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First tile gap filler
This extended movie shows Steve Robinson riding the station's robot arm, moving within reach of Discovery's underside and successfully pulling out the first protruding tile gap filler. (6min 45sec file)
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Second tile gap filler
This extended movie shows Steve Robinson successfully pulling out the second protruding tile gap filler. (9min 23sec file)
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Storage platform
The External Stowage Platform-2 designed to hold spares and replacement equipment for the space station is attached to the Quest airlock module's outer hull during the spacewalk. (6min 29sec file)
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Station experiments
Japanese astronaut Soichi Noguchi climbed 60 feet above Discovery's payload bay to the space station's P6 solar array truss to attach the Materials International Space Station Experiment-5 package. (4min 08sec file)
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Opening the suitcase
Noguchi deploys the MISSE-5 package, revealing a host of material samples to the space environment for extended exposure. (3min 43sec file)
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Atop the station
Noguchi's helmet-mounted camera provides a stunning view atop the P6 truss showing Discovery to his right and the Russian segment of the space station on his left. (2min 31sec file)
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NASA successfully completes shuttle SRB test firing
NASA NEWS RELEASE
Posted: August 16, 2005

NASA's Space Shuttle program successfully fired its first Production Rate Motor Tuesday, Aug. 16, at a Utah test facility. The two-minute static, or stationary, firing of the rocket motor was performed at ATK Thiokol Inc., an Alliant Techsystems company, in Promontory, north of Salt Lake City.


A two-minute static firing of the shuttle program's first Production Rate Motor was successfully tested Aug. 16. Credit: ATK Thiokol
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The firing of the Production Rate Motor was one of several annual tests conducted by the Reusable Solid Rocket Motor Project Office at NASA's Marshall Space Flight Center in Huntsville, Ala., to qualify any proposed changes to the rocket motor and to guarantee that new materials meet safety requirements. These annual tests closely replicate a Space Shuttle launch.

The Aug. 16 test demonstrated process, material and design changes made to the Reusable Solid Rocket Motors produced during the past two years. The motor firing also will allow NASA to further evaluate the performance of new sensors that read and retain detailed information -- much faster than instruments now used -- on pressures generated in the motor during a Shuttle launch.

"Testing such as this is important to ensure continued quality and performance," said Jody Singer, manager of the Reusable Solid Rocket Motor Project, part of the Space Shuttle Propulsion Office at the Marshall Center.

The test satisfied 48 objectives, including the evaluation of new sensors, or Intelligent Pressure Transducers. Produced by Stellar Technology, Inc. of Amherst, N.Y., the transducers also were tested earlier this year on a modified motor at the Marshall Center.

In addition to evaluating the performance of the new sensors, the test also monitored an operational pressure transducer recently qualified for flight and flown on STS-114: Space Shuttle Return to Flight launched July 26. These transducers, also made by Stellar Technology, help determine the time of separation of the Solid Rocket Boosters from the Orbiter.

The Production Rate Motor test also will allow NASA and ATK Thiokol engineers to further examine a more environmentally friendly insulation material and to gather information on a pressure-sensitive adhesive that may soon