Pegasus: The 'Winged Horse' of the Space Program


Transporting one of NASA’s external tanks from Michoud Assembly Facility (MAF) to the Kennedy Space Center in Florida is no simple operation. The external tank, which is 153.8 ft long, 27.6 feet in diameter and weighs approximately 58,500 pounds, is transported via a specially designed and built, ocean-going barge. The barge, known as the Pegasus, is 266 ft long and 50 ft wide and is currently utilized by the Space Shuttle Program to transport external tanks over 900 miles of inland and open ocean waterways from the Michoud Assembly Facility to the Kennedy Space Center in Florida. For this trip external tank number 134 (ET-134) is our Very Important Passenger — a genuine VIP. 


Three seamen and one technician crew the barge 24/7 when underway from the barge’s regular mooring site near the Vehicle Assembly Building at Kennedy Space Center.

In Greek mythology Pegasus is a winged horse, captured by and made to serve warrior Bellerophon. Among the many versions of Pegasus’ role and life there are two that seem to stand out. In one version Pegasus brings forth water or fresh springs where ever she steps. In another version Pegasus brings forth lightning or is the god of lightning. The role of NASA’s Pegasus seems to integrate both these mythological versions; NASA’s Pegasus lives, works and travels on water. And Pegasus delivers to the Kennedy Space Center the external tanks that feed the smoke and fire of a space shuttle launch; smoke, fire, thunder, and awe.

For many years the Pegasus, towed by the reusable solid rocket booster (RSRB) recovery ships, took the route through the Mississippi River — Gulf Outlet (MRGO) out to the Gulf of Mexico. Recently, MRGO was closed to larger ships due to significant shoaling and severe erosion caused by Hurricane Katrina. This route was utilized up through ET-128 and took approximately 4 -5 days for the barge to arrive on dock at Kennedy.

Today Pegasus is towed by two commercial tug boats along the Gulf Intracoastal Waterway (GIWW) through the Mississippi Sound to Gulfport, Miss. The Gulf Intracoastal Waterway route is approximately 25 miles longer, with one day added to the travel schedule.  Solid rocket booster recovery ship Liberty Star will meet Pegasus at Gulfport, take Pegasus in tow and depart south into the Gulf of Mexico. 

Pegasus is manned 24 hours a day from the time it leaves Kennedy, goes to MAF and returns to Kennedy. On average, a round trip takes between 10-11 days.  Once the last external tank is shipped, the barge will be utilized by Ares I Upper Stage which also plans to use the Gulf Intracoastal Waterway route.

Marshall Space Flight Center engineers developed the technical requirements for the Pegasus Barge, Halter Marine created the design and produced the drawings. Gulf Coast Fabricators of Pascagoula, Miss., constructed and completed the 1,648 ton Pegasus in June 1999. 

NASA has used many barges to transport large spacecraft components from their respective manufacturing sites to Kennedy. Other NASA barges including Orion, Poseidon, Little Lake, Palaemon, Pearl River, Promise and USNS Point Barrow were used to tow Saturn vehicle components between Marshall , MAF, California and Stennis Research Center to Kennedy in Florida. Of the older barges, only Poseidon remains docked at Stennis, awaiting final disposition.

Pegasus Looking Ahead to Weather Decision Later Today


Pegasus and crew are ready to get under way from the dock at Michoud Assembly Facility in East New Orleans pending a weather decision later today. Weather forecast does show winds prohibiting departure of Pegasus diminishing in the afternoon. Current winds up to 25 knots — that’s about 30 miles per hour — are expected to drop to around 15 knots or 17 miles per hour during the afternoon.  Cloudless skies and very cool temperatures are making for a very pleasant morning in the New Orleans area. 

Take a look at this video shot by Marshall television producer Mick Speer of the roll put to the dock, loading and securing the cargo doors of Pegasus; plus some video of Pegasus at the dock over the weekend.

A New Logistics System for the 'Right Stuff'


Hi everyone! We’re here at Michoud Assembly Facility waiting to sail with ET-134 to the Kennedy Space Center. Thought I’d share with you a little history about how NASA developed the logistics system to move and support all this heavy, outsized spacecraft hardware.


