NASA to Start Designing More Sustainable Jet Engine Core

NASA to Start Designing More Sustainable Jet Engine Core

4 min read

Preparations for Next Moonwalk Simulations Underway (and Underwater)

Graphic shows a possible future General Electric jet engine with exposed fan blades in front of a cut-away-interior view of its core mechanisms -- all part of NASA's HyTEC research project.
This artist concept shows a NASA-developed small-core jet engine installed in General Electric Aerospace’s CFM RISE jet engine design. The more fuel-efficient small core powers a large open turbofan, which also helps increase efficiency. The effort is part of NASA’s Sustainable Flight National Partnership to help inform the next generation of ultra-efficient airliners.
GE Aerospace

NASA, alongside industry, will soon begin designing a new jet engine concept for the next generation of ultra-efficient airliners — officially graduating to the project’s next phase.

As part of NASA’s goal to make the aviation industry more sustainable, the agency is developing a small core for a hybrid-electric turbofan jet engine that could reduce fuel burn by 10% compared to today’s engines.

A jet engine’s core is where compressed air is combined with fuel and ignited to generate power. By making this core smaller, fuel efficiency can be improved and carbon emissions reduced.

The goal of the project, named Hybrid Thermally Efficient Core (HyTEC), is to demonstrate this compact core and have the technology ready for adoption in engines powering next-generation aircraft in the 2030s. HyTEC is a key component of NASA’s Sustainable Flight National Partnership.

To achieve its ambitious goal, HyTEC is structured in two phases:

  • Phase 1, which is wrapping up, focused on selecting the component technologies to use in the core demonstrator.
  • Phase 2, starting now, will see researchers design, build, and test a compact core in collaboration with GE Aerospace.

“Phase 1 of HyTEC is winding down and we are ramping up Phase 2,” said Anthony Nerone, who leads HyTEC at NASA’s Glenn Research Center in Cleveland. “This phase will culminate in a core demonstration test that proves the technology so it can transition to industry.”

The End of the Beginning

Before researchers could start the design and build process for the core, they had to explore innovative new materials to use in the engine. After three years of notably fast progress, HyTEC researchers came up with solutions.

“We’ve been laser-focused since day one. We began the project with certain technical goals and metrics for success and, so far, we haven’t had to change course from any of them,” Nerone said.

To shrink the size of a core while maintaining the same level of thrust, heat and pressure must increase compared to standard jet engines used today. This means the engine core must be made of more durable materials that can withstand higher temperatures.

In addition to conducting materials research, the project also explored advanced aerodynamics and other key technical elements.

Cross section of a typical turbofan jet engine showing the combustor in teal, the high-pressure turbine in blue and the high-pressure compressor in yellow.
Cross section of a typical turbofan jet engine highlights parts of the core HyTEC will work to advance. These include the high-pressure compressor, combustor, high pressure turbine, and power extraction components.
NASA

What Comes Next

Phase 2 builds on Phase 1 to create a compact core for ground testing that proves HyTEC’s capabilities.

“Phase 2 is very complex. It’s not just a core demonstration,” Nerone said. “What we’re creating has never been done before, and it involves many different technologies coming together to form a new type of engine.”

Technologies tested in the HyTEC program will help enable a much higher bypass ratio, hybridization, and compatibility with sustainable aviation fuels.

The bypass ratio describes the relationship between the amount of air flowing through the engine core compared to the amount of air bypassing the core to flow around it.

By decreasing the core size while increasing the size of the turbofan it powers – while maintaining the same thrust output — the HyTEC concept would use less fuel and reduce carbon emissions.

“HyTEC is an integral part of our RISE program,” said Kathleen Mondino, who helps lead RISE program technologies at GE Aerospace. “GE Aerospace and NASA have a long history of collaboration to advance the latest aviation technologies. The HyTEC program builds on this relationship to help chart the future of more sustainable flight.”

Another piece of the puzzle is hybridization. HyTEC’s hybrid-electric capability means the core will also be augmented by electrical power to further reduce fuel use and carbon emissions.

“This engine will be the first mild hybrid-electric engine, and hopefully, the first production engine for airliners that is hybrid-electric,” Nerone said.

