NASA Collins xEVAS Update 

NASA Collins xEVAS Update 

The space station is pictured from the SpaceX Crew Dragon Endeavour during its departure and flyaround on Nov. 8, 2021.
The space station is pictured from the SpaceX Crew Dragon Endeavour during its departure and flyaround on Nov. 8, 2021.

In 2022 and 2023, NASA awarded Collins Aerospace two task orders under the agency’s xEVAS (Exploration Extravehicular Activity Services) contract. The first task order was to deliver a next generation spacesuit and spacewalking system for potential use on the International Space Station with a base value of $97.2 million. The second task order was to advance additional spacesuit capabilities with a base value of $5 million.

After a thorough evaluation, NASA and Collins Aerospace have mutually agreed to descope the existing task orders on the Collins Exploration Extravehicular Activity Services contract. This descope includes ending the International Space Station suit demonstration, which was targeted for 2026. No further work will be performed on the task orders. This action was agreed upon after Collins recognized its development timeline would not support the space station’s schedule and NASA’s mission objectives.

This change to the xEVAS contract has no impact on NASA’s spacewalking capabilities on the space station. Collins will continue to support NASA’s EMU (Extravehicular Activity Mobility Unit) spacesuit and is committed to supporting space station’s ongoing spacewalking capabilities through the existing Extravehicular Space Operations Contract.


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 video highlights at: https://roundupreads.jsc.nasa.gov/videoupdate/

Get the latest from NASA delivered every week. Subscribe here: www.nasa.gov/subscribe

Powered by WPeMatico

Get The Details…

Mark Garcia

Cargo, Science, and Spacewalk Preps Fill Station’s Day

Cargo, Science, and Spacewalk Preps Fill Station’s Day

The first rays of an orbital sunrise reflect off the International Space Station's roll-out solar arrays that overshadow and augment the orbital outpost's main solar arrays.
The first rays of an orbital sunrise reflect off the International Space Station’s roll-out solar arrays that overshadow and augment the orbital outpost’s main solar arrays.

Six NASA astronauts aboard the International Space Station had a day filled with cargo packing, orbital plumbing, and a spacewalk conference. The orbital outpost’s three cosmonauts from Roscosmos spent their day testing a 3D printer, collecting microbial air samples, and servicing life support gear.

Expedition 71 Flight Engineers Tracy C. Dyson, Mike Barratt, Matthew Dominick, and Jeanette Epps worked throughout Wednesday packing trash and discarded cargo inside Northrop Grumman’s Cygnus cargo space freighter. Cygnus is targeted to complete a five-and-a-half-month mission in mid-July and depart the station’s Unity module before descending into Earth’s atmosphere for a fiery, but safe disposal above the South Pacific Ocean.

In the midst of the cargo work, Dominick videotaped the location of station hardware stowed in the starboard side of the Columbus laboratory module. Epps swapped sample cartridges inside the Materials Science Laboratory, a research furnace that safely exposes metals, alloys, polymers, and other materials to high temperatures to discover new applications for Earth and space industries. Dyson and Barratt continued spacesuit and tool configurations in the Quest airlock.

At the end of the workday, the four NASA astronauts gathered in the Destiny laboratory module for a video conference with mission controllers on the ground. The quartet called down to the NASA engineers and discussed procedures and readiness for an upcoming spacewalk.

NASA’s Boeing Crew Flight Test astronauts Butch Wilmore and Suni Williams started their morning with exercise sessions before organizing cargo packed inside the Permanent Multipurpose Module. The duo then spent the afternoon working to remove and replace a failed pressure control and pump assembly module that is part of the Tranquility module’s bathroom, or waste and hygiene compartment.

Station Commander Oleg Kononenko from Roscosmos spent all day Wednesday testing a 3D printer and its ability to manufacture space hardware on demand. Flight Engineer Nikolai Chub spent half his day servicing plumbing hardware in the Nauka science module before working out on the advanced resistive exercise device and jogging on a treadmill during the afternoon. Flight Engineer Alexander Grebenkin’s list of duties included collecting more microbial air samples for analysis and maintaining electronics systems.


