Artemis II Rocket Hardware Ready for Final Outfitting

Materials scientists finished applying the thermal protection system to NASA’s Space Launch System (SLS) launch vehicle stage adapter and moved it to another manufacturing area to finish outfitting the flight hardware for the Artemis II mission.

Artemis II launch vehicle stage adapter
Technicians at NASA’s Marshall Space Flight Center in Huntsville, Alabama moved the Artemis II launch vehicle stage adapter to another manufacturing area to finish outfitting the flight hardware on Dec. 8, 2021.

On Dec. 8, 2021, a NASA transporter moved the adapter which was built at NASA’s Marshall Space Flight Center by lead contractor Teledyne Brown Engineering in Huntsville, Alabama. Teams recently completed applying the spray-on foam insulation that will protect the rocket hardware during flight. Now, crews will outfit the inside of the adapter with platforms that will allow teams to access the inside during assembly with the rest of the rocket. Technicians will also install special systems that allow the adapter and the core stage to separate from the Interim Cryogenic Propulsion Stage, or ICPS. The adapter connects the rocket’s core stage to the ICPS, which provides the power to perform the trans-lunar injection maneuver to send the Orion spacecraft to the Moon. This adapter is for the Artemis II mission that will be the first to return American astronauts to lunar orbit.

launch vehicle stage adapter
Prior to the launch vehicle stage adapter being moved on Dec. 8, 2021, teams recently completed applying the spray-on foam insulation that will protect the rocket hardware during flight.

SLS Booster Fired up to Test Improved Design for Future Artemis Missions

A team of NASA and Northrop Grumman engineers fired a 2-foot-diameter, subscale solid rocket booster on Dec. 2, 2021, at NASA’s Marshall Space Flight Center in Huntsville, Alabama. This test, conducted in Marshall’s East Test Area, was the second of three tests supporting the Booster Obsolescence and Life Extension (BOLE) program, which will have an upgraded design to power the evolved configuration of the Space Launch System (SLS) rocket on flights after Artemis VIII.

24-inch diameter subscale solid rocket test
NASA engineers successfully completed a 24-inch diameter subscale solid rocket test on Dec. 2, 2021, at NASA’s Marshall Space Flight Center in Huntsville, Alabama, in the East Test Area. The sub-scale motor produced 76,400 pounds of thrust during the hot fire test. This test was the first of two tests supporting the Booster Obsolescence and Life Extension (BOLE) development effort that includes a new motor design for upcoming Artemis missions after Artemis VIII. This 334-inch motor was the longest subscale motor tested to date.

The BOLE booster will be a larger and more powerful solid rocket motor than the current SLS solid rocket booster. The boosters for the first eight flights of the Artemis program repurpose the steel booster cases and parts from the Space Shuttle Program with an upgraded design. The BOLE booster will implement a composite case design, replace obsolete parts with newer components, and improve the booster’s design and performance.

This test focused on the booster motors, which provide the majority of the power to launch SLS. Unlike previous subscale motor tests, this marked the first time the team could evaluate insulation and nozzle on one motor rather than two configurations, one for the nozzle and one for the insulation. During this subscale test, the motor produced 76,400 pounds of thrust.

The original test design had two segments, each 9 feet long. To get a more characteristic thrust profile, a 4.5-foot-long segment was added to the test article, totaling nearly 28 feet and making this the longest subscale motor tested to date. In addition to the added half segment, a new propellant, aft dome design, and nozzle design are included in the BOLE motor development program that will become part of the Block 2 evolved rocket.

During the test, three different internal case insulation formulations were evaluated in the aft dome. The performance results of these materials will aid in selecting a final formulation for the first full-scale test fire of the BOLE booster. As the team completes the final design for the full-scale motor, this test is an important step in learning how materials will perform at the higher pressure and performance expected for the BOLE motor as compared to current motors.