About the Author

John Gould

John Gould

Aeronautics Research Mission Directorate

John Gould is a member of NASA Aeronautics’ Strategic Communications team at NASA Headquarters in Washington, DC. He is dedicated to public service and NASA’s leading role in scientific exploration. Prior to working for NASA Aeronautics, he was a spaceflight historian and writer, having a lifelong passion for space and aviation.

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Robotics, Health Research, and Cleaning to End Week

Robotics, Health Research, and Cleaning to End Week

 

One of the International Space Station's free-flying robots, Astrobee.
One of the International Space Station’s free-flying robots, Astrobee.

Expedition 71 wrapped up a week of maintenance and health investigations aboard the International Space Station on Friday. The septet worked robotics, two human health studies, and finished some cleaning in the cupola.

NASA Flight Engineer Jeanette Epps started her day in the Japanese Experiment Module to power on Astrobee, the station’s free-flying robots, to later rehearse the device’s flight and tech operations for an upcoming Kibo Robot Programming Challenge. The challenge is an educational program designed for students to solve various given problems by using the free-flying robots, moving and controlling them remotely.

Afterward, Epps removed yesterday’s Immunity Assay samples from Kubik, then incubated them in the Human Research Facility’s centrifuge. The device is designed to separate biological substances from the samples by spinning at high rates in microgravity. Once completed, Epps stowed the samples in MELFI, an ultra-cold freezer, to preserve them for future analysis on Earth.

As part of the CIPHER study, NASA Flight Engineer Mike Barratt set up tomography hardware in the morning and later received an eye examine. In microgravity, body fluids shift toward a crew member’s head, which can cause one of the most visible symptoms of living in space, known as “puffy face.” As fluids shift upward, this can alter the structure and function of the eyes and brain. Astronauts routinely perform eye examines aboard the orbiting complex to help scientist on Earth study these changes.

Barratt then moved onto some spacesuit work, manually removing gasses from the Contingency Water Containers, then filling the water tanks in preparation for a round of spacewalks this summer.

Astronauts often use the station’s cupola to capture photos of Earth or complete robotics activities, among other tasks. NASA Flight Engineers Matthew Dominick and Tracy C. Dyson spent the morning in the “window to the world” to remove and replace some acrylic scratch panes on a few of the windows, work that began earlier in the week, then cleaned the primary pressure panes.

In the Roscosmos segment, Flight Engineer Nikolai Chub and current station Commander Oleg Kononenko spent the day replacing a belt on one of the treadmills. Meanwhile, their crewmate, Alexander Grebenkin, completed some robotic arm simulation training.

NASA, Boeing, and ULA (United Launch Alliance) teams will take additional time to work through spacecraft closeout processes and flight rationale before proceeding with the launch of the agency’s Boeing Crew Flight Test. The teams now are targeting a launch no earlier than 3:09 p.m. EDT Saturday, May 25, for the flight test carrying NASA astronauts Butch Wilmore and Suni Williams to the International Space Station.

The additional time allows teams to further assess a small helium leak in the Boeing Starliner spacecraft’s service module traced to a flange on a single reaction control system thruster. Pressure testing performed on May 15 on the spacecraft’s helium system showed the leak in the flange is stable and would not pose a risk at that level during the flight. The testing also indicated the rest of the thruster system is sealed effectively across the entire service module. Boeing teams are working to develop operational procedures to ensure the system retains sufficient performance capability and appropriate redundancy during the flight. As that work proceeds, NASA’s Commercial Crew Program and the International Space Station Program will take the next few days to review the data and procedures to make a final determination before proceeding to flight countdown.

The ULA Atlas V rocket and Boeing’s Starliner remain in the Vertical Integration Facility at Space Launch Complex-41 on Cape Canaveral Space Force Station in Florida. The NASA, Boeing, and ULA teams remain committed to ensuring a safe Starliner flight test.

Wilmore and Williams will remain quarantined in Houston as prelaunch operations progress. They will fly back to NASA’s Kennedy Space Center in Florida closer to the new launch date. The duo is the first to launch aboard Starliner to the space station as part of the agency’s Commercial Crew Program. The astronauts will spend about a week at the orbiting laboratory before returning to Earth and making a parachute and airbag-assisted landing in the southwestern United States.

