Teams from NASA, Lockheed Martin, the European Space Agency (ESA), Airbus Defence, and Airbus Netherlands have completed the meticulous installation of Orion’s four solar array wings. The arrays will supply energy to the service module that will power and propel the spacecraft during NASA’s Artemis I mission. They were fitted onto the European Service Module (ESM) inside the Neil Armstrong Operations and Checkout Building at the agency’s Kennedy Space Center in Florida.
Activities on the spacecraft continue to move forward — the next set of final installations include the spacecraft adapter jettison fairings, which enclose the service module, and forward bay cover, protecting the upper part of Orion including its parachutes throughout its mission. Once complete, the spacecraft will begin its journey through Kennedy to be integrated with its launch abort system and ultimately, the Space Launch System (SLS) rocket for launch from Kennedy’s Launch Pad 39B.
Artemis I will demonstrate NASA’s networks’ comprehensive services for journeys to lunar orbit. The mission requires all three of NASA’s major networks to work in tandem, providing different communications and tracking service levels as Orion leaves Earth, orbits the Moon, and returns safely home.
Communications services allow flight controllers in mission control centers to send commands to the spacecraft and receive data from Orion and SLS systems. Tracking, or navigation, services enable the flight controllers to see where the spacecraft are along their trajectory through space.
Engineers at NASA’s Stennis Space Center near Bay St. Louis, Mississippi, completed a simulated launch countdown sequence on Oct. 5 for the sixth test of the eight-part core stage Green Run test series for NASA’s Space Launch System (SLS) rocket.
The rocket’s core stage has three flight computers and avionics systems to help launch and guide NASA’s Artemis missions to the Moon. During the simulated countdown, NASA engineers and technicians, along with prime contractors Boeing, and Aerojet Rocketdyne, monitored the stage to validate the timeline and sequence of events leading up to the test, which is similar to the countdown for the Artemis I launch.
The countdown sequence for an actual Artemis launch begins roughly two days prior to liftoff. In addition to all the procedures leading up to the ignition of the four RS-25 engines, the SLS core stage requires about six hours to fully load fuel into the two liquid propellant tanks. The simulated countdown sequence test at Stennis began at the 48-hour mark as if the stage was first powered up before liftoff. Engineers then skipped ahead in the sequence to monitor the stage and procedures of the stage 10 minutes before the hot fire. The simulated countdown sequence is one of the final tests of the SLS Green Run campaign. The series of tests is designed to gradually bring the rocket stage and all its systems to life for the first time.
Engineers and technicians at NASA’s Kennedy Space Center in Florida install the radiator for the Mass Spectrometer Observing Lunar Operations (MSolo) instrument inside the Space Station Processing Facility on Sept. 25, 2020. Photo credit: NASA/Glenn Benson
A versatile instrument designed to help analyze the chemical makeup of lunar landing sites and study water on the Moon as part of the Artemis program has completed an important step in its final assembly.
Teams working on the Mass Spectrometer Observing Lunar Operations, or MSolo, at NASA’s Kennedy Space Center in Florida installed the radiator – a critical component that will keep the instrument’s temperature stable in the extreme heat and cold it will encounter on the Moon.
MSolo is a commercial off-the-shelf mass spectrometer modified to work in space. NASA will use MSolo to identify molecules on the surface of the Moon. Multiple MSolo instruments are destined for the Moon via the help of NASA’s commercial partners, landing scientific instruments and technology demonstrations on the lunar surface as part of the Commercial Lunar Payload Services (CLPS) initiative.
NASA has scheduled MSolo instruments to launch on future robotic missions starting in 2021 at Lacus Mortis, a large crater on the near side of the Moon. MSolo is a key component of the Polar Resources Ice Mining Experiment, or PRIME-1, instrument suite that will use a drill to harvest ice just below the lunar surface in 2022. Later, the technology will be one of three instruments on board NASA’s water-hunting Volatiles Investigating Polar Exploration Rover, VIPER, scheduled to launch to the Moon’s South Pole in late 2023.
On VIPER, the MSolo instrument will help evaluate subsurface soil cuttings brought up by a 3-foot drill in search of water ice and other volatiles that future missions could use as resources. The mission will create the most detailed view of the Moon’s water to date – helping to pave the way for the lunar surface missions with crew beginning in 2024.
NASA is headed back to the Moon as part of the Artemis program – and the agency’s “worm” logo will be along for the ride on the first integrated mission of the powerful Space Launch System (SLS) rocket and Orion spacecraft. Teams at NASA’s Kennedy Space Center in Florida have applied the historic logo in bright red on visible parts of the Artemis I rocket and spacecraft.
NASA’s Super Guppy arrives at Kennedy Space Center’s Launch and Landing Facility in Florida on Sept. 11, 2020, carrying the Orion Service Module Structural Test Article (SM-STA). Photo credit: NASA/Yulista Tactical Services, LLC/Tommy Quijas
The Orion Service Module Structural Test Article (SM-STA), composed of the European Service Module (ESM) and Crew Module Adapter (CMA), arrived at NASA’s Kennedy Space Center in Florida following the completion of the test campaign to certify the Orion Service Module for Artemis I. Transported via Super Guppy from Lockheed Martin’s test facility in Denver, Colorado, on Sept. 11, components will now be used in testing for future Artemis missions.