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 video highlights at: https://roundupreads.jsc.nasa.gov/videoupdate/

Get the latest from NASA delivered every week. Subscribe here: www.nasa.gov/subscribe

Powered by WPeMatico

Get The Details…

Mark Garcia

NASA Selects International Space Station US Deorbit Vehicle

NASA Selects International Space Station US Deorbit Vehicle

NASA logo
NASA logo

NASA is fostering continued scientific, educational, and technological developments in low Earth orbit to benefit humanity, while also supporting deep space exploration at the Moon and Mars. As the agency transitions to commercially owned space destinations closer to home, it is crucial to prepare for the safe and responsible deorbit of the International Space Station in a controlled manner after the end of its operational life in 2030.

NASA announced SpaceX has been selected to develop and deliver the U.S. Deorbit Vehicle that will provide the capability to deorbit the space station and ensure avoidance of risk to populated areas.

“Selecting a U.S. Deorbit Vehicle for the International Space Station will help NASA and its international partners ensure a safe and responsible transition in low Earth orbit at the end of station operations. This decision also supports NASA’s plans for future commercial destinations and allows for the continued use of space near Earth,” said Ken Bowersox, associate administrator for Space Operations Mission Directorate at NASA Headquarters in Washington. “The orbital laboratory remains a blueprint for science, exploration, and partnerships in space for the benefit of all.”

While the company will develop the deorbit spacecraft, NASA will take ownership after development and operate it throughout its mission. Along with the space station, it is expected to destructively breakup as part of the re-entry process.

Since 1998, five space agencies, CSA (Canadian Space Agency), ESA (European Space Agency), JAXA (Japan Aerospace Exploration Agency), NASA (National Aeronautics and Space Administration), and State Space Corporation Roscosmos, have operated the International Space Station with each agency responsible for managing and controlling the hardware it provides. The station was designed to be interdependent and relies on contributions from across the partnership to function. The United States, Japan, Canada, and the participating countries of ESA have committed to operating the station through 2030. Russia has committed to continued station operations through at least 2028. The safe deorbit of the International Space Station is the responsibility of all five space agencies.

The single-award contract has a total potential value of $843 million. The launch service for the U.S. Deorbit Vehicle will be a future procurement.

In its 24th year of continuously crewed operations, the space station is a unique scientific platform where crew members conduct experiments across multiple disciplines of research, including Earth and space science, biology, human physiology, physical sciences, and technology demonstrations not possible on Earth. Crews living aboard station are the hands of thousands of researchers on the ground having conducted more than 3,300 experiments in microgravity. Station is the cornerstone of space commerce, from commercial crew and cargo partnerships to commercial research and national lab research, and lessons learned aboard International Space Station are helping to pass the torch to future commercial stations.

Learn more about space station operations at:

https://www.nasa.gov/station

-end-

Josh Finch
Headquarters, Washington
202-356-1100
joshua.a.finch@nasa.gov

Sandra Jones
Johnson Space Center, Houston
281-483-5111
sandra.p.jones@nasa.gov

Powered by WPeMatico

Get The Details…
Abbey A. Donaldson

40 Years Ago: STS-41D – First Space Shuttle Launch Pad Abort

40 Years Ago: STS-41D – First Space Shuttle Launch Pad Abort

In 1983, NASA received delivery of Discovery, the third space qualified vehicle in the agency’s space shuttle fleet. During the launch attempt for the STS-41D mission on June 26, 1984, Discovery’s onboard computers halted the countdown four seconds before liftoff, and after two of its main engines had already ignited. The six astronauts safely egressed the orbiter. This first on-the-pad abort of the shuttle program required the vehicle’s return to its assembly building for replacement of the faulty engine that caused the shutdown. The resulting two-month delay caused a shuffling of the mission’s payloads, but Discovery finally lifted off on Aug. 30, and the astronauts completed a successful six-day mission, deploying three commercial satellites, testing a new solar array, and conducting a commercial biotechnology experiment.

Space shuttle Discovery rolls out of Rockwell’s Palmdale facility Discovery atop the Shuttle Carrier Aircraft during the cross-country ferry flight Discovery arrives at NASA’s Kennedy Space Center in Florida
Left: Space shuttle Discovery rolls out of Rockwell’s Palmdale facility. Middle: Discovery atop the Shuttle Carrier Aircraft during the cross-country ferry flight. Right: Discovery arrives at NASA’s Kennedy Space Center in Florida.

