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By NASA
The powerhouse of Gateway, NASA’s orbiting outpost around the Moon and a critical piece of infrastructure for Artemis, is in the midst of several electric propulsion system tests.
The Power and Propulsion Element (PPE), being manufactured by Maxar Technologies, provides Gateway with power, high-rate communications, and propulsion for maneuvers around the Moon and to transit between different orbits. The PPE will be combined with the Habitation and Logistic Outpost (HALO) before the integrated spacecraft’s launch, targeted for late 2024 aboard a SpaceX Falcon Heavy. Together, these elements will serve as the hub for early Gateway crewed operations and various science and technology demonstrations as the full Gateway station is assembled around it in the coming years.
In this image, PPE engineers successfully tested the integration of Aerojet Rocketdyne’s thruster with Maxar’s power procession unit and Xenon Flow Controller.
Image Credit: NASA
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By NASA
2 min read
Preparations for Next Moonwalk Simulations Underway (and Underwater)
An automated fiber placement machine on an industrial robot is seen at Fives Machining Systems Inc. Fives is one of the new partners joining a NASA project that explores ways to speed up the production of composite aircraft.Fives Machining Systems Inc. Gulfstream Aerospace Corporation and Fives Machining Systems Inc. have joined 20 other organizations to support NASA’s Hi-Rate Composite Aircraft Manufacturing (HiCAM) project.
The project is addressing industry’s needs to meet growing demand for air travel, replace aging airliners, and secure U.S. competitiveness in the commercial aircraft industry.
NASA and its partners are collaborating and sharing costs to increase the manufacturing rate for aircraft components made from composite (nonmetallic) materials. Gulfstream and Fives are the newest members in a public-private partnership called the Advanced Composites Consortium.
Advanced Composites Consortium
Members of the Consortium have significant and unique expertise in aircraft design, manufacturing, certification, testing, and tool development, with the new members bringing important new insights and capabilities to the team.
“By partnering with U.S. industry, academia, and regulators, we’ll increase the likelihood of impacting the next generation of transports,” said Richard Young, manager for NASA’s HiCAM project, which oversees the consortium.
The team is currently competing concepts to determine which technologies will have the greatest impact on manufacturing rates. Once the most promising concepts are selected, they’ll be demonstrated at full scale.
The project and Advanced Composites Consortium contribute to NASA’s Sustainable Flight National Partnership by enabling broader use of lightweight composite airframes, which will reduce fuel consumption and carbon emissions, improving air quality and the environment.
HiCAM is managed under NASA’s Advanced Air Vehicles Program.
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Last Updated Aug 22, 2024 EditorJim BankeContactRobert Margettarobert.j.margetta@nasa.gov Related Terms
Aeronautics Advanced Air Vehicles Program Aeronautics Research Mission Directorate Green Aviation Tech Hi-Rate Composite Aircraft Manufacturing Sustainable Flight National Partnership View the full article
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By NASA
Teams with NASA’s Exploration Ground Systems Program, in preparation for the agency’s Artemis II crewed mission to the Moon, conduct testing of four emergency egress baskets on the mobile launcher at Launch Complex 39B at the agency’s Kennedy Space Center in Florida in July 2024. The baskets are used in the case of a pad abort emergency to allow astronauts and other pad personnel to escape quickly from the mobile launcher to the base of the pad to be driven to safety by emergency transport vehicles.NASA/Amanda Arrieta Since NASA began sending astronauts to space, the agency has relied on emergency systems for personnel to safely leave the launch pad and escape the hazard in the unlikely event of an emergency during the launch countdown.
During the Mercury and Gemini programs, NASA used launch escape systems on spacecraft for the crew to safely evacuate if needed. Though these systems are still in use for spacecraft today, the emergency routes on the ground were updated starting with the Apollo missions to account for not only the crew, but all remaining personnel at the launch pad.
During Apollo, personnel relied on a ground-based emergency egress system – or emergency exit route – to allow for a quick and safe departure. Though the system has varied over time and different launch pads use different escape systems, the overall goal has stayed the same – quickly leave the launch pad and head to safety.
Beginning with Artemis II, the Exploration Ground Systems (EGS) Program at Kennedy Space Center in Florida, will use a track cable which connects the mobile launcher to the perimeter area of the launch pad where four baskets, similar to gondolas at ski lifts, can ride down. Once down at the ground level, armored emergency response vehicles are stationed to take personnel safely away from the launch pad to one of the triage site locations at Kennedy.