“The Orion SM-STA supported testing in multiple configurations to validate the structural robustness of the vehicle under a variety of conditions that a spacecraft will experience on lunar missions for the Artemis program,” said Rafael Garcia, Orion Test and Verification lead.
At Kennedy, the Orion SM-STA test article will be separated from the CMA test article, and portions of the CMA test article will support qualifications tests in preparation for the Artemis II mission. The test version of the ESM will remain at Kennedy, in order to support future structural qualification tests such as testing what volume of sound and how much shaking the vehicle can handle for future Artemis missions.
When tested together, the full test stack of Orion verified the spacecraft’s structural durability for all flight phases of the Artemis I flight, which is designed to be an opportunity to test the kind of maneuvers and environments the spacecraft will see on future exploration missions. The test structures experienced launch and entry loads tests, intense acoustic vibration force, and shock tests that recreate the powerful blasts needed for critical separation events during flight. A lightning test was performed to evaluate potential flight hardware damage if the vehicle were to be hit by lightning prior to launch.
The Artemis II flight will test a hybrid free return trajectory, which uses the Moon’s gravitational pull as a slingshot to put Orion on the return path home instead of using propulsion. With astronauts aboard the spacecraft, additional validation is required of all vehicle components to certify the capsule prior to proving lunar sustainability with Artemis III and beyond.
The first in a series of increasingly complex missions, Artemis I will test the Orion spacecraft and Space Launch System as an integrated system ahead of crewed flights to the Moon. Under the Artemis program, NASA will land the first woman and the next man on the Moon in 2024.
Following a series of critical contract awards and hardware milestones, an update on NASA’s Artemis program is now available, including the latest Phase 1 plans to land the first woman and the next man on the surface of the Moon in 2024.
In the 18 months since NASA accepted a bold challenge to accelerate its exploration plans by more than four years and establish sustainable exploration by the end of the decade, the agency has continued to gain momentum toward sending humans to the Moon again for the first time since the last Apollo mission in 1972.
The document captures Artemis progress to date, identifying the key science, technology and human missions as well as the commercial and international partnerships that will ensure we continue to lead in exploration and achieve our ambitious goal to land astronauts on the Moon.
Technicians with NASA’s Exploration Ground Systems rehearse booster stacking operations inside the Vehicle Assembly Building (VAB) at the agency’s Kennedy Space Center in Florida on Monday, Sept.14, in preparation for the Artemis I launch. The team is using full-scale replicas of booster segments, referred to as pathfinders, for the practice exercise in one of the tallest sections, or high bays, of the VAB built for stacking rockets. As part of the rehearsal, a pathfinder for an aft segment, the very bottom of the stack, was prepared in High Bay 4. Then, a team of crane operators moved the segment into High Bay 3, where it was placed on the mobile launcher. Careful measurements were taken before the team added a center segment to the stack.
The actual Space Launch System (SLS) booster segments will be stacked on the mobile launcher later this year, following completion of Green Run testing of the rocket’s core stage – a series of eight tests taking place at the agency’s Stennis Space Center in Mississippi.
Inside the Neil Armstrong Operations and Checkout Building at NASA’s Kennedy Space Center in Florida, technicians have extended one of the Artemis I solar array wings on Sept. 10, 2020. Prior to installation on the Orion spacecraft, the team performed an inspection to confirm proper extension and to ensure all of the mechanisms functioned as expected. The pictured solar array is one of four panels that will generate 11 kilowatts of power and span about 63 feet. The array is a component of Orion’s service module, which is provided by the European Space Agency and built by Airbus Defence and Space to supply Orion’s power, propulsion, air and water.
The first in a series of increasingly complex missions, Artemis I will test the Orion spacecraft and Space Launch System as an integrated system ahead of crewed flights to the Moon. Under the Artemis program, NASA will land the first woman and the next man on the Moon in 2024.
Engineers have completed the fifth of eight Green Run tests on the core stage of NASA’s new Space Launch System (SLS) rocket, continuing progress toward a hot fire test this fall. Operators evaluated the stage’s thrust vector control system on the historic B-2 Test Stand at NASA’s Stennis Space Center near Bay St. Louis, Miss., on Sept. 13. The test provided critical verification of the control system and its related hydraulics as operators moved the stage’s four RS-25 engines as they must move during flight to steer the rocket and maintain a proper trajectory. The stage now is set for two more tests – a simulated countdown demonstration and wet dress rehearsal – directly leading to the hot fire of all four RS-25 engines, as during an actual flight.
In the countdown demonstration, engineers will simulate the launch countdown and procedures to validate the established timeline and sequence of events. In the wet dress rehearsal, engineers will conduct another countdown exercise and actually load, control and drain more than 700,000 gallons of cryogenic propellants to ensure all is set for the final test of the Green Run series. The concluding test will activate all stage systems and fire the four RS-25 engines to generate the same combined 1.6 million pounds of thrust that will help launch the SLS rocket when it flies on the Artemis I mission.