Discovery rolled out of Rockwell International’s plant in Palmdale, California, on Oct. 16, 1983. Five of the six crew members assigned to its first flight attended the ceremony. Workers trucked Discovery overland from Palmdale to NASA’s Dryden, now Armstrong, Flight Research Center at Edwards Air Force Base (AFB). Discovery arrived at NASA’s Kennedy Space Center (KSC) on Nov. 9 after a cross-country ferry flight from Edwards, following a two-day stopover at Vandenberg Air Force, now Space Force, Base in California, atop the Shuttle Carrier Aircraft, a modified Boeing 747. Discovery, named after several historical ships of exploration, incorporated manufacturing lessons learned from the first orbiters as well as through the use of more advanced materials. The new vehicle weighed nearly 8,000 pounds less than its sister ship Columbia and 700 pounds less than Challenger.

The STS-41D crew patch The STS-41D crew of R. Michael “Mike” Mullane, front row left, Steven A. Hawley, Henry W. “Hank” Hartsfield, and Michael D. Coats; and Charles D. Walker, back row left, and Judith A. Resnik
Left: The STS-41D crew patch. Right: The STS-41D crew of R. Michael “Mike” Mullane, front row left, Steven A. Hawley, Henry W. “Hank” Hartsfield, and Michael D. Coats; and Charles D. Walker, back row left, and Judith A. Resnik.

To fly Discovery’s first flight, originally designated STS-12 and later renamed STS-41D, in February 1983 NASA assigned Commander Henry W. Hartsfield, a veteran of STS-4, and first-time flyers Pilot Michael L. Coats, and Mission Specialists R. Michael Mullane, Steven A. Hawley, and Judith A. Resnik, all from the 1978 class of astronauts. In May 1983, NASA announced the addition of Charles D. Walker, an employee of the McDonnell Douglas Corporation, to the crew, flying as the first commercial payload specialist. He would operate the company’s Continuous Flow Electrophoresis System (CFES) experiment. The mission’s primary payloads included the Leasat-1 (formerly known as Syncom IV-1) commercial communications satellite and OAST-1, three experiments from NASA’s Office of Aeronautics and Space Technology, including the Solar Array Experiment, a 105-foot long lightweight deployable and retractable solar array.

Workers in the Vehicle Assembly Building (VAB) at NASA’s Kennedy Space Center in Florida lift Discovery to mate it with its external tank and solid rocket boosters Initial rollout of Discovery from the VAB to Launch Pad 39A on May 19, 1984 The Flight Readiness Firing on June 2
Left: Workers in the Vehicle Assembly Building (VAB) at NASA’s Kennedy Space Center in Florida lift Discovery to mate it with its external tank and solid rocket boosters. Middle: Initial rollout of Discovery from the VAB to Launch Pad 39A on May 19, 1984. Right: The Flight Readiness Firing on June 2.

The day after its arrival at KSC, workers towed Discovery from the SLF to the Orbiter Processing Facility (OPF) to being preparing it for its first space flight. Between Dec. 9, 1983, and Jan. 10, 1984, it entered temporary storage in the Vehicle Assembly Building (VAB) to allow postflight processing of Columbia in the OPF following STS-9. Workers returned Discovery to the OPF for final processing, towing it to the VAB on May 12 for mating with its External Tank (ET) and Solid Rocket Boosters (SRBs). The completed stack rolled out to Launch Pad 39A on May 19. On June 2, engineers successfully completed an 18-second Flight Readiness Firing of the shuttle main engines. Post test inspections revealed a debonding of a thermal shield in main engine number 1’s combustion chamber, requiring its replacement at the pad. The work pushed the planned launch date back three days to June 25.

The June 26 launch abort Discovery’s three main engines hours after the launch abort
Left: The June 26 launch abort. Right: Discovery’s three main engines hours after the launch abort.