After successful completion of the mission, NASA will begin the final process of certifying Starliner and its systems for crewed rotation missions to the space station.


Learn more about station activities by following the space station blog, @space_station and @ISS_Research on X, as well as the ISS Facebook and ISS Instagram accounts.

Get weekly updates from NASA Johnson Space Center at: https://roundupreads.jsc.nasa.gov/

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Abby Graf

NASA, Boeing Now Working Toward May 25 Launch of Crew Flight Test

NASA, Boeing Now Working Toward May 25 Launch of Crew Flight Test

A United Launch Alliance Atlas V rocket with Boeing’s Starliner spacecraft aboard is seen on the launch pad illuminated by spotlights at Space Launch Complex 41 on Sunday, May 5, 2024. Photo Credit: NASA/Joel Kowsky

NASA, Boeing, and ULA (United Launch Alliance) teams will take additional time to work through spacecraft closeout processes and flight rationale before proceeding with the launch of the agency’s Boeing Crew Flight Test. The teams now are targeting a launch no earlier than 3:09 p.m. EDT Saturday, May 25, for the flight test carrying NASA astronauts Butch Wilmore and Suni Williams to the International Space Station.

The additional time allows teams to further assess a small helium leak in the Boeing Starliner spacecraft’s service module traced to a flange on a single reaction control system thruster. Pressure testing performed on May 15 on the spacecraft’s helium system showed the leak in the flange is stable and would not pose a risk at that level during the flight. The testing also indicated the rest of the thruster system is sealed effectively across the entire service module. Boeing teams are working to develop operational procedures to ensure the system retains sufficient performance capability and appropriate redundancy during the flight. As that work proceeds, NASA’s Commercial Crew Program and the International Space Station Program will take the next few days to review the data and procedures to make a final determination before proceeding to flight countdown.

The ULA Atlas V rocket and Boeing’s Starliner remain in the Vertical Integration Facility at Space Launch Complex-41 on Cape Canaveral Space Force Station in Florida. The NASA, Boeing, and ULA teams remain committed to ensuring a safe Starliner flight test.

Wilmore and Williams will remain quarantined in Houston as prelaunch operations progress. They will fly back to NASA’s Kennedy Space Center in Florida closer to the new launch date. The duo is the first to launch aboard Starliner to the space station as part of the agency’s Commercial Crew Program. The astronauts will spend about a week at the orbiting laboratory before returning to Earth and making a parachute and airbag-assisted landing in the southwestern United States.

After successful completion of the mission, NASA will begin the final process of certifying Starliner and its systems for crewed rotation missions to the space station.

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Danielle Sempsrott

NASA Around the World: Interns Teach Virtual Lessons in Kenya

NASA Around the World: Interns Teach Virtual Lessons in Kenya

2 min read

Preparations for Next Moonwalk Simulations Underway (and Underwater)

Video Credit: NASA/Dennis Brown, TechLit Africa

When it comes to inspiring the next generation, NASA interns know no bounds. Interns at NASA’s Glenn Research Center in Cleveland taught students 7,600 miles away in Mogotio, Kenya, but thanks to technology, they didn’t travel a single mile.

Collaborating with TechLit Africa — a non-profit organization that teaches digital skills in Kenyan rural primary schools — interns shared virtual lessons on robot simulation, artificial intelligence, and drawing and modeling applications.

Nelly Cheboi concentrates while testing a virtual reality demonstration. She wears a virtual reality headset and a red and white dress. Her hands appear as if she is pressing buttons on an invisible tablet.
Nelly Cheboi, TechLit Africa CEO and founder, enjoys a virtual reality demonstration in NASA Glenn’s GVIS Laboratory.
Credit: NASA/Jef Janis

“It was an absolute privilege to help these kids and being a part of it,” said Marc Frances, extended reality developer and former NASA Glenn intern. “We do a lot of outreach events and try to influence kids from every part of life to become an engineer and be part of something that’s bigger than themselves.”

Kenyan students surround a computer laptop. They are smiling and laughing at the screen.
Students learn digital skills in rural primary schools in Mogotio, Kenya.
Credit: TechLit Africa

The opportunity arose after Herb Schilling, a Glenn computer scientist, met Nelly Cheboi, TechLit Africa CEO and founder, through a virtual event in 2020. The two began talking about Cheboi’s work with Kenyan students, and Schilling felt inspired to get involved.

