View allAll Photos Tagged SpaceLaunchSystem
Artemis I Launch Director Charlie Blackwell-Thompson monitors launch countdown events inside Firing Room 1 of the Rocco A. Petrone Launch Control Center at NASA’s Kennedy Space Center in Florida on Aug. 29, 2022. Launch of the agency’s Space Launch System and Orion spacecraft was waved off due to an issue during tanking. Launch is now no earlier than Sept. 3, at 2:17 p.m. EDT from Kennedy’s Launch Complex 39B. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown. Photo credit: NASA/Kim Shiflett
NASA astronauts and astronaut candidates view NASA’s Artemis I Space Launch System and Orion spacecraft atop the mobile launcher on the pad at Launch Complex 39B at the agency’s Kennedy Space Center in Florida on Sept. 2, 2022. The astronauts are, from left to right: Victor Glover, NASA astronaut; Marcos Berrios, NASA astronaut candidate; Anne McClain, NASA astronaut; Anil Menon and Deniz Burnham, NASA astronaut candidates; and Zena Cardman, NASA astronaut. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown. 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/Steven Seipel
The NASA Photo Social at NASA’s Michoud Assembly Facility (MAF) in New Orleans, Louisiana, gathered social media-savvy photographers together on August 16 and 17 to snap and share photos of the facility where NASA is building components for its deep space rocket, the Space Launch System, and crew vehicle, the Orion spacecraft. NASA Michoud is a world-class facility that is unique because it is one of the largest production buildings in the nation with a rich history of manufacturing excellence.
Image Credit: NASA/Steven Seipel
From left, Artemis I Launch Director Charlie Blackwell-Thompson, and Assistant Launch Director Jeremy Graeber, monitor launch countdown events inside Firing Room 1 of the Rocco A. Petrone Launch Control Center at NASA’s Kennedy Space Center in Florida on Aug. 29, 2022. Launch of the agency’s Space Launch System and Orion spacecraft was waved off due to an issue during tanking. Launch is now no earlier than Sept. 3, at 2:17 p.m. EDT from Kennedy’s Launch Complex 39B. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown. Photo credit: NASA/Kim Shiflett
Members of the Artemis I launch team are at their consoles inside Firing Room 1 of the Rocco A. Petrone Launch Control Center at NASA’s Kennedy Space Center in Florida for launch countdown Aug. 29, 2022. Launch of the agency’s Space Launch System and Orion spacecraft was waved off due to an issue during tanking. Launch is now no earlier than Sept. 3, at 2:17 p.m. EDT from Kennedy’s Launch Complex 39B. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown. Photo credit: NASA/Kim Shiflett
NASA commentator Derrol Nail, at left, talks with NASA Administrator Bill Nelson during the Artemis I launch countdown inside Firing Room 1 of the Rocco A. Petrone Launch Control Center at NASA’s Kennedy Space Center in Florida on Aug. 29, 2022. Launch of the agency’s Space Launch System and Orion spacecraft was waved off due to an issue during tanking. Launch is now no earlier than Sept. 3, at 2:17 p.m. EDT from Kennedy’s Launch Complex 39B. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown. Photo credit: NASA/Kim Shiflett
John Nesworthy, crawler-transporter/mobile launcher systems mechanical technician, Jacobs Engineering, looks on as NASA’s Space Launch System (SLS) and Orion spacecraft rolls out of the Vehicle Assembly Building’s High Bay 3 to Launch Complex 39B on Tuesday, Aug. 16, 2022, at NASA’s Kennedy Space Center in Florida. The agency’s Artemis I flight test is scheduled to liftoff on Monday, Aug. 29. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by launching Orion atop the SLS rocket, operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown. Photo credit: NASA/Ben Smegelsky
Hello Lego friends,
A new era of human space exploration for NASA dawns with the Space Launch System, or SLS. This super heavy-lift launch vehicle will take the Orion spacecraft and its crew of up to four astronauts beyond Earth’s orbit, enabling missions to the Moon, Mars and deep-space destinations.
Designed to reach a record-breaking speed of Mach 23 and rated for payloads of 26 metric tons, this variant will complete the first three Artemis Lunar missions.
At 1:110 scale, our product idea includes a total of 2020 Lego bricks and has three key sections.
Core stage
•Four RS-25 engines.
•External fuel line.
•Two solid boosters.
•Launch vehicle stage adaptor.
•1,953 bricks and 30 decals.
•Diameter: 10 studs, 8 cm or 3.14 inches.
•Rocket & Boosters width: 19 studs, 15.2 cm or 2.04 inches.
•Height: 126 studs, 100.8 cm or 39.68 inches.
•
Orion Crew Vehicle
•Crew module.
•Service module - with collapsed and extended solar arrays.