“We have four baskets that sit on the side of the mobile launcher tower at the same level as the crew access arm, the location where the crew enters the spacecraft,” said Amanda Arrieta, mobile launcher 1 senior element engineer for NASA’s EGS Program. “The intention is to provide another means of egress for the crew and the closeout crew in the event of an emergency. Each of these baskets will go down a wire. It’s a wire rope system that connects to the pad terminus, an area near the pad perimeter where the baskets will land after leaving the mobile launcher tower.”
Infographic shows the route astronauts and personnel would take during an emergency abort situation. Credit: NASA The Artemis system works like this: personnel will exit the Orion spacecraft or the white room (depending where teams are at the time of the emergency) inside the crew access arm of the mobile launcher. Located on the 274-foot-level, teams are approximately 375 feet above the ground. From there, they will head down the 1,335-foot-long cables inside the emergency egress baskets to the launch pad perimeter, or the pad terminus area. Each basket, which is similar in size to a small SUV, is designed to carry up to five people or a maximum weight of 1,500 pounds.
Once teams have left the terminus area and arrive at the triage site location, emergency response crews are there to evaluate and take care of any personnel.
“When we send our crews to the pad during launch, their safety is always at the forefront of our minds. While it is very unlikely that we will need the emergency egress and pad abort systems, they are built and tested to ensure that if we do need them then they are ready to go,” said Charlie Blackwell-Thompson, Artemis launch director. “Our upcoming integrated ground systems training is about demonstrating the capability of the entire emergency egress response from the time an emergency condition is declared until we have the crews, both flight and ground, safely accounted for outside the hazardous area.”
For the agency’s Commercial Crew Program, SpaceX uses a slidewire cable with baskets that ride down the cable at the Launch Complex 39A pad. At Space Launch Complex 40, meanwhile, the team uses a deployable chute for its emergency egress system. Boeing and United Launch Alliance also use a slidewire, but instead of baskets, the team deploys seats that ride down the slide wires, similar to riding down a zip line, at Space Launch Complex 41 at Cape Canaveral Space Force Station.
Artemis II will be NASA’s first mission with crew aboard the SLS (Space Launch System) rocket and Orion spacecraft and will also introduce several new ground systems for the first time – including the emergency egress system. Though no NASA mission to date has needed to use its ground-based emergency egress system during launch countdown, those safety measures are still in place and maintained as a top priority for the agency.
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By NASA
The NASA Disasters Response Coordination System (DRCS) formally launched on 6/13/24 during a ceremony at NASA Headquarters with Administrator Nelson as the keynote speaker. The DRCS is a revamped one NASA approach in how the agency responds to natural hazards and disasters domestically and internationally to support partners and stakeholders The DRCS will be organized by the Program Office located at LaRC. MSFC and Earth Science Branch Disasters team will continue to support the DRCS and events that agency respond too by tapping into expertise and subject matter expertise here at MSFC. MSFC was represented at the DRCS launch by Center Response Coordinators Jordan Bell (ST11), Ronan Lucey (ST11/UAH) and Earth Action Associate Disasters Program Manager Lori Schultz (ST11). Additional information about the DRCS launch can be found here: https://science.nasa.gov/earth/natural-disasters/nasa-announces-new-system-to-aid-disaster-response/.
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By NASA
Linda Krause and Heidi Haviland (ST13) along with Jeff Apple, Miguel Rodriguez-Otero (ES11), Kurt Dietz (ES52), and Gary Thornton (ES21) contributed to the Planetary Instrument Concepts for the Advancement of Solar System Observations (PICASSO) proposal LVACCS that was selected for funding. Omar Leon (University of Michigan) is the instrument suite PI. Electric charge accumulates on the lunar rovers and landers from ambient plasma, ionizing radiation, suprathermal charged particles, dust, and surface regolith. LVACCS will measure both the positive and negative charge, acts to discharge negative charge buildup, and actively charges the vehicle to a known positive potential. This increases the accuracy and precision of related instruments including dust, plasma, and electric fields. LVACCS builds from heritage systems in geosynchronous orbit but with a much smaller size, weight, and power. LVACCS has two main components: a collimated photoelectron gun (CPEG, led by MSFC), and a spacecraft charge detector (led by the University of Michigan). Within the two years of the award, the instrument will mature from TRL 2 to 5. LVACCS solves the important and timely problem of charge build up at the lunar surface for future lander and rover missions.
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