“I haven’t done a lot of the teaching,” Schilling said. “I let the interns do it, because I want to give them the experience and encourage them to do these kinds of things too.”

Nelly Cheboi enjoys a virtual reality demonstration. She smiles as she wears a VR headset and holds a remote controller. She is wearing a red and white dress. Herb Schilling, computer scientist, smiles as he watches her.
Nelly Cheboi tests a virtual reality demonstration in NASA Glenn’s GVIS Laboratory.
Credit: NASA/Jef Janis

Using a beginner-level coding application, the interns showed Cheboi’s students how to design and animate a rocket that would launch into space. After several virtual lessons, Cheboi, CNN’s 2022 Hero of the Year, and her partner, Tyler Cinnamon, visited Glenn to learn more about NASA and meet Schilling in person.

“I think it has really helped shape our curriculum, Cheboi said. “For these kids to look at this experience as something normal to them really speaks volumes of the impact. It matters what environment you grow up into, and you really can only be it if you see it.”  

Learn more about how to engage with NASA on the NASA Engages web page.

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Kelly M. Matter

Sols 4186-4188: Almost there…

Sols 4186-4188: Almost there…

3 min read

Sols 4186-4188: Almost there…

Mars Hand Lens Imager (MAHLI)
NASA’s Mars rover Curiosity acquired this image using its Mars Hand Lens Imager (MAHLI), located on the turret at the end of the rover’s robotic arm, on May 14, 2024, Sol 4184 of the Mars Science Laboratory Mission, at 06:58:35 UTC.
NASA/JPL-Caltech/MSSS

Earth planning day: Wednesday, May 15, 2024

The rover planning engineers yet again did a great job navigating through the large bedrock blocks that litter the terrain in front of us. We are getting ever closer to being able to cross the Gediz Vallis channel and associated deposits, a feature we identified long before landing and of high scientific interest. As a member of the group responsible for planning the observations we hope to get on the Gediz Vallis deposits and associated landforms (called the Channel Surfers), I am very excited to finally be at this point in the mission. To help decide where to drive onto the deposit, we are driving a little closer to the edge and taking extra post-drive imaging to aid in that decision. We are also acquiring a large Mastcam mosaic of an area of the deposit we hope to study in more detail, “Arc Pass.”

Before we drive, we will of course acquire lots of science observations from our current location. The workspace in front of the rover contained an interesting textured block that immediately drew all our attention – a polygonally patterned erosional feature (“Tuolumne Meadows”) that we were able to place the rover’s arm on for contact science. We will also be able to brush it and clear the dust before analyzing with APXS for chemistry and MAHLI for the fine-scale texture. ChemCam will also analyze the same spot, as well as the front face of the same block (“Wapama Falls”), which will also be documented by Mastcam. To compare with this block, we are also planning APXS and MAHLI on a separate, more typical looking bedrock block, “Parker Lakes.”

Looking a little further afield, the views continue to be stunning as we climb Mount Sharp, and so of course we wanted to document features of interest. The Yardang unit, high above us on Mount Sharp, is about to disappear from view, so we planned a ChemCam RMI mosaic to capture structures and textures. A little closer to the rover, we will also image another area of the “Pinnacle Ridge” section of the Gediz Vallis deposit to continue documenting the textures and structures associated with this relatively young feature in Gale crater. 

The team also planned a series of observations to monitor environmental and atmospheric conditions. These included Navcam dust devil and suprahorizon movies, a line of sight scan and deck monitoring. Standard DAN and RAD round out this jam-packed plan.

As the APXS strategic planner this week, and as a Channel Surfer, I am excited for the downlink from this plan, and for the upcoming investigations of the Gediz Vallis deposit. To whet our appetite, we got down the results of APXS and MAHLI observations from the previous plan on an interesting textured, included block from the deposit. See the image associated with this post to marvel at the “Tenaya Lake” rock.

Written by Lucy Thompson, Planetary Geologist at University of New Brunswick

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Last Updated
May 17, 2024

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