•Launch abort system.
•Interim Cryogenic Propulsion Stage.
•71 bricks and 19 decals.
•Diameter: 4 studs, 3.2 cm or 1.25 inches.
•Height: 15 studs, 12 cm or 4.72 inches.
•Wingspan: 15 studs, 12 cm or 4.72 inches.
Optional Display Stand
•Displays SLS ready for launch at Kennedy Space Center’s Pad 39B.
•222 bricks.
•Width: 24 studs, 19.2 cm or 7.55 inches.
•Length: 28 studs, 22.4 cm or 8.81 inches.
•Height: 10 studs, 8 cm or 3.14 inches.
This collaborative project was created by Saturn V co-designer Valerie Roche (Whatsuptoday) and her SpaceX Collection/ Starship & New Glenn Co-Designer Matthew Nolan, along with co-designer of SpaceX Starship Mark Nolan.
Please, visite our Lego Ideas project: ideas.lego.com/projects/e72800b7-14d6-40b4-b9f1-d9a60efc9e45
Have it fun and enjoy it!
Marcie Nolan, Matthew Nolan & Valérie Roche
The core stage for NASA's first Artemis mission to the Moon moved to the agency’s Pegasus barge on Jan. 8, 2020. The 212-foot Space Launch System rocket stage, built by NASA and lead contractor Boeing at NASA's Michoud Assembly Facility, rolled the onto Pegasus, which shipped it to NASA's Stennis Space Center on Jan. 12. Here, it will undergo a comprehensive series of engineering tests called the Green Run. After Green Run is complete, the core stage will be sent to NASA's Kennedy Space Center, where it will join with SLS's giant boosters and the Orion spacecraft to launch into space on Artemis I.
Image credit: NASA
A liquid oxygen tank confidence article for NASA's new rocket, the Space Launch System, completes final welding on the Vertical Assembly Center at Michoud Assembly Facility in New Orleans.
A liquid oxygen tank confidence article for NASA's new rocket, the Space Launch System, completes final welding on the Vertical Assembly Center at Michoud Assembly Facility in New Orleans.
_______________________________
These official NASA photographs are being made available for publication by news organizations and/or for personal use printing by the subject(s) of the photographs. The photographs may not be used in materials, advertisements, products, or promotions that in any way suggest approval or endorsement by NASA. All Images used must be credited. For information on usage rights please visit: www.nasa.gov/audience/formedia/features/MP_Photo_Guidelin...
NASA’s Space Launch System standing tall at LC-39B, scheduled to send the Orion spacecraft to the Moon Monday, August 29. The 2-hour launch window for the #Artemis I mission opens at 8:33am (EDT)
#WeAreGoing
The structural test article adapter is flipped at Marshall testing facility Building 4705. The turnover is an important step in finishing the machining work on the hardware. (NASA/MSFC)
More about SLS:
More SLS graphics and concepts:
www.nasa.gov/exploration/systems/sls/multimedia/gallery/S...
Space Launch System Flickr album
www.flickr.com/photos/28634332@N05/sets/72157627559536895/
________________________________
These official NASA photographs are being made available for publication by news organizations and/or for personal use printing by the subject(s) of the photographs. The photographs may not be used in materials, advertisements, products, or promotions that in any way suggest approval or endorsement by NASA. All Images used must be credited. For information on usage rights please visit: www.nasa.gov/audience/formedia/features/MP_Photo_Guidelin...
Hello Lego friends,
A new era of human space exploration for NASA dawns with the Space Launch System, or SLS. This super heavy-lift launch vehicle will take the Orion spacecraft and its crew of up to four astronauts beyond Earth’s orbit, enabling missions to the Moon, Mars and deep-space destinations.
Designed to reach a record-breaking speed of Mach 23 and rated for payloads of 26 metric tons, this variant will complete the first three Artemis Lunar missions.
At 1:110 scale, our product idea includes a total of 2020 Lego bricks and has three key sections.
Core stage
•Four RS-25 engines.
•External fuel line.
•Two solid boosters.
•Launch vehicle stage adaptor.
•1,953 bricks and 30 decals.
•Diameter: 10 studs, 8 cm or 3.14 inches.
•Rocket & Boosters width: 19 studs, 15.2 cm or 2.04 inches.
•Height: 126 studs, 100.8 cm or 39.68 inches.
•
Orion Crew Vehicle
•Crew module.
•Service module - with collapsed and extended solar arrays.
•Launch abort system.
•Interim Cryogenic Propulsion Stage.
•71 bricks and 19 decals.
•Diameter: 4 studs, 3.2 cm or 1.25 inches.
•Height: 15 studs, 12 cm or 4.72 inches.
•Wingspan: 15 studs, 12 cm or 4.72 inches.