The failure of the shuttle’s backup General Purpose Computer (GPC) caused a one-day delay of the first launch attempt on June 25. On June 26, the countdown proceeded smoothly and at T minus 6.6 seconds the orbiter’s GPCs began the serial ignition sequence of the three main engines. Normally, the three engines ignite at 0.12-second intervals to ease stress on the system and to allow onboard computers to diagnose any problems. Engines number 2 and 3, forming the base of the triangle closest to the body flap, ignited as planned, but engine number 1 at the apex of the triangle and nearest the vertical tail, did not ignite at all. This caused the Redundant Set Launch Sequencer (RSLS) to shut the two working engines down, calling an abort to the countdown at T minus 4 seconds. To ease the tension, Hawley reportedly said, “Gee, I thought we’d be a little higher at main engine cutoff.” The fact that engine number 1 had never ignited caused some momentary confusion as displays showed that the RSLS had not shut it down. A single engine still burning with the shuttle still on the pad would have led to a disaster. Once controllers and the onboard crew realized what had actually happened, they calmed down somewhat. What no one realized at the time is that a hydrogen fire, invisible to the naked eye, had broken out at the aft end of the orbiter. Had the crew evacuated at that time, they would have run through the invisible flames. The pad’s fire suppression system came on to deal with the fire, and when the crew did finally egress the shuttle, they received a good dousing of water. The crew returned safely, if a little drenched, to crew quarters. After ground teams assessed the cause of the abort, they made the decision to roll the stack back to the VAB, demate Discovery from the ET and SRBs and tow it back to the OPF. Workers replaced the faulty engine, and Discovery rolled back out to the launch pad on Aug. 9 for another launch attempt 20 days later, delayed by one day due to a software issue, and finally on Aug. 30, Discovery roared off its launch pad on a pillar of flame and within 8 minutes, NASA’s newest orbiter reached low Earth orbit.

Gemini VI launch pad abort in December 1965 Gemini VI crew of Thomas P. Stafford, left, and Walter M. Schirra
Left: Gemini VI launch pad abort in December 1965. Right: Gemini VI crew of Thomas P. Stafford, left, and Walter M. Schirra.

Although the first on the pad abort of the space shuttle program, the June 1984 attempt to launch Discovery on STS-41D represented the second such incident in the American human spaceflight program. The dubious honor of the first on the pad abort belongs to Gemini VI. On Dec. 12, 1965, astronauts Walter M. Schirra and Thomas P. Stafford strapped into the spacecraft for their second launch attempt to rendezvous with Gemini VII. The countdown clock ticked down to zero, and the Titan-II rocket’s first stage engines ignited. And shut off after just 1.2 seconds. Although the mission clock aboard the spacecraft had started, the rocket had not lifted off, and Schirra made the split-second decision not to eject himself and Stafford from the spacecraft. Engineers later traced the cause of the abort to a dust cap inadvertently left in the engine compartment. After workers took care of that issue, Schirra and Stafford tried to launch again on Dec. 15, and the third time proved to be the charm. 

STS-51F in August 1985 STS-55 in March 1993 STS-51 in August 1993 STS-68 in August 1994
Four space shuttle on-the-pad aborts. STS-51F in August 1985, left, STS-55 in March 1993, STS-51 in August 1993, and STS-68 in August 1994.

In the 10 years following the June 1984 abort, four additional shuttle launch attempts ended with an RSLS abort after at least one main engine had ignited.

July 12, 1985, STS-51F space shuttle Challenger

The RSLS executed a shutdown at T minus 3 seconds, after all three main engines had ignited, because the number two main engine’s chamber coolant valve did not close as rapidly as needed for startup. Investigations revealed a faulty sensor as the real culprit, and workers replaced it at the pad. Challenger launched successfully on July 29, but during ascent engine number 1 shut down, the only inflight failure of a main engine, resulting in the only abort to orbit of the program. Although the shuttle achieved a slightly lower than planned orbit, the mission met most of its science objectives.

March 22, 1993, STS-55 space shuttle Columbia

Following a trouble-free countdown, Columbia’s three main engines came to life at as planned, but three seconds later, the RSLS shut them all down when it detected that engine number 3 had not come up to full power. A tiny fragment of rubber caused a valve in the liquid oxygen system to leak, preventing the engine from fully starting. Columbia borrowed three main engines from Endeavour, and STS-55 took off on April 26 to carry out its German Spacelab-D2 mission.