The third test of the subscale motor is currently scheduled for spring 2022 at Marshall, followed by the first full-scale BOLE motor test, tentatively scheduled for spring 2024 at Northrop Grumman’s test facility in Utah. Northrop Grumman, lead contractor for the booster, helped conduct the Marshall test and will be assisting with data evaluation.

Final Certification Run for Orion Recovery

A test version of the Orion spacecraft is loaded into the well deck of a U.S. Navy ship.
A test version of NASA’s Orion spacecraft is loaded into the well deck of a U.S. Navy ship in preparation for the ninth in a series of tests to verify and validate procedures and hardware that will be used to recover the spacecraft after it splashes down in the Pacific Ocean following the agency’s Artemis I mission. The first in an increasingly complex series of missions, Artemis I will test the Space Launch System rocket and Orion as an integrated system prior to crewed flights to the Moon. Photo credit: NASA/Pete Reutt

NASA and the U.S. Navy are preparing to head out to sea for the ninth in a series of tests to verify and validate procedures and hardware that will be used to recover the Orion spacecraft after it splashes down in the Pacific Ocean following deep space exploration missions.

NASA’s Landing and Recovery team, managed by Exploration Ground Systems, is heading from the agency’s Kennedy Space Center in Florida to Naval Base San Diego in California where they will have their final certification run for the Artemis I mission.

During the weeklong test, the joint team will conduct simulations that will exercise all the operational procedures, including nighttime, to support certification of team members for the Artemis I mission. The team will practice recovering a test version of an Orion capsule and bringing it into the well deck of a Navy ship, ensuring all personnel are properly trained before the real Orion splashes down.

Orion is the exploration spacecraft designed to carry astronauts to the Moon and destinations not yet explored by humans. It is slated to launch atop NASA’s Space Launch System rocket on its first deep space mission to pave the way for future flights with astronauts.

Stacking Operations for Artemis I Mission Nearing Completion

Orion spacecraft
Photo Credit: Frank Michaux

Teams with Exploration Ground Systems successfully lifted the Orion Spacecraft for the Artemis I mission inside the Vehicle Assembly Building on Oct. 20, 2021. Teams attached the spacecraft to one of the five overhead cranes inside the building and began lifting it a little after midnight EDT. Work is underway to fully secure Orion to the Space Launch System rocket after teams initially placed the spacecraft on top of the rocket earlier today. This operation will take several hours to make sure Orion is securely in place.

Lift Underway to Top Mega-Moon Rocket with Orion Spacecraft

Orion lifted atop SLS rocket in the VAB
Photo Credit: Chad Siwik

Final stacking operations for NASA’s mega-Moon rocket are underway inside the Vehicle Assembly Building at NASA’s Kennedy Space Center as the Orion spacecraft is lifted onto the Space Launch System (SLS) rocket for the Artemis I mission. Engineers and technicians with Exploration Ground Systems (EGS) and Jacobs attached the spacecraft to one of the five overhead cranes inside the building and began lifting it a little after midnight EDT.

Next, teams will slowly lower it onto the fully stacked SLS rocket and connect it to the Orion Stage Adapter. This will require the EGS team to align the spacecraft perfectly with the adapter before gently attaching the two together. This operation will take several hours to make sure Orion is securely in place.

NASA will provide an update once stacking for the Artemis I mission is complete.

Orion ‘Powerhouse’ for Artemis II Arrives at Kennedy

The European Service Module (ESM) for NASA’s Orion spacecraft arrives at the Launch and Landing Facility at NASA’s Kennedy Space Center in Florida on Thursday, Oct. 14, 2021.
The European Service Module for NASA’s Orion spacecraft arrives at the Launch and Landing Facility at NASA’s Kennedy Space Center in Florida on Thursday, Oct. 14, 2021. Making the journey from the Airbus Facility in Bremen, Germany, aboard a Russian Antonov aircraft, the service module will be transferred to Kennedy’s Neil A. Armstrong Operations and Checkout Facility. Photo credit: NASA/Isaac Watson

Built by teams at ESA (European Space Agency) and aerospace corporation Airbus, the European Service Module for NASA’s Orion spacecraft arrived at NASA’s Kennedy Space Center in Florida on Thursday, Oct. 14, aboard the Russian Antonov aircraft. This service module will be used for Artemis II, the first Artemis mission flying crew aboard Orion. Service module assembly was completed at the Airbus facility in Bremen, Germany, and the module traveled across the world on its journey to Kennedy.