Optional Display Stand
•Displays SLS ready for launch at Kennedy Space Center’s Pad 39B.
•222 bricks.
•Width: 24 studs, 19.2 cm or 7.55 inches.
•Length: 28 studs, 22.4 cm or 8.81 inches.
•Height: 10 studs, 8 cm or 3.14 inches.
This collaborative project was created by Saturn V co-designer Valerie Roche (Whatsuptoday) and her SpaceX Collection/ Starship & New Glenn Co-Designer Matthew Nolan, along with co-designer of SpaceX Starship Mark Nolan.
Please, visite our Lego Ideas project: ideas.lego.com/projects/e72800b7-14d6-40b4-b9f1-d9a60efc9e45
Have it fun and enjoy it!
Marcie Nolan, Matthew Nolan & Valérie Roche
As Olympic athletes converge on London with dreams of winning gold in the 2012 Summer Olympic Games, NASA is also setting records while testing the J-2X powerpack at the Stennis Space Center. The first time was June 8, when engineers went the distance and set the Test Complex A record with a 1,150-second firing of the developmental powerpack assembly. On July 24, engineers surpassed that record with a 1,350-second test of the engine component on the A-1 Test Stand at Stennis. The powerpack is a system of components on the top portion of the J-2X engine. On the complete J-2X engine, the powerpack feeds the thrust chamber, which produces the engine fire and thrust. The advantage of testing the powerpack without the thrust chamber is to operate over a wide range of conditions to understand safe limits.
The July 24 test specifically gathered data on performance of the liquid oxygen and fuel pumps during extreme conditions. The test data provides critical information for continued development of the turbopump for use on the J-2X engine, the first human-rated liquid oxygen and liquid hydrogen rocket engine to be developed in four decades. The J-2X is being built by Pratt & Whitney Rocketdyne for NASA’s Marshall Space Flight Center in Huntsville, Ala.
The J-2X engine will power the upper-stage of a planned two-stage Space Launch System, or SLS. The SLS will launch NASA's Orion spacecraft and other payloads, and provide an entirely new capability for human exploration beyond low Earth orbit. Designed to be safe, affordable and flexible for crew and cargo missions, the SLS will continue America's journey of discovery and exploration to destinations including nearby asteroids, Lagrange points, the moon and ultimately, Mars.
Credit: NASA/SSC
View NASA feature:
www.nasa.gov/exploration/systems/sls/j2x/pp_july24_1.html
More about the J-2X Engine Development:
There's a Flickr photoset about the J-2X egnine development, if you'd like to know more: www.flickr.com/photos/28634332@N05/sets/72157625345364038/
_____________________________________________
These official NASA photographs are being made available for publication by news organizations and/or for personal use printing by the subject(s) of the photographs. The photographs may not be used in materials, advertisements, products, or promotions that in any way suggest approval or endorsement by NASA. All Images used must be credited. For information on usage rights please visit: www.nasa.gov/audience/formedia/features/MP_Photo_Guidelin...
The J-2X powerpack assembly was fired up one last time on Dec. 13 at NASA's Stennis Space Center in Mississippi, finishing a year of testing on an important component of America's next heavy-lift rocket. The powerpack assembly burned millions of pounds of propellants during a series of 13 tests during 2012 totaling more than an hour and a half. NASA engineers will remove the assembly from the test stand to focus on tests of the fully integrated engine. Installation on a test stand at Stennis will begin in 2013. The powerpack is a system of components on top of the engine that feeds propellants to the bell nozzle of the engine to produce thrust. The J-2X engine, designed and built by NASA and industry partner Pratt & Whitney Rocketdyne of Canoga Park, Calif., will power the upper stage of the 143-ton (130-metric-ton) Space Launch System (SLS) rocket. The SLS will launch NASA's Orion spacecraft and other payloads from the agency's Kennedy Space Center in Florida, providing an entirely new capability for human exploration beyond low Earth orbit. The program is managed at the Marshall Space Flight Center in Huntsville, Ala.
Image credit: NASA/SSC
View original image/caption:
www.nasa.gov/exploration/systems/sls/j2x/ppt_dec13_1.html
More about the J-2X Engine Development:
There's a Flickr photoset about the J-2X egnine development, if you'd like to know more: www.flickr.com/photos/28634332@N05/sets/72157625345364038/
_____________________________________________
These official NASA photographs are being made available for publication by news organizations and/or for personal use printing by the subject(s) of the photographs. The photographs may not be used in materials, advertisements, products, or promotions that in any way suggest approval or endorsement by NASA. All Images used must be credited. For information on usage rights please visit: www.nasa.gov/audience/formedia/features/MP_Photo_Guidelin...
