives, close scrutiny is being placed on what issues may occur with the new element in the fuel, such as spark plug fouling. The lubricants testing will also ensure compatibility with whatever oil is in use, for example.

What’s Next?

Clearly, the four candidate fuels are in different states of availability for testing—some more broadly than others—and both the engine and airframe OEMs are eager to keep going. Bunce summarized the position of the manufacturers. “We have the money, our manufacturers have the money to purchase it, to be able to go and look at that fuel and understand what chemical components are in relation to the spec to be able to run it and to do the type of testing that we feel comfortable that we can put our families into that aircraft employing that fuel. And if we see good or bad, we will share it, as manufacturers, to the FAA., That’s our obligation—but that’s the right thing to do.”

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Boom Aerospace Delivers Update on Supersonic Model https://www.flyingmag.com/boom-aerospace-delivers-update-on-supersonic-model/ Tue, 20 Jun 2023 12:52:32 +0000 https://www.flyingmag.com/?p=174124 The company announced new suppliers, and building the company’s ‘iron bird’ facility has begun in Colorado.

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Boom Supersonic’s collection of tier 1 suppliers now counts Leonardo, Aernnova, and Aciturri among the roster of global companies on board to develop and execute on the supersonic vision reiterated by Boom founder and CEO Blake Scholl. 

The announcement was made on Tuesday at the Paris Air Show, along with several updates on the airframe and engine development as well as manufacturing and testing plans. The final product—the Overture—is projected to fly at Mach 1.75 in overwater cruise powered by bespoke Symphony engines running on 100 percent sustainable aviation fuel.

Mainline Suppliers

Leonardo, based in Rome, will provide its expertise in composite structure development and manufacturing as engineering lead for the Overture’s fuselage structural components integration, and serve as a design and build partner for fuselage sections—including the wingbox. The cross section of the Overture has a larger diameter at its fore section growing smaller towards the rear of the airplane. The design is intended to “minimize wave-drag and maximize fuel efficiency at supersonic speeds,” according to a statement from the company.

Aernnova, in Madrid, a large tier-one aerospace supplier, has been chosen to design and develop the Overture’s gull-shaped wings, which are structurally thinner than typical subsonic wings. Their nature is intended to reduce drag and increase efficiency at high speeds.

Aciturri, based in Miranda de Ebro, Spain, and another major tier 1 supplier, has been selected to provide the empennage to the Overture. A horizontal stabilizer that allows for greater control at subsonic speeds, including takeoff landing, is a key element to the tail design.

Symphony Engine Milestones

Florida Turbine Technologies (FTT) of Doral is the main partner on Boom’s proprietary engine, named the Symphony, and it continues to move forward in the two-spool, medium-bypass turbofan’s development. Scholl gave details on the powerplant’s specs along with teasing photos of the cross section that include the aforementioned optimization to run on 100 percent SAF. “Symphony features a high-specific-flow fan,” said Scholl, “which allows us to reduce the frontal area of the engine, which reduces supersonic drag.” Other details include:

  • 35,000-pound thrust
  • single-stage 72-inch fan
  • air-cooled, multi-stage turbine
  • FAA Part 33 and EASA CS 33 compliant
  • adherence to ICAO Chapter 14 noise levels

Use of additive manufacturing will enable lightweight composition, low parts count, and reduced assembly costs. The engine features three low-pressure compressor stages, six high-pressure compressor stages, three low-pressure turbine stages, and a single high-pressure turbine stage. Former Rolls-Royce CTO and Singapore Aerospace programme chair Ric Parker serves as lead on the engine program, which has been under the magnifying glass when it moved away from former engine partner Rolls-Royce and went with a trio of new collaborators: FTT, GE Additive, and Standard Aero. Scholl spoke to this tangentially, stating that the need for a bespoke engine “specifically optimized for sustained supersonic flight and sustainable supersonic portions of that.” The vertical integration strategy is key to achieving this.

Manufacturing of the engines at scale will take place at FTT’s facility in Jupiter, Florida, Scholl revealed at the press conference. He also updated on progress of the company’s “iron bird” testing facility at its headquarters on the Centennial Airport (KAPA) on the south side of the Denver metro area in Colorado. 

“This is the integrated test facility, where we will be able to put all of the systems hardware through exhaustive testing, with software and hardware in the loop, with thousands of simulated first flights before Overture makes its maiden voyage,” said Scholl. Flight controls, electrical power, and landing gear will all be operable in the iron bird facility.

Fuel System as CG Control

One of the unique aspects of the Overture includes systems architecture updated upon during the press conference by Scholl. While avionics, flight controls, hydraulics, and gear systems were touched upon—and will meet FAA and EASA Part 25 regs—he offered a bit of insight on the fuel system, which will be used to provide center of gravity (CG) control during both sub- and supersonic operations.

The all-composite makeup of Overture enables the use of complex aerostructures to create the contoured fuselage and gull-wing planform. Overall, the use of already certified technologies have been chosen thus far to reduce the risk on the program, as it breaks ground in significant ways in commercial passenger service.

The program remains on track in its 10-year development cycle—where it stands 3.5 years in—for a planned type certification in 2029.

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DeltaHawk Gains Type Certification on Jet-Fueled Piston Powerplant https://www.flyingmag.com/deltahawk-gains-type-certification-on-jet-fueled-piston-powerplant/ https://www.flyingmag.com/deltahawk-gains-type-certification-on-jet-fueled-piston-powerplant/#comments Thu, 18 May 2023 21:04:09 +0000 https://www.flyingmag.com/?p=172252 The ‘upside down’ DHK180 has been in development for more than two decades.

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It’s been more than a decade in the making, but now the “upside down” DeltaHawk engine has arrived. The company announced Thursday that its DeltaHawk DHK180 piston powerplant—set to run on jet-A—has gained FAA type certification after a significant period of development.

The liquid-cooled,180 hp, 4-cylinder diesel engine uses an inverted “V” configuration and mechanical fuel injection, along with a slimmer design expected to fit more efficiently into modern aircraft cowling. It’s turbocharged and supercharged, direct drive, and has been assembled with 40 percent fewer parts than other engines in its class.

“We began by completely reimagining what a general aviation engine should be,” said Christopher Ruud, DeltaHawk’s CEO. “And the result is that we now have a certified engine that is a game-changer. It’s been a long time coming but, in engineering, simple is hard. However, this engine’s performance, simplicity, and reliability have made it worth the time and the investment, as it is truly ‘power reimagined.’”

A Long Road to TC

It’s not easy or cheap to bring a new powerplant into the GA market, and the DeltaHawk story proves this to be true once again. Few new designs have surfaced in the past 60 years.

The DHK180 stems from the DH180 originally on display at EAA AirVenture 2014 on a Cirrus SR20. After the Ruud family took controlling ownership in 2016, the path toward certification became clearer: The 180 hp variant showed up at Oshkosh in 2019, also on the SR20, and at that time DeltaHawk expected certification by the end of that year. With a little delay—and pandemic induced slowdowns—the engine has now acquired the TC it needs to move into the production phase.

Good things come to those who persevere, however. According to the company, it has had interest from potential suitors from kit builders to the military—even from NASA to power its Subsonic Single Aft Engine Aircraft (SUSAN) scale flight test vehicle.

DeltaHawk expects to deliver the first of its production DHK180s in 2024.

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