The service module is the powerhouse that will fuel and propel Orion in space. It stores the spacecraft’s propulsion, thermal control, electrical power, and critical life support systems such as water, oxygen, and nitrogen.

The service module will be transferred from the Launch and Landing Facility to Kennedy’s Neil A. Armstrong Operations and Checkout Facility where teams from NASA and Lockheed Martin will integrate it with the crew module adapter and crew module, already housed in the facility.

With Artemis missions, NASA will land the first woman and the first person of color on the lunar surface. Artemis II will be the first crewed flight test of NASA’s Space Launch System and Orion, paving the way for human exploration to the Moon and Mars.

Final Piece of Rocket Hardware Added to Artemis I Stack

Final OSA stacked on top of the ICPS
After successfully completing the integrated modal test, technicians removed the Space Launch System (SLS) rocket’s Orion stage adapter structural test article and the Mass simulator for Orion. Then, they moved the Orion stage adapter flight hardware to the Vehicle Assembly Building at NASA’s Kennedy Space Center in Florida. On Oct. 9, the Orion stage adapter was connected to the top of the Interim Cryogenic Propulsion Stage (ICPS) that provides the power to send Orion to the Moon. Soon, Orion, which rides on top of SLS, will be stacked to complete the Artemis I spaceship. Artemis I is the first integrated flight of SLS and Orion. This uncrewed flight test will be followed by Artemis II, which will be the first mission to send astronauts on a mission to orbit the Moon.

Leerlo en español aquí.

The last piece of Space Launch System (SLS) rocket hardware has been added to the stack at NASA’s Kennedy Space Center in Florida. Crews with NASA’s Exploration Ground Systems and contractor Jacobs added the Orion stage adapter to the top of the rocket inside the spaceport’s Vehicle Assembly Building. To complete the Artemis I stack, crews will soon add the Orion spacecraft and its launch abort system on top of Orion stage adapter.

The Orion stage adapter, built at NASA’s Marshall Space Flight Center in Huntsville, Alabama connects Orion to the Interim Cryogenic Propulsion Stage (ICPS), which was built by Boeing and United Launch Alliance at ULA’s factory in Decatur, Alabama. During the mission, the ICPS will fire one RL10 engine in a maneuver called trans-lunar injection, or TLI, to send Orion speeding toward the Moon.

As Orion heads to the Moon for its mission, the ICPS will separate from Orion and then deploy 10 secondary payloads that are riding to space inside the Orion stage adapter. These CubeSats have their own propulsion systems that will take them on missions to the Moon and other destinations in deep space.

While the ICPS and Orion stage adapter are making it possible for SLS to send its first science payloads to space on this uncrewed mission, they only will be used for the first three Artemis missions. The Exploration Upper Stage (EUS), a more powerful stage with four RL10 engines, will be used on future Artemis missions. The EUS can send 83,000 pounds to the Moon, which is 40 percent more weight than the ICPS. The EUS makes it possible to send Orion, astronauts, and larger and heavier co-manifested payloads to the Moon.

Artemis I will be followed by a series of increasingly complex missions. With Artemis, NASA will land the first woman and the first person of color on the lunar surface and establish long-term exploration at the Moon in preparation for human missions to Mars. SLS and NASA’s Orion spacecraft, along with the commercial human landing system and the Gateway in orbit around the Moon, are NASA’s backbone for deep space exploration. SLS is the only rocket that can send Orion, astronauts, and supplies to the Moon in a single mission.