Machinists at NASA's Marshall Space Flight Center use a state-of-the-art milling tool to create the pathfinder version of the adapter hardware design. (NASA/MSFC/Emmett Given)
More about SLS:
More SLS graphics and concepts:
www.nasa.gov/exploration/systems/sls/multimedia/gallery/S...
Space Launch System Flickr album
www.flickr.com/photos/28634332@N05/sets/72157627559536895/
________________________________
These official NASA photographs are being made available for publication by news organizations and/or for personal use printing by the subject(s) of the photographs. The photographs may not be used in materials, advertisements, products, or promotions that in any way suggest approval or endorsement by NASA. All Images used must be credited. For information on usage rights please visit: www.nasa.gov/audience/formedia/features/MP_Photo_Guidelin...
The NASA Photo Social at NASA’s Michoud Assembly Facility (MAF) in New Orleans, Louisiana, gathered social media-savvy photographers together on August 16 and 17 to snap and share photos of the facility where NASA is building components for its deep space rocket, the Space Launch System, and crew vehicle, the Orion spacecraft. NASA Michoud is a world-class facility that is unique because it is one of the largest production buildings in the nation with a rich history of manufacturing excellence.
Image Credit: NASA/Steven Seipel
The last time humans flew to the Moon was December, 1972 - 53 years ago. This (Saturday) morning, NASA took one step closer to reseting that clock.
At 7am (ET), the Mobile Launcher emerged from the the VAB and the Artemis II SLS and Orion spacecraft began the trip to LC-39B.
NASA Administrator Jared Isaacman was on hand to introduce the Artemis II crew, Commander Reid Wiseman, Pilot Victor Glover, and Mission Specialists Christina Koch and Jeremy Hansen, heroes all.
These are some seriously cool astronauts, all well-prepared and looking forward to an incredible journey to the Moon.
One postscript: Administrator Isaacman did a great job at the podium, keeping the focus on the astronauts and the thousands of people supporting the mission; and the astronauts seem to genuinely respect him and his spaceflight experience.
A view from high above in the Vehicle Assembly Building at NASA's Kennedy Space Center in Florida, shows a 325-ton crane lifting the first half of the K-level work platforms up for installation in High Bay 3. The platform will be secured into position on tower E, about 86 feet above the floor. The K work platforms will provide access to NASA's Space Launch System (SLS) core stage and solid rocket boosters during processing and stacking operations on the mobile launcher. The Ground Systems Development and Operations Program is overseeing upgrades and modifications to High Bay 3 to support processing of the SLS and Orion spacecraft. A total of 10 levels of new platforms, 20 platform halves altogether, will surround the SLS rocket and Orion spacecraft and provide access for testing and processing. Photo credit: NASA/Glen Benson
On September 8, 2018, the ML moved into High Bay 3 in NASA's Vehicle Assembly Building, where it will stay 7 months for fit tests. (Pics: Michael Seeley / We Report Space)
Arthur Howard, senior Safety console operator with Jacobs, NASA's Test and Operations Support Contractor, monitors operations from his position in Firing Room 1 at the Kennedy Space Center's Launch Control Center during a terminal countdown demonstration for Exploration Mission 1. Taking place on Dec. 14, 2018, the countdown demonstration was intended to validate the launch team's capability to perform an EM-1 countdown and respond to challenges put into the system for practice.
Photo credit: NASA/Frank Michaux
On March 4, crews sign a 900-pound steel beam that "topped out" Test Stand 4697, which is under construction to test the Space Launch System liquid oxygen tank at NASA's Marshall Space Flight Center. SLS will be the world's most powerful rocket and carry astronauts in NASA's Orion spacecraft on deep-space missions, including the journey to Mars. "Topping out" is a builders' rite traditionally held when the last beam is placed on top of a structure during its construction. The 85-foot-tall test stand will use hydraulic cylinders to subject the liquid oxygen tank and hardware of the massive SLS core stage to the same loads and stresses it will endure during a launch. The tests also will verify the models already in place that predict the amount of loads the core stage can withstand during launch and ascent. (NASA/MSFC/Emmett Given)
More SLS Photos:
www.nasa.gov/exploration/systems/sls/multimedia/gallery/S...
Space Launch System Flickr photoset:
www.flickr.com/photos/28634332@N05/sets/72157627559536895/
#JourneyToMars #NASAMarshall #SLS
_______________________________
These official NASA photographs are being made available for publication by news organizations and/or for personal use printing by the subject(s) of the photographs. The photographs may not be used in materials, advertisements, products, or promotions that in any way suggest approval or endorsement by NASA. All Images used must be credited. For information on usage rights please visit: www.nasa.gov/audience/formedia/features/MP_Photo_Guidelin...