ET-134 moves inside the Pegasus covered barge at NASA’s Michoud Assembly
Facility. Credit: Lockheed Martin

When the space program kicked into high gear in the early 1960s the equipment necessary to move the very large components of spacecraft did not exist. In fact, the lack of necessary equipment almost became a limiting factor when preparing spacecraft designs and considering how to move them to launch sites, the primary location being Kennedy Space Center, Fla.


NASA used barges for transporting full-sized stages for the Saturn I, Saturn IB,
and Saturn V vehicles between the Marshall Space Flight Center; the  Michoud Assembly
Facility; the Mississippi Test Facility, now Stennis Space Center; and the Kennedy
Space Center. Credit: NASA

An agency-level logistics office was created at NASA Headquarters in Washington to orchestrate and coordinate a complex set of requirements based on a new and developing program, the Saturn/Apollo Program, and very geographically dispersed set of players, including various NASA centers, test sites, launch sites, suppliers, contractors, and manufacturers; an amazing challenge.

Spacecraft could be built, but now they had to be moved. In the early 1960s Marshall Space Flight Center developed its own logistics management office and began developing plans for a “fleet” of specialized transporters to move the “right stuff.”

Eventually, with assistance and vessels from the U.S. Navy, NASA developed its own ocean-going fleet of seven barges capable of transporting most of the components of the Saturn/Apollo program from home bases to Kennedy Space Center for launch operations.


Aerial view of NASA Dock at Michoud Assembly Facility with four barges, left to right,
Paleamon, Promise, Poseidon and Orion. The barges ferried Saturn IB and
Saturn V stages between the Marshall Space Center; the Michoud Assembly
Facility; the Mississippi Test Facility, now Stennis Space Center; and the
Kennedy Space Center. Credit: NASA

A smaller fleet of two oversize and heavily modified aircraft known as the Super Guppy and the Pregnant Guppy were procured for movement by air of Saturn F-1 engines, lunar modules and S-IVB stages.

 
NASA’s B377SGT Super Guppy Turbine cargo aircraft touches down at Edwards
Air Force Base, Calif., June 11, 2000, to deliver the latest version of the X-38 flight
test vehicle to NASA’s Dryden Flight Research Center. Credit: NASA

Also, NASA made use of the railroads for moving Saturn propellants and even U.S. Army CH-47 helicopters to move large components from long distances for testing at Marshall.


The NASA Railroad train moves along the track through NASA Kennedy Space
Center’s Launch Complex 39 area. Behind the locomotive car is the Vehicle Assembly
Building. The train is hauling solid rocket booster segments from the STS-122
mission. After a mission, the spent boosters are recovered, cleaned, disassembled,
refurbished and reused. After hydrolasing the interior of each segment,
they are placed on flatbed trucks and individual booster segments are transferred
to a railhead located at the railroad yard. Credit: NASA

The Space Shuttle Program inherited significant experience and a well-oiled logistics machine from the Saturn Program. Shuttle components are moved by a wide variety of outsized transporters just as in the days of Saturn/Apollo. 

Today, components that make up the solid rocket motors (segments and aft exit cones) are transported cross-country via rail beginning in Utah where they are manufactured. With the help of multiple railroad companies, these components typically spend less than two weeks riding over the rail before arriving at the Kennedy Space Center. Once the components are offloaded, assembled, and ultimately flown in space, they are recovered, disassembled, inspected, and ultimately the segments are transported back to Utah on the same rail that brought them to Kennedy. At this stage in the process the hardware is refurbished and made ready for future flight opportunities.  Solid rocket booster components (forward assemblies, aft skirts) are manufactured at the Assembly and Refurbishment Facility at KSC and transported via ground support equipment over the Kennedy road system to the respective Kennedy facilities where these components are integrated with the solid rocket motor segments. Solid rocket booster hardware and solid rocket motor hardware, when integrated together, make up the space shuttle reusable solid rocket booster. Essentially, NASA is a railroad man as well.