All Artemis I Secondary Payloads Installed in Rocket’s Orion Stage Adapter

Technicians have loaded the last of 10 CubeSats into the Space Launch System (SLS) rocket’s five-foot-tall Orion stage adapter at NASA’s Kennedy Space Center in Florida. After the Orion spacecraft separates from the SLS rocket for a precise trajectory toward the Moon, the shoebox-sized payloads are released from the Orion stage adapter to conduct their own science and technology missions.

SLS’s main goal for the Artemis I mission is to successfully send the uncrewed Orion spacecraft to lunar orbit where it can test out critical spacecraft systems and then return to Earth testing the spacecraft’s heat shield at lunar reentry speeds. The Orion stage adapter connects the rocket to Orion and contains room inside the adapter to provide a rare opportunity to send the CubeSats to deep space using extra lift-capacity on the uncrewed mission. The CubeSats will study everything from the Moon to asteroids to the deep space radiation environment. Each CubeSat provides its own propulsion and navigation to get to various deep space destinations.

Nine of the ten CubeSats were loaded into the adapter earlier this summer. The last CubeSat to be placed aboard was BioSentinel, the sole CubeSat among this group of satellite payloads that contains a living microorganism, and which was refrigerated until loading in order to preserve its biological contents as long as possible for the mission. BioSentinel’s primary objective is to detect and measure the effect of space radiation on living organisms – in this case, yeast – over long durations beyond low-Earth orbit. A similar experiment is being carried out on the International Space Station so that research teams can compare radiation effects experienced on the station about 250 miles above Earth to those encountered in deep space near the Moon, more than 240,000 miles away.

BIOSENTINEL installed in OSA and other CubeSats in OSA
The Jacobs team at NASA’s Kennedy Space Center in Florida installing the last of 10 CubeSats in the Space Launch System (SLS) rocket’s Orion stage adapter. Biosentinel, the final CubeSat to be loaded, will study how radiation affects living organisms in deep space. Biosentinel joins nine other CubeSats that will be studying a variety of destinations, including the Moon, and scientific areas important to deep space exploration.

Developed by NASA’s Ames Research Center in California’s Silicon Valley and the agency’s Johnson Space Center in Houston, Loma Linda University Medical Center, and the University of Saskatchewan, It is among the first studies of the biological response to space radiation outside low-Earth orbit in nearly 50 years. Human cells and yeast cells have many similar biological mechanisms, including DNA damage and repair, and BioSentinel’s experiments can help us better understand the radiation risks for long-duration deep space human exploration.

OSA with all the CubeSats installed.
All 10 secondary payloads have been installed in the Space Launch System (SLS) rocket’s Orion stage adapter. The SLS rocket had extra capacity to give the “hitchhiking” CubeSats a free ride on the Artemis I mission. The mission’s primary goal is a flight test of the integrated SLS and Orion system. The Orion stage adapter connects the SLS rocket to Orion and had slots built into it for the payloads. The CubeSats provide their own deployment and propulsion systems that will take them to specific destinations including the Moon and an asteroid.

Progress continues to complete stacking for the Artemis I mission and check out the integrated hardware operations. The team recently successfully completed two complex tests: the Umbilical Retract and Release Test and the Integrated Modal Test.  Next, the Artemis I Orion stage adapter with the secondary payloads will be moved to the Vehicle Assembly Center at Kennedy Space Center in Florida and added to complete stacking of the rocket. Then, the Orion spacecraft will be stacked on top of the rocket to complete the Artemis I spaceship. Artemis I is the first in a series of increasingly complex missions to send astronauts to the Moon for long-term exploration that sets the stage for human missions to Mars.