LS
NASA Deputy Administrator Dr. Dava J. Newman takes the stage for a few questions with participants of the NASA Social.
A 325-ton crane lifts the first half of the K-level work platforms high up in High Bay 4 inside the Vehicle Assembly Building at NASA's Kennedy Space Center in Florida. The platform will be lifted over the transfer aisle that runs down the center of the VAB and lower it into High Bay 3. It will be secured into position on tower E, about 86 feet above the floor. The K work platforms will provide access to NASA's Space Launch System (SLS) core stage and solid rocket boosters during processing and stacking operations on the mobile launcher. The Ground Systems Development and Operations Program is overseeing upgrades and modifications to High Bay 3 to support processing of the SLS and Orion spacecraft. A total of 10 levels of new platforms, 20 platform halves altogether, will surround the SLS rocket and Orion spacecraft and provide access for testing and processing. Photo credit: NASA/Ben Smegelsky
A 325-ton crane has lifted the first half of the K-level work platforms up and out of High Bay 4 inside the Vehicle Assembly Building at NASA's Kennedy Space Center in Florida. The platform is being moved over the transfer aisle that runs down the center of the VAB and will be lowered into High Bay 3. It will be secured into position on tower E, about 86 feet above the floor. The K work platforms will provide access to NASA's Space Launch System (SLS) core stage and solid rocket boosters during processing and stacking operations on the mobile launcher. The Ground Systems Development and Operations Program is overseeing upgrades and modifications to High Bay 3 to support processing of the SLS and Orion spacecraft. A total of 10 levels of new platforms, 20 platform halves altogether, will surround the SLS rocket and Orion spacecraft and provide access for testing and processing. Photo credit: NASA/Ben Smegelsky
NASA Spacecraft Hardware Delivered to Marshall in Preparation for 2014 Orion Test Launch.
Orion's stage adapter diaphragm was delivered from a manufacturing facility at Janicki Industries in Hamilton, Washington, to the Marshall Center. The diaphragm will be used to keep launch vehicle gases away from the Orion spacecraft during its test flight. (NASA/MSFC)
More about SLS:
More SLS graphics and concepts:
www.nasa.gov/exploration/systems/sls/multimedia/gallery/S...
Space Launch System Flickr album
www.flickr.com/photos/28634332@N05/sets/72157627559536895/
________________________________
These official NASA photographs are being made available for publication by news organizations and/or for personal use printing by the subject(s) of the photographs. The photographs may not be used in materials, advertisements, products, or promotions that in any way suggest approval or endorsement by NASA. All Images used must be credited. For information on usage rights please visit: www.nasa.gov/audience/formedia/features/MP_Photo_Guidelin...
Boeing engineer Tony Castilleja works on the CST-100 Starliner, which will provide NASA with transportation to and from the International Space Station.
WATCH Tony talk about what inspired him to become a rocket engineer - www.boeing.com/principles/education/students-families.pag...
A technician at the Marshall Center applies the finishing touches on the stage adapter. The top coat for the adapter is a special paint that protects the hardware and its components, like sensors, from electrical discharge on ascent. (NASA/MSFC)
More about SLS:
More SLS graphics and concepts:
www.nasa.gov/exploration/systems/sls/multimedia/gallery/S...
Space Launch System Flickr album
www.flickr.com/photos/28634332@N05/sets/72157627559536895/
________________________________
These official NASA photographs are being made available for publication by news organizations and/or for personal use printing by the subject(s) of the photographs. The photographs may not be used in materials, advertisements, products, or promotions that in any way suggest approval or endorsement by NASA. All Images used must be credited. For information on usage rights please visit: www.nasa.gov/audience/formedia/features/MP_Photo_Guidelin...
Employees at the Marshall Space Flight Center in Huntsville, Ala., unpack four large metal rings that will be used to create adapters for NASA's Orion spacecraft to integrate with the propulsion elements for flight. The rings were forged at Major Tool and Machine in Indianapolis, Ind., for NASA's Space Launch System Program, managed at the Marshall Center.
Image credit: NASA/MSFC
Original image:
www.nasa.gov/exploration/systems/sls/multimedia/gallery/a...
More about SLS:
www.nasa.gov/exploration/systems/sls/index.html
Space Launch System Flickr photoset:
www.flickr.com/photos/28634332@N05/sets/72157627559536895/
_____________________________________________
These official NASA photographs are being made available for publication by news organizations and/or for personal use printing by the subject(s) of the photographs. The photographs may not be used in materials, advertisements, products, or promotions that in any way suggest approval or endorsement by NASA. All Images used must be credited. For information on usage rights please visit: www.nasa.gov/audience/formedia/features/MP_Photo_Guidelin...
Stennis Space Center engineers and technicians install the J-2X powerpack into the A-1 test stand in preparation for testing Dec. 5.