Aug. 12, 1993, STS-51 space shuttle Discovery

After a trouble-free preflight processing and countdown, Discovery’s three main engines ignited as planned at T minus 6.6 seconds. Three seconds later, all three engines shut down. Investigation revealed the cause as a faulty sensor that monitors fuel flow through main engine number 2. Workers replaced all three engines at the pad, and Discovery took off on Sept. 12 to carry out its mission.

Aug. 18, 1994, STS-68 space shuttle Endeavour

Following a smooth countdown, Endeavour’s three main engines began their startup sequence at T minus 6.6 seconds. The GLS computers detected a problem with the No. 3 main engine’s High Pressure Oxidizer Turbine. One of its sensors detected a dangerously high discharge temperature, exceeding the rules of the Launch Commit Criteria, and Endeavour’s computers halted the countdown a mere 1.9 seconds before liftoff. Workers rolled Endeavour back to the VAB, replacing its three main engines with ones borrowed from Atlantis. STS-68 finally took off on Sept. 30 and successfully completed its radar mapping mission. NASA astronaut Daniel W. Bursch holds the distinction as the only person to have experienced two on-the-pad aborts, as he served as a mission specialist on both STS-51 and STS-68.

The lessons learned from these on-the-pad abort experiences can inform current and future programs. For example, the Space Launch System (SLS) uses main engines leftover from the space shuttle program to power its booster stage. And operationally, other launcher systems can learn from these experiences and safely manage similar future events.

Read recollections of the STS-41D mission by Hartsfield, Coats, Mullane, Hawley, and Walker in their oral histories with the JSC History Office.

Powered by WPeMatico

Get The Details…
Kelli Mars

Detective Work Enables Perseverance Team to Revive SHERLOC Instrument

Detective Work Enables Perseverance Team to Revive SHERLOC Instrument

5 min read

Preparations for Next Moonwalk Simulations Underway (and Underwater)

Imagery captured by a navigation camera aboard NASA’s Perseverance rover on Jan. 23 shows the position of a cover on the SHERLOC instrument. The cover had become stuck several weeks earlier but the rover team has since found a way to address the issue so the instrument can continue to operate.
NASA/JPL-Caltech

After six months of effort, an instrument that helps the Mars rover look for potential signs of ancient microbial life has come back online.

The SHERLOC (Scanning Habitable Environments with Raman & Luminescence for Organics and Chemicals) instrument aboard NASA’s Perseverance Mars rover has analyzed a rock target with its spectrometer and camera for the first time since encountering an issue this past January. The instrument plays a key role in the mission’s search for signs of ancient microbial life on Mars. Engineers at NASA’s Jet Propulsion Laboratory in Southern California confirmed on June 17 that the instrument succeeded in collecting data.

“Six months of running diagnostics, testing, imagery and data analysis, troubleshooting, and retesting couldn’t come with a better conclusion,” said SHERLOC principal investigator Kevin Hand of JPL.

Position of a cover on the SHERLOC instrument
Imagery captured by a navigation camera aboard NASA’s Perseverance rover on Jan. 23 shows the position of a cover on the SHERLOC instrument. The cover had become stuck several weeks earlier but the rover team has since found a way to address the issue so the instrument can continue to operate.
NASA/JPL-Caltech

Mounted on the rover’s robotic arm, SHERLOC uses two cameras and a laser spectrometer to search for organic compounds and minerals in rocks that have been altered in watery environments and may reveal signs of past microbial life. On Jan. 6, a movable lens cover designed to protect the instrument’s spectrometer and one of its cameras from dust became frozen in a position that prevented SHERLOC from collecting data.

Analysis by the SHERLOC team pointed to the malfunction of a small motor responsible for moving the protective lens cover as well as adjusting focus for the spectrometer and the Autofocus and Context Imager (ACI) camera. By testing potential solutions on a duplicate SHERLOC instrument at JPL, the team began a long, meticulous evaluation process to see if, and how, the lens cover could be moved into the open position.