Space shuttle solid rocket motor segments are transported cross-country via rail from
Utah, where they are manufactured, to the Kennedy Space Center, Fla. Credit: NASA

External tanks such as ET-134, as you know already, move by barge and towing ship from New Orleans to Kennedy Space Center over water and space shuttle main engines move by truck. Some NASA equipment, such as specialized cargo or payloads for the International Space Station are moved by Super Guppy, stationed at Ellington Field in Houston, Texas.   

The space shuttle orbiter flies everywhere it goes, except for short distances over ground at Kennedy. If the orbiter has to land away from Kennedy due to weather, such as at Edwards Air Force Base, Calif., a special Boeing 747 pulls up and flies the orbiter back to Kennedy “piggy-back” style in just a few days.


Southern California’s high desert provides the backdrop as one of NASA’s two
modified 747 Shuttle Carrier Aircraft ferries Space Shuttle Atlantis back to the
Kennedy Space Center after departing NASA’s Dryden Flight Research Center
at Edwards Air Force Base. Credit: NASA/J. Ross

Future space program hardware will likely make use of this same or similar means of transportation for movement from point of origin to the Kennedy Space Center for launch operations. 

Liberty Star’s mission to tow ET-134 to Kennedy is essentially part of a bigger NASA logistics operation.

It has been said that logistics is everything. It may be. You simply have to have the “right stuff” at the right place at the right time…to make a difference.

ET-134 Rolls Out to the Dock


ET-134 has rolled out to the dock at NASA’s Michoud Assembly Facility and loaded onto the Pegasus barge — the first step in its long journey. Walt Adams, supervisor of  Pegasus barge operations, discusses the weather delay in shipping ET-134, as well as conditions for safe shipment of the external fuel tank through the Intracoastal Waterway and the Mississippi Sound to Gulfport, Miss.

Watch the interview (Windows, streaming)


ET-134 rolls out of Building 420 at NASA’s Michoud Assembly Facility for
its trip to the dock and loading onto the Pegasus barge. Credit: Lockheed Martin


ET-134 continues its move to the dock at Michoud Assembly Facility on the
morning of Oct. 15. The move was executed flawlessly in approximately one hour.
Credit: Lockheed Martin


 ET-134 continues its trip to the Michoud docks. Credit: Lockheed Martin


ET-134 makes an early morning move on Oct. 15 across Michoud Assembly facility
to the dock in preparation for loading. Credit: Lockheed Martin 


Marshall television producer Mick Speer visually documents the movement of ET-134
through NASA’s Michoud Assembly Facility to the dock in preparation for loading
on board the Pegasus barge. Credit: Lockheed Martin


ET-134 moves inside the Pegasus covered barge. Credit: Lockheed Martin


ET-134 is moved onto the Pegasus barge. Credit: Lockheed Martin


Marshall Television producer Mick Speer, left, and Steve Roy, public affairs
spokesperson and blogger for Marshall Space Flight Center, are pictured during
loading operations of ET-134 on Thursday, Oct. 15.at NASA’s Michoud Facility
Assembly in New Orleans. Credit: Lockheed Martin


Pegasus barge operations supervisor Walt Adams, right, of United Space Alliance
discusses final loading procedures and weather forecasts for the next several days
with Marshall public affairs spokesperson Steve Roy, left. Credit: Lockheed Martin


Pegasus barge Able Bodied Seaman B.H. “Skip” Conway greets Marshall
spokesperson and blogger Steve Roy at the Michoud dock as ET-134 is loaded and
secured to the barge. Credit: Lockheed Martin


ET-134 as it is guided onto the Pegasus barge during the early morning hours of
Thursday, Oct. 15, in preparation for departure to Kennedy Space Center.
Credit: Lockheed Martin

 
Pegasus barge operations supervisor Walt Adams stands on the bow of the barge
Pegasus during loading of external tank, ET-134, at the Michoud Assembly
Facility dock. Credit: Lockheed Martin

The Cradle of External Tanks: The Space Shuttle's Gas Tank


To understand the role that external tanks play and why this trip begins in eastern New Orleans on the Intracoastal Waterway, you have to start where they are built, NASA’s Michoud Assembly Facility.