For engineers working on the J-2X engine program, installation of the upgraded J-2X powerpack on the A-1 Test Stand on Dec. 5 had to feel like a long-awaited holiday gift.
The powerpack consists of a gas generator and turbopumps and is a critical component for the new engine. It is responsible for pumping liquid hydrogen and liquid oxygen into the engine’s main combustion chamber to produce the needed thrust capability. Arrival and installation of the next-generation engine component marked the culmination of more than two years of extensive modification work to prepare the A-1 stand for the critical test series. The major work effort began after NASA engineers completed an initial series of tests on a heritage J-2 engine powerpack in mid-2008.
Read the NASA Web feature:
www.nasa.gov/mission_pages/j2x/11-152.html
Image credit: NASA/SSC
More about the J-2X Engine Development:
There's a Flickr photoset about the J-2X egnine development, if you'd like to know more: www.flickr.com/photos/28634332@N05/sets/72157625345364038/
_____________________________________________
These official NASA photographs are being made available for publication by news organizations and/or for personal use printing by the subject(s) of the photographs. The photographs may not be used in materials, advertisements, products, or promotions that in any way suggest approval or endorsement by NASA. All Images used must be credited. For information on usage rights please visit: www.nasa.gov/audience/formedia/features/MP_Photo_Guidelin...
Media and social media followers had an invitation to watch as NASA tested the RS-25 engine like those that will power the rocket that launches astronauts on missions to an asteroid and to Mars. The test took place on Thursday, August 13, at NASA’s Stennis Space Center in Mississippi. Panel on stage from left to right: Steve Wofford - NASA SLS Engines Mananger at Marshall, Julie Van Kleek - VP Advanced Space & Launch Business Unit for Aerojet Rocketdyne, Ronnie Rigney - RS25 Test Project Manager at Stennis.
A 6-foot-tall model of NASA's Space Launch System – which is managed at the Marshall Space Flight Center -- stands near the space shuttle Atlantis as the orbiter makes its final voyage on Nov. 2, 2012, rolling from the Kennedy Space Center's orbiter processing facility to its permanent home at Kennedy's visitor's center. Thousands of people from across the country and as far away as New Zealand, Europe and South America were on hand for the "Atlantis Rollover" celebration Nov. 2-4, and were given the opportunity to learn about the Space Launch System.
Image credit: NASA/KSC
More about SLS:
www.nasa.gov/exploration/systems/sls/index.html
Space Launch System Flickr photoset:
www.flickr.com/photos/28634332@N05/sets/72157627559536895/
_____________________________________________
These official NASA photographs are being made available for publication by news organizations and/or for personal use printing by the
subject(s) of the photographs. The photographs may not be used in materials, advertisements, products, or promotions that in any way suggest
approval or endorsement by NASA. All Images used must be credited. For information on usage rights please visit: www.nasa.gov/audience/formedia/features/MP_Photo_Guidelin...
A 325-ton crane has lifted the first half of the K-level work platforms up and out of High Bay 4 inside the Vehicle Assembly Building at NASA's Kennedy Space Center in Florida. The platform is being moved across the transfer aisle that runs down the center of the VAB and will be lowered into High Bay 3. It will be secured into position on tower E, about 86 feet above the floor. The K work platforms will provide access to NASA's Space Launch System (SLS) core stage and solid rocket boosters during processing and stacking operations on the mobile launcher. The Ground Systems Development and Operations Program is overseeing upgrades and modifications to High Bay 3 to support processing of the SLS and Orion spacecraft. A total of 10 levels of new platforms, 20 platform halves altogether, will surround the SLS rocket and Orion spacecraft and provide access for testing and processing. Photo credit: NASA/Ben Smegelsky
After successfully arriving at Kennedy Space Center’s Launch Complex 39B, Exploration Ground Systems’ mobile launcher continues its journey atop crawler-transporter 2 up to the pad surface on June 28, 2019. The mobile launcher began its final solo trek to the pad at midnight on June 27, departing from NASA’s Vehicle Assembly Building. The mobile launcher will remain at the pad over the summer, undergoing final testing and checkouts. Its next roll to the pad will be with the agency’s Space Launch System rocket and Orion in preparation for the launch of Artemis 1. Photo credit: NASA/Ben Smegelsky
Construction workers with JP Donovan assist with preparations to lift and install the Interim Cryogenic Propulsion Stage Umbilical on the tower of the mobile launcher at NASA's Kennedy Space Center in Florida. The last of the large umbilicals to be installed, the ICPSU will provide super-cooled hydrogen and liquid oxygen to the Space Launch System (SLS) rocket's interim cryogenic propulsion stage, or upper stage, at T-0 for Exploration Mission-1. The umbilical is located at about the 240-foot-level of the mobile launcher and will supply fuel, oxidizer, gaseous helium, hazardous gas leak detection, electrical commodities and environment control systems to the upper stage of the SLS rocket during launch. Exploration Ground Systems is overseeing installation of the umbilicals on the ML. Photo credit: NASA/Ben Smegelsky
The NASA/Boeing team works on setting up the avionics system in flight configuration in the Systems Integration and Test Facility at NASA's Marshall Space Flight Center. The units, which have powered up successfully and will undergo testing, will guide the most powerful rocket ever built -- NASA's Space Launch System.