Release and Retract Test Marks Artemis I Mission Milestone

A close-up view of the Artemis I Space Launch System rocket inside High Bay 3 of the Vehicle Assembly Building at Kennedy Space Center in Florida.
A close-up view of the Artemis I Space Launch System rocket inside High Bay 3 of the Vehicle Assembly Building at NASA’s Kennedy Space Center in Florida on Sept. 20, 2021. All 10 levels of work platforms have been retracted from around the rocket as part of the umbilical release and retract test. During the test, several umbilical arms on the mobile launcher were extended to connect to the SLS rocket and then swung away from the launch vehicle, just as they will on launch day. Artemis I will be the first integrated test of the SLS and Orion spacecraft. In later missions, NASA will land the first woman and the first person of color on the surface of the Moon, paving the way for a long-term lunar presence and serving as a steppingstone on the way to Mars. Photo credit: NASA/Frank Michaux

Engineers with Exploration Ground Systems and contractor Jacobs successfully completed the Umbilical Release and Retract Test on Sept. 19 inside the Vehicle Assembly Building (VAB) at NASA’s Kennedy Space Center in preparation for the Artemis I mission.

The umbilicals will provide power, communications, coolant, and fuel to the rocket and the Orion spacecraft while at the launch pad until they disconnect and retract at ignition and liftoff.

“Previous testing at the Launch Equipment Test Facility and in the VAB refined our designs and processes and validated the subsystems individually, and for Artemis I, we wanted to prove our new systems would work together to support launch,” said Jerry Daun, Jacobs Arms and Umbilical Systems Operations Manager.

During the test, several umbilical arms extended to connect the Space Launch System (SLS) rocket and the mobile launcher. They swung away from the rocket, just as they will on launch day.

“This test is important because the next time these ground umbilical systems are used will be the day of the Artemis I launch,” said Scott Cieslak, umbilical operations and testing technical lead.

Teams will continue conducting tests inside the VAB before transporting the Orion spacecraft to the assembly building and stacking it atop the SLS, completing assembly of the rocket for the Artemis I mission.

“It was a great team effort to build, and now test, these critical systems,” said Peter Chitko, arms and umbilicals integration manager. “This test marked an important milestone because each umbilical must release from its connection point at T-0 to ensure the rocket and spacecraft can lift off safely.”

Artemis I will be the first integrated test of the SLS and Orion spacecraft. In later Artemis missions, NASA will land the first woman and the first person of color on the surface of the Moon, paving the way for a long-term lunar presence and serving as a steppingstone on the way to Mars.

Orion Spacecraft Goes ‘Shields Up’ for Artemis I

The four ogive fairings for the Orion Artemis I mission are installed on the launch abort system assembly inside the Launch Abort System Facility at NASA's Kennedy Space Center in Florida on Aug. 20, 2021.
The four ogive fairings for the Orion Artemis I mission are installed on the launch abort system assembly inside the Launch Abort System Facility at NASA’s Kennedy Space Center in Florida on Aug. 20, 2021. Photo credit: NASA/Kim Shiflett

Teams at NASA’s Kennedy Space Center in Florida are putting the final touches on the Orion spacecraft for the Artemis I mission by connecting the ogive fairings for the launch abort system (LAS) assembly.  Pronounced oh-jive, the ogive fairings consist of four protective panels, and their installation will complete the LAS assembly.

Technicians and engineers from the center’s Exploration Ground Systems and contractor Jacobs recently finished attaching the launch abort tower to the top of the Orion crew module. They then began lifting and mating the lightweight fairings, which will shield the crew module from the severe vibrations and sounds it will experience during launch. One of the fairing panels has a hatch to allow access to the crew module before launch.

During Artemis missions, the 44-foot-tall LAS will detach from the spacecraft when it is no longer needed, shortly after launching on the Space Launch System (SLS) rocket, to lighten the journey to the Moon. Although the abort motors will not be active on the uncrewed Artemis I flight test, the system is intended to protect astronauts on future missions if a problem arises during launch or ascent by pulling the spacecraft away from a failing rocket.

Once LAS installation is complete, the spacecraft will leave the Launch Abort System Facility and continue on its path to the pad, making its way to the spaceport’s Vehicle Assembly Building to be integrated with the SLS rocket ahead of the launch.