The original tract of land where Michoud Assembly facility was built was part of a 34,500-acre French Royal land grant to local merchant Gilbert Antoine de St. Maxent in 1763. By the early 1800s, the property was owned by architect and engineer Bartholomey Lafon, whose maps of the waters surrounding the tract were used in defeating the British in the Battle of New Orleans in January 1815. Near Chalmette, LA, a few miles from Michoud, the mischievous British army advanced in the open against a mixed force of U.S. Army regulars, American Indians, New Orleans militia and local buccaneers hunkered down behind hastily built trenches and barricades. Massed rifle and musket fire turned the British formation into shambles before the British withdrew, losing 2,000 casualties, their commanding general, Edward Pakenham, and the two other most senior officers.

Later, the land was acquired by French transplant Antoine Michoud, who moved to the city in 1827. Michoud operated a sugar cane plantation and refinery on the site until his death in 1863. His heirs continued operating the refinery and kept the original St. Maxent estate intact into the 20th century. Two brick smokestacks from the original refinery still stand on the Michoud facility grounds.

In 1940, the U.S. government purchased the land as a site for war-related construction. Three years later, the world’s largest production building at the time, covering 43 acres under one roof, was completed. The plant was used during World War II to build cargo planes and other aircraft, and again during the Korean War to produce tank engines.

The Michoud facility was acquired by NASA in 1961, after its availability was brought to the space agency’s attention by Wernher von Braun, known as the father of the Saturn family of rockets, who was named the first director of Marshall Space Flight Center in Huntsville, Ala., in 1960.
 
Managed by the Marshall Center, Michoud includes one of the world’s largest manufacturing plants, with 43 acres under one roof, and a port permitting transportation of large space systems and hardware.

Building External Tanks
External tanks are assembled at Michoud from hardware delivered by hundreds of sub-contractors and vendors.  Once the components are positioned at Michoud, a small army of aerospace workers begin the almost three year process to fully assemble, weld, test and inspect a new external tank. 


Flickr Gallery: External Tank Assembly

Today there are four external tanks in the assembly line at Michoud, ET-135 thru ET-138. All of these tanks will board Pegasus in late 2009 or early 2010 and make the 900-mile trip from Michoud to Kennedy Space Center to play their vital role in supplying the Space Shuttle Main Engines with 145,000 gallons of liquid oxygen and 390,000 gallons of liquid hydrogen during the first eight-and-a-half-minutes of launch.  One additional tank resides at Michoud, but it may never fly. ET-122 was present at Michoud when Hurricane Katrina hit Louisiana in 2005 and was damaged.  In fact ET-122 is now being repaired to serve as the very last tank of the Space Shuttle Program, the Launch on Need tank for the last scheduled space shuttle mission, STS-133, in the fall of 2010.  If all goes well with that mission ET-122 should never fly.


Flickr Gallery: External Tank Assembly

After the loss of space shuttle Columbia in February 2003, NASA went to work to redesign and improve many components of the structures of the external tanks and the application processes of the all important foam, also known as the Thermal Protection System or TPS. Major improvements have been made to the tank’s forward bipod fitting area, the liquid hydrogen tank Ice Frost Ramps, the intertank flange area, and the liquid oxygen feedline brackets and bellows. The tank’s protuberance air load ramps — known as PAL ramps — were also removed.

By the summer of 2008 external tank foam application and new designs had reduced the amount of foam being released during launch to very small, if not tiny amounts of foam. The successful reduction in foam debris came as a result of a non-stop process of continuous improvement to make shuttle launches as safe as possible, recognizing that external tanks will still release very small amounts of foam.  Even with a few hiccups, the external tanks flying today are the safest and best tanks ever flown in the history of the shuttle program.

The newest tanks, including ET-134, have been welded using a new welding technology called Friction Stir Welding, a technique better than conventional fusion welding.  Friction stir welding is different in that the materials are not melted. A rotating tool pin uses friction and pressure to plasticize the metal and join the two parts together. As a result, weld joints are more efficient, yielding 80 percent of the base strength. Fusion welding averages 40 to 50 percent of the base material’s strength.  In fact ET-134 is the first external tank to have most of its liquid hydrogen tank welding performed by friction stir welding.