Boeing provides this photo for the public to share. Media interested in high-resolution images for publication should email boeingmedia@boeing.com or visit boeing.mediaroom.com. Users may not manipulate or use this photo in commercial materials, advertisements, emails, products, or promotions without licensed permission from Boeing. If you are interested in using Boeing imagery for commercial purposes, email imagelicensing@boeing.com or visit www.boeingimages.com.
In High Bay 3 inside the Vehicle Assembly Building at NASA's Kennedy Space Center in Florida, preparations are underway to lift the first half of the K-level work platforms for NASA's Space Launch System (SLS). A 325-ton crane will lift the platform up so it can be installed about 86 feet above the floor. The K work platforms will provide access to the SLS core stage and solid rocket boosters during processing and stacking operations on the mobile launcher. The Ground Systems Development and Operations Program is overseeing upgrades and modifications to High Bay 3 to support processing of the SLS and Orion spacecraft. A total of 10 levels of new platforms, 20 platform halves altogether, will surround the SLS rocket and Orion spacecraft and provide access for testing and processing. Photo credit: NASA/Glen Benson
The team at NASA’s Kennedy Space Center in Florida, USA, unboxed ESA’s third European Service Module earlier this week. This powerhouse, boasting 33 engines, is destined for the Artemis III mission, where it will provide life support for the astronauts and propel NASA’s Orion spacecraft in deep space. The module was built with contributions from over 20 companies across more than 10 European countries.
During this summer, the European Service Module left the integration halls of Airbus in Bremen, Germany and sailed across the Atlantic Ocean on board Canopée, the world’s first hybrid wind-powered commercial cargo vessel. Eleven days later, the ship and its precious cargo arrived safely in Port Canaveral, ready to meet the other modules of the NASA Orion spacecraft that will carry astronauts back towards the Moon.
In the next weeks, engineers will connect the third European Service Module with the Crew Module Adapter to form the complete service module of the Orion vehicle. ESA’s second European Service Module underwent the same process last year; it is now connected to its crew module and is in the later stages of testing ahead of the Artemis II mission next year.
Credits: NASA
Eric Corder, right, avionics system manager at NASA's Marshall Space Flight Center in Huntsville, Ala., talks about NASA's Space Launch System (SLS) booster avionics system at ATK's Clearfield, Utah, lab. The avionics system is responsible for igniting, steering and jettison of the two, five-segment solid rocket boosters for the SLS. ATK is the prime contractor for the SLS boosters. Marshall manages the SLS Program for the agency.
Image credit: ATK
Original image:
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These official NASA photographs are being made available for publication by news organizations and/or for personal use printing by the subject(s) of the photographs. The photographs may not be used in materials, advertisements, products, or promotions that in any way suggest approval or endorsement by NASA. All Images used must be credited. For information on usage rights please visit: www.nasa.gov/audience/formedia/features/MP_Photo_Guidelin...
A liquid oxygen tank confidence article for NASA's new rocket, the Space Launch System, completes final welding on the Vertical Assembly Center at Michoud Assembly Facility in New Orleans.
A liquid oxygen tank confidence article for NASA's new rocket, the Space Launch System, completes final welding on the Vertical Assembly Center at Michoud Assembly Facility in New Orleans.
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These official NASA photographs are being made available for publication by news organizations and/or for personal use printing by the subject(s) of the photographs. The photographs may not be used in materials, advertisements, products, or promotions that in any way suggest approval or endorsement by NASA. All Images used must be credited. For information on usage rights please visit: www.nasa.gov/audience/formedia/features/MP_Photo_Guidelin...
In this image:
NASASocial participants pose for a group photo in front of an RS-25 engine in Aerojet Rocketdyne's Engine Assembly Facility at SSC.
More about the Vertical Assembly Center:
The largest spacecraft welding tool in the world, the Vertical Assembly Center officially is open for business at NASA's Michoud Assembly Facility in New Orleans. The 170-foot-tall, 78-foot-wide giant completes a world-class welding toolkit that will be used to build the core stage of America's next great rocket, the Space Launch System (SLS).