SHERLOC instrument’s Autofocus and Context Imager to capture this image of its calibration target
Perseverance’s team used the SHERLOC instrument’s Autofocus and Context Imager to capture this image of its calibration target on May 11 to confirm an issue with a stuck lens cover had been resolved. A silhouette of the fictional detective Sherlock Holmes is at the center of the target.
NASA/JPL-Caltech

SHERLOC Sleuthing

Among many other steps taken, the team tried heating the lens cover’s small motor, commanding the rover’s robotic arm to rotate the SHERLOC instrument under different orientations with supporting Mastcam-Z imagery, rocking the mechanism back and forth to loosen any debris potentially jamming the lens cover, and even engaging the rover’s percussive drill to try jostling it loose. On March 3, imagery returned from Perseverance showed that the ACI cover had opened more than 180 degrees, clearing the imager’s field of view and enabling the ACI to be placed near its target.

“With the cover out of the way, a line of sight for the spectrometer and camera was established. We were halfway there,” said Kyle Uckert, SHERLOC deputy principal investigator at JPL. “We still needed a way to focus the instrument on a target. Without focus, SHERLOC images would be blurry and the spectral signal would be weak.”

Like any good ophthalmologist, the team set about figuring out SHERLOC’s prescription. Since they couldn’t adjust the focus of the instrument’s optics, they relied on the rover’s robotic arm to make minute adjustments in the distance between SHERLOC and its target in order to get the best image resolution. SHERLOC was commanded to take pictures of its calibration target so that the team could check the effectiveness of this approach.

NASA’s Perseverance rover gathering data on the “Walhalla Glades” abrasion
This image of NASA’s Perseverance rover gathering data on the “Walhalla Glades” abrasion was taken in the “Bright Angel” region of Jezero Crater by one of the rover’s front hazard avoidance cameras on June 14. The WATSON camera on the SHERLOC instrument is closest to the Martian surface.
NASA/JPL-Caltech

“The rover’s robotic arm is amazing. It can be commanded in small, quarter-millimeter steps to help us evaluate SHERLOC’s new focus position, and it can place SHERLOC with high accuracy on a target,” said Uckert. “After testing first on Earth and then on Mars, we figured out the best distance for the robotic arm to place SHERLOC is about 40 millimeters,” or 1.58 inches. “At that distance, the data we collect should be as good as ever.”

Confirmation of that fine positioning of the ACI on a Martian rock target came down on May 20. The verification on June 17 that the spectrometer is also functional checked the team’s last box, confirming that SHERLOC is operational.

“Mars is hard, and bringing instruments back from the brink is even harder,” said Perseverance project manager Art Thompson of JPL. “But the team never gave up. With SHERLOC back online, we’re continuing our explorations and sample collection with a full complement of science instruments.”

Perseverance is in the later stages of its fourth science campaign, looking for evidence of carbonate and olivine deposits in the “Margin Unit,” an area along the inside of Jezero Crater’s rim. On Earth, carbonates typically form in the shallows of freshwater or alkaline lakes. It’s hypothesized that this also might be the case for the Margin Unit, which formed over 3 billion years ago.

 

More About the Mission

A key objective of Perseverance’s mission on Mars is astrobiology, including caching samples that may contain signs of ancient microbial life. The rover will characterize the planet’s geology and past climate, pave the way for human exploration of the Red Planet, and be the first mission to collect and cache Martian rock and regolith.

Subsequent NASA missions, in cooperation with ESA (European Space Agency), would send spacecraft to Mars to collect these sealed samples from the surface and return them to Earth for in-depth analysis.

The Mars 2020 Perseverance mission is part of NASA’s Moon to Mars exploration approach, which includes Artemis missions to the Moon that will help prepare for human exploration of the Red Planet.

NASA’s Jet Propulsion Laboratory, which is managed for the agency by Caltech, built and manages operations of the Perseverance rover.

For more about Perseverance:

science.nasa.gov/mission/mars-2020-perseverance

News Media Contacts

DC Agle
Jet Propulsion Laboratory, Pasadena, Calif.
818-393-9011
agle@jpl.nasa.gov

Karen Fox / Charles Blue
NASA Headquarters
202-385-1600 / 202-802-5345
karen.c.fox@nasa.gov / charles.e.blue@nasa.gov

2024-091

Share

Details

Last Updated

Jun 26, 2024

Powered by WPeMatico

Get The Details…
Anthony Greicius