Flickr Gallery: External Tank Assembly, Friction Stir Welding


Flickr Gallery: External Tank Assembly, Friction Stir Welding

Here’s the status of the remaining external tanks:

ET-133/STS-129 is poised to launch from KSC in November
ET-134/STS-130 is en route to KSC with Pegasus
ET-135/STS-131 is in assembly at MAF
ET-136/STS-132 is in assembly at MAF
ET-137/STS-134 is in assembly at MAF
ET-138/STS-133 is in assembly at MAF

With the upcoming completion of the Space Shuttle Program in 2010 the end of the assembly line at Michoud is coming to an end as well.  The number of workers at Michoud building external tanks is declining steadily and eventually there will be no work on external tanks. Work will eventually shift to other NASA projects.

As NASA enters a new era in space travel, the Michoud Assembly Facility is poised to continue its legacy, providing vital support to NASA’s mission to return humans to space and perhaps the moon, Mars and perhaps to extend a human presence into the solar system.

Katrina
To fully understand Michoud today you have to understand what the facility and what its employees experienced in late August 2005; Hurricane Katrina.

My first trip to Michoud was in the aftermath of Katrina. I traveled by air to Gulfport, Miss. and then overland to Stennis Research Center located some 40 miles to the east of Michoud.  I then traveled with Marshall Security from Stennis to Michoud overland via Interstate 10 and  Highway 11 thru Slidell, La. What I saw in Slidell was truly a shock. The portion of Slidell nearest the coast on Lake Pontchartrain had been badly flooded and was abandoned rubble; giant toothpicks lay everywhere. The most dangerous part of Katrina had passed to the east of Slidell and smashed the small Mississippi coastal towns like Waveland, Pass Christian and Gulfport, but Slidell received much of the wrath of Katrina as well.  Entire neighborhoods of Slidell were nothing more than stacks of debris twenty feet high; people’s homes, schools, and businesses; people’s hopes and dreams. It was a wrenching sight. 

What I didn’t know then was that many Slidell area residents and other residents of mauled East New Orleans represented much of the Lockheed Martin workforce at Michoud; the workforce that builds external tanks; the backbone and gas tank of Shuttle Transportation System.

Our little convoy passed over Lake Pontchartrain on Highway 11, which unlike I-10 was still standing, crossed under the Interstate 10 overpass and entered Irish Bayou.  There were few structures standing in Irish Bayou.  One man was living alone in a house built on stilts and our security detachment stopped to check up on him. His home had a roof and only three walls and he was very tired and haggard.  His job, a cook in a restaurant in Slidell, no longer existed. Over the next few days on subsequent daily trips our security detachment dropped off small amounts of food and water for the lone survivor and although money wasn’t worth much because nothing was open, I gave him my travel money.  In the early days after Katrina Lockheed Martin employees of the rideout team and a Marshall Security detachment were the first group to clear a route of debris along this portion of Highway 11 thru Irish Bayou, permitting vehicle traffic to enter East New Orleans and travel to Michoud.

We continued into eastern New Orleans and worked our way to Michoud proper. I had only a very vague idea of how Michoud had fared during Katrina. Michoud was intact, standing with some damage, but I had no real idea how the external tank production line had fared.  After meeting with the Michoud/NASA Chief Operating Officer Patrick Scheuerman, I headed across to see the external tank manufacturing floor in Building 103 and assess the area for a stand up location for an upcoming television interview with Miles O’Brien of CNN, pre-arranged by my colleague and friend Dave Drachlis. Miles O’Brien had been covering the New Orleans story since early post Katrina and he had shown interest interviewing members of the Michoud Hurricane Rideout Team, all Lockheed Martin employees, who made up the vast majority of Michoud employees building NASA’s external tanks.

U.S. Marines, Colorado and Washington state National Guard soldiers and Canadian and American search and rescue personnel dotted the landscape of Michoud.  Helicopters of all types came and went regularly, particularly the helicopters of the U.S. Coast Guard.  Everyone knows about their incredible service to the people of New Orleans.

Then I received the second shock of the day. I entered the all important manufacturing floor of Building 103. I could see perhaps two or three small puddles of water and some disturbed roofing, but everything else including several external tanks near completion was untouched. In fact it was so clean and orderly it nearly took your breath away. I crossed to the west side of Building 103 and picked the spot. Miles O’Brien would be brought here to shoot the interview, looking back to the east along the aligned sight of transporters, liquid oxygen tanks, liquid hydrogen tanks, intertanks and welding tools; all in pristine condition. I let out a sigh; Michoud was an island in a sea of disaster and the shuttle program had dodged a bullet, but not the Lockheed Martin employees of Michoud. Words like catastrophic, devastated and heart-rending are understatements at best to describe the condition of the greater New Orleans area, the city to which Michoud employees were now returning.


The International Space Station photographed Katrina’s damage from 230 miles
above. While Michoud (right) is largely dry, the adjacent neighborhoods are
extensively  flooded. (NASA)

The next day went like clockwork. Miles O’Brien checked in by cell phone and eventually flew by commercial helicopter into Michoud for the interview. He readily accepted the shoot location and interviewed three members of the rideout team, Lockheed Martin technicians who had operated the vital pump house pushing water out of Michoud as fast as it entered. Michoud could have flooded without the pump house and its team of technicians who braved wind and rain and drove in little visibility to keep the pumps working. 

One day later, while eating lunch next to a group of U.S. Marines in the recently restarted cafeteria, CNN started running the Miles O’Brien interview with the Michoud members of the rideout team. The cafeteria television was tuned to CNN and quickly caught everyone’s attention as Miles O’Brien described the heroic deeds of those who had risked their lives for the nation’s space program.  As a body, the Marines stood on their feet and clapped and cheered for the space workers present in the cafeteria, including many members from the rideout team. It was quite a moment. These were Marines that a few months earlier had just returned from combat operations in Faluja, Iraq. It was a fine tribute from one great body of Americans to another.

John Schwartz of the New York Times also braved the hot weather and minimal amenities and interviewed the rideout team at Michoud. He was great to work with. He wrote a good story.

By way of wrapping up the week at Michoud, Marshall Television deployed a production team  consisting of Bob Moder, James Bilbrey and Mick Speer to document the recovery work underway at Michoud and shoot interviews for NASA Television. This done we packed up and headed back to Huntsville, Ala. NASA television began broadcasting this video of Michoud the next day.

By late October 2005 sufficient workers of Michoud’s Lockheed Martin team had returned to work to restart the external tank assembly line. It should not be forgotten that many of these workers in the months ahead worked one or sometimes two shifts at the assembly line and then returned to their homes in the evening to strip their homes of moldy sheet rock, ruined furniture and appliances, ruined carpet and to shovel mounds of mud and other debris out of immediate sight. It was a non-stop work in progress for a highly dedicated group of aerospace workers.

I returned to New Orleans in June 2006 with my volunteer church group to help prepare houses for refurbishment. We worked for several days in Gentilly and East New Orleans pulling down moldy sheet rock, attic insulation and removing furniture and battered appliances; saving the home owners something like $8,000 each. At 95 degrees it was hot work. Insulation stuck like little pins in every corner, nook and cranny, as we sweated and heaved gunk and junk. Upon leaving New Orleans on the last day our group decided to pass through the Ninth Ward. Although the streets were clear of debris, almost every structure was badly mauled or unrecognizable; homes, businesses and churches had imploded from force of tons of water sloshing back and forth. It was the saddest sight I’ve ever seen, and I couldn’t help but wonder what happened to all these people.

Sailing with NASA


Last week, one of NASA’s Space Shuttle Solid Rocket Booster Recovery (SRB) ships, the Liberty Star, sailed from its dock at Cape Canaveral Air Force Station, picked up the tow of NASA’s Pegasus barge and headed south along the Atlantic coast, through the Straits of Florida, and across the Gulf of Mexico to the Port of Gulfport, Gulfport, Miss.  The Liberty Star arrived at Gulfport, Miss., today, October 13. Two small tug boats then picked up Pegasus and towed her to Michoud Assembly facility in East New Orleans. In the early morning hours of Friday, October 16, Pegasus will arrive back in Gulfport where Liberty Star will again take the barge in tow and begin the return voyage back across the Gulf and the Straits of Florida to deliver a very important passenger to the Kennedy Space Center.