SLS will be the most powerful rocket ever built for deep space missions, including to an asteroid and eventually Mars. The core stage, towering more than 200 feet tall (61 meters) with a diameter of 27.6 feet (8.4 meters), will store cryogenic liquid hydrogen and liquid oxygen that will feed the rocket's four RS-25 engines.
Read more:
www.nasa.gov/press/2014/september/nasa-unveils-worlds-lar...
Image credit: NASA/SSC
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More SLS graphics and concepts:
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Space Launch System Flickr album
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_____________________________________________
These official NASA photographs are being made available for publication by news organizations and/or for personal use printing by the subject(s) of the photographs. The photographs may not be used in materials, advertisements, products, or promotions that in any way suggest approval or endorsement by NASA. All Images used must be credited. For information on usage rights please visit: www.nasa.gov/audience/formedia/features/MP_Photo_Guidelin...
Thursday afternoon at LC-39B: The Orion spacecraft sits atop the Space Launch System (SLS) with 3 people for scale (on the Crew Access Arm, enjoying the view).
The #Artemis mission is proceeding toward an 8:33am (EDT) launch on 8/29.
I was born and raised in Puerto Rico and have wanted to work at NASA ever since I was in high school. I earned a bachelor's degree in mechanical engineering from the University of Puerto Rico-Mayagüez and my master's degree in the same field from the University of Michigan-Dearborn. It's important to never lose track of what you want and set your goals to get there.
It's really exciting for me to get to work on the next-generation rocket. I'm on the team testing the noise levels generated by NASA's Space Launch System (SLS) propulsion system and how the noise affects the vehicle using a 5-percent subscale model of the SLS and launch structures. We collect noise data at different elevations and water suppression configurations through more than 200 sensors attached to the model. I analyze that data that will be used for the rocket's sound suppression system.
I worked for the Ford Motor Company as a noise and vibration engineer early in my career, which I feel prepared me for my current job. Every experience counts. I’ve had the opportunity to test the noise generated by rocket motors of various sizes in horizontal and launch configurations. It's always impressive and exciting to see the rockets fire and the power they generate. It can be very interesting trying to test outside -- we've dealt with weather and wildlife, but our team always makes it work.
I love to travel and try new things I can learn and grow from. I grew up playing sports, and I am currently on a salsa dance team with which I travel around the country to perform. Cooking also is a big passion of mine. I enjoy making dishes from scratch. It's like an extension of engineering and science -- you're creating something out of nothing. You do a lot of testing and experimenting until you have the perfect finished product.
Image credit: NASA/MSFC
Original image:
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More about SLS:
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_____________________________________________
These official NASA photographs are being made available for publication by news organizations and/or for personal use printing by the subject(s) of the photographs. The photographs may not be used in materials, advertisements, products, or promotions that in any way suggest approval or endorsement by NASA. All Images used must be credited. For information on usage rights please visit: www.nasa.gov/audience/formedia/features/MP_Photo_Guidelin...
NASA Launch Director Charlie Blackwell-Thompson stands next to her console in Firing Room 1 at the Kennedy Space Center's Launch Control Center during a terminal countdown demonstration for Exploration Mission 1, or EM-1. The launch will be the first integrated test of the Space Launch System rocket and Orion spacecraft that will eventually take astronauts beyond low-Earth orbit to destinations such as the Moon and Mars. Taking place on Dec. 14, 2018, the countdown demonstration was intended to validate the launch team's capability to perform an EM-1 countdown and respond to challenges put into the system for practice.
Photo credit: NASA/Frank Michaux
The NASA/Boeing team works on setting up the avionics system in flight configuration in the Systems Integration and Test Facility at NASA's Marshall Space Flight Center. The units, which have powered up successfully and will undergo testing, will guide the most powerful rocket ever built -- NASA's Space Launch System.
Boeing provides this photo for the public to share. Media interested in high-resolution images for publication should email boeingmedia@boeing.com or visit boeing.mediaroom.com. Users may not manipulate or use this photo in commercial materials, advertisements, emails, products, or promotions without licensed permission from Boeing. If you are interested in using Boeing imagery for commercial purposes, email imagelicensing@boeing.com or visit www.boeingimages.com.
After successfully arriving at Kennedy Space Center’s Launch Complex 39B, Exploration Ground Systems’ mobile launcher continues its journey atop crawler-transporter 2 up to the pad surface on June 28, 2019. The mobile launcher began its final solo trek to the pad at midnight on June 27, departing from NASA’s Vehicle Assembly Building. The mobile launcher will remain at the pad over the summer, undergoing final testing and checkouts. Its next roll to the pad will be with the agency’s Space Launch System rocket and Orion in preparation for the launch of Artemis 1. Photo credit: NASA/Ben Smegelsky