Artemis I extends NASA and ESA’s (European Space Agency) strong international partnership beyond low-Earth orbit to lunar exploration with Orion on Artemis missions, as the ESA logo joins the historic NASA “meatball” insignia on the Artemis I spacecraft adapter jettison fairing panels that protect the service module during launch. Photo credit: NASA/Glenn Benson
NASA’s Artemis IOrion spacecraft is being outfitted with additional artwork as technicians began installing the logo for ESA (European Space Agency). ESA provided the European-built service module, which provides power and propulsion for the Orion spacecraft, and will also provide water and air for astronauts on future missions.
The ESA (European Space Agency) logo joins the historic NASA “meatball” insignia on the Artemis I spacecraft adapter jettison fairing panels that protect the service module during launch. Orion is currently stationed at NASA’s Kennedy Space Center in the Multi-Payload Processing Facility. Photo credit: NASA/Glenn Benson
Artemis I extends NASA and ESA’s strong international partnership beyond low-Earth orbit to lunar exploration with Orion on Artemis missions. The ESA logo joins the historic NASA “meatball” insignia on the Artemis I spacecraft adapter jettison fairing panels that protect the service module during launch.
Orion is currently stationed at NASA’s Kennedy Space Center in the Multi-Payload Processing Facility, where it will undergo fueling and servicing by NASA’s Exploration Ground Systems and Jacobs Technology teams in preparation for the upcoming flight test with the Space Launch System rocket under the agency’s Artemis program.
The twin solid rocket boosters for NASA’s Space Launch System (SLS) are being stacked on the mobile launcher inside the Vehicle Assembly Building at the agency’s Kennedy Space Center in Florida. The boosters will power SLS on the Artemis I mission. Photo credit: NASA/Kim Shiflett
Booster stacking continues! The second to last set of segments for NASA’s Space Launch System (SLS) solid rocket boosters were placed on the mobile launcher inside the Vehicle Assembly Building at NASA’s Kennedy Space Center. Engineers with Exploration Ground Systems and Jacobs transported the segments from the Rotation, Processing and Surge Facility, where they have been since June. Once fully stacked, each booster will stand nearly 17 stories tall. The twin boosters will power the first flight of the agency’s new deep space rocket during the Artemis I mission. This uncrewed flight later this year will test the SLS rocket and Orion spacecraft as an integrated system ahead of crewed flights.
Orion is buttoned up and ready to march towards the Multi-Payload Processing Facility to begin ground processing by the Exploration Ground Systems and Jacobs teams ahead of the Artemis I launch. Shielded by a protective covering for transport, the spacecraft departs its home at the Neil Armstrong Operations and Checkout Building at NASA’s Kennedy Space Center in Florida on Jan. 16, 2021. Photo credit: NASA/Kim Shiflett
NASA marked another milestone on the path toward the launch of Artemis I on Saturday, as engineers moved the Orion spacecraft out of the Neil Armstrong Operations & Checkout Building on its way to the Multi-Payload Processing Facility (MPPF) at the agency’s Kennedy Space Center in Florida, where the spacecraft will be fueled for its mission around the Moon.
The milestone marked completion of years of assembly and testing operations for the spacecraft and formal transfer of the spacecraft from the Orion Program and its prime contractor Lockheed Martin to NASA’s Exploration Ground Systems (EGS) team responsible for processing the vehicle, integrating it with the Space Launch System rocket, and launching them on their inaugural mission together.
The spacecraft was moved out of the O&C aboard a transport pallet and air bearing system which sits on top of a transporter. In the MPPF, it will be moved into a service stand that provides 360-degree access, allowing engineers and technicians from EGS, its lead contractor Jacobs Technology, and other support organizations to fuel and service the spacecraft. Crane operators will remove the transportation cover and use fuel lines and several fluid ground support equipment panels to load the various gases and fluids into the crew and service modules.
After Orion is fueled and engineers perform final checks in the MPPF, they will move the spacecraft to the Launch Abort System Facility, where EGS will install the Launch Abort System tower and the ogive panels that protect the crew module and LAS and provide its aerodynamic shape.
Orion is a critical component for NASA’s deep space exploration plans. During Artemis I, the spacecraft will launch on the most powerful rocket in the world and fly farther than any spacecraft built for humans has ever flown – 280,000 miles from Earth, thousands of miles beyond the Moon over the course of about a three-week mission.
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.
The attitude control motor for the Artemis II mission arrives in the Launch Abort System Facility at NASA’s Kennedy Space Center in Florida on Aug. 28, 2020. Photo credit NASA/Ben Smegelsky
The last of three motors required to assemble the Launch Abort System for NASA’s Artemis II mission–the first crewed mission of the Orion spacecraft–arrived at Kennedy Space Center in Florida on August 28. The attitude control motor (ACM) was delivered by truck from Northrop Grumman’s manufacturing facility in Maryland, to the Launch Abort System Facility (LASF) at Kennedy.
During launch of Orion atop the agency’s Space Launch System rocket, the LAS motors work together to separate the spacecraft from the rocket in the unlikely event of an emergency during launch. The LAS includes three motors – the launch abort motor, the jettison motor, and the attitude control motor—that once activated, will steer the spacecraft carrying the astronauts to safety. The launch abort and attitude control motors were manufactured by Northrop Grumman; the jettison motor was manufactured by Aerojet Rocketdyne.
The ACM operates to keep Orion’s crew module on a controlled flight path in the event it needs to jettison and steer away from the rocket. It then reorients the crew module for parachute deployment and landing. The motor consists of a solid propellant gas generator, with eight proportional valves equally spaced around the outside of the 32-inch diameter motor. Together, the valves can exert up to 7,000 pounds of steering force to the vehicle in any direction upon command from the crew module.
Inside the LASF, the motor will be placed on a special trailer for future integration with the rest of the LAS elements. It will remain in the LASF midbay, where the Artemis I LAS is being integrated with its designated crew and service module for its mission next year.
Artemis II is the first crewed flight in a series of increasingly complex missions to the Moon that will lay the foundation for exploration of Mars and beyond. Artemis II will confirm all of the Orion spacecraft’s systems operate as designed in the actual environment of deep space with astronauts aboard. As part of the Artemis program, NASA will send the first woman and next man to the Moon in 2024.
Inside the Launch Control Center’s Firing Room 1 at NASA’s Kennedy Space Center in Florida, members of the Artemis I launch team rehearse the procedures for fueling the Space Launch System (SLS) rocket with super cold propellants, or cryogenics, on Aug. 18, 2020. Photo credit: NASA/Chad Siwik
The launch team for Artemis I is back in the firing room at NASA’s Kennedy Space Center for more practice. The team conducted a simulation on the procedures for cryogenic loading, or fueling the Space Launch System rocket with super cold propellants. During simulations potential problems are introduced to the team to test the application of firing room tools, processes, and procedures.
The Exploration Ground Systems team of launch controllers who will oversee the countdown and liftoff of the SLS rocket and Orion spacecraft will be practicing the procedures several more times ahead of launch. Special protocols have been put in place to keep personnel safe and healthy, including limiting personnel in the firing room, using acrylic dividers and adjusting assigned seating for the cryo team.