It’s a journey the Liberty Star and her sister ship, the Freedom Star, have made repeatedly since 1996.  That year the booster recovery ships were pressed into service to tow Pegasus for the major part of the voyage between Michoud Assembly Facility in East New Orleans in lieu of using commercial tug boats the entire distance. 

As mentioned above commercial tug boats are still used to tow Pegasus at the very beginning of the journey in Louisiana and Mississippi and during the final miles in a shallow and narrow channel to the turn basin in front of the Vehicle Assembly Building at the Kennedy Space Center. 

The very important passenger (VIP) that needs to be delivered to the Kennedy Space Center, on time and in good shape, is one of the most important elements of what is known as the “Shuttle Stack,” the complete towering Shuttle Transportation System. The “Stack” includes the Orbiter, the three Space Shuttle Main Engines, the two reusable solid rocket boosters and motors and the very important passenger that will ride the Pegasus; an external tank numbered 134.

ET-134 will be the backbone of the “Shuttle Stack” and the gas tank for the space shuttle main engines for the February 2010 launch of space shuttle Endeavour’s flight to the International Space Station, mission number STS-130.


Watch how an external tank “goes to sea” (Windows, streaming)

NASA public affairs officer, Steve Roy (that’s me) of the Marshall Space Flight Center, will travel on board the Pegasus and Liberty Star to give you some insight into NASA’s maritime operations and life on board the vessels that make these important 1,800 mile round trips, as well as the story of the VIP of the trip, ET-134. Steve will be joined by NASA television producer Mick Speer of Marshall Television, a former U.S. Navy photographer and television production specialist. Steve will blog via the NASA portal several times a day with updates, images and video.

To begin I’d like to explain the relationship between SRB recovery ships, the Pegasus barge, Michoud Assembly Facility and my NASA center, the Marshall Space Flight Center in Huntsville, Ala.  The Marshall Center exercises overall management responsibilities for NASA’s Michoud Assembly Facility where the external tanks are built by Lockheed Martin. Marshall also has management responsibility for the manufacturing, assembly and delivery of the external tanks as part of the space shuttle transportation system, as well as the solid rocket boosters and motors and space shuttle main engines.

Management responsibility for the solid rocket boosters includes their recovery at sea. The prime contractor under Marshall for booster recovery is United Space Alliance (USA) in Cape Canaveral. USA runs all aspects of day-to-day maritime operations for NASA including training crews, readiness of the NASA fleet, real time booster recovery operations, and towing external tanks for the majority of the trip to Kennedy Space Center.


From a Flickr Photo Gallery: “Booster Recovery at Sea”

I am the NASA public affairs officer with responsibility to support all aspects of the external tanks, reusable solid rocket boosters and motors and the space shuttle main engines. Thus by definition, and lucky for me, I am the NASA public affairs officer, along with the public affairs staff of United Space Alliance, with responsibility to support the role of the recovery ships, Freedom Star and Liberty Star, as well as the Pegasus barge.

I am but one spokesperson in a greater NASA public affairs team that supports space flight operations of the space shuttle, expendable launch vehicles and the International Space Station. That team includes the public affairs space operations teams at NASA Headquarters, Washington D.C.; at Johnson Space Center in Texas; at the Kennedy Space Center in Florida; at Stennis Research Center in Mississippi; and the team at Marshall Space Flight Center in Alabama. The space operations public affairs team also includes other public affairs representatives at United Space Alliance (USA), which includes the major orbiter subcontractor Boeing, in Florida and Texas; Lockheed Martin/Michoud Assembly Facility (LM/MAF builds external tanks) in Louisiana; Pratt Whitney Rocketdyne (PWR) builds space shuttle main engines) in California and Florida, and ATK (ATK builds RSRMs) in Utah.

Sounds complicated uh? It’s not so bad when you’re in the middle of it. Let’s get ready to go.  Grab your binoculars, flip flops, sun screen, folding chair and snacks and head to your computer. Join the voyage and Sail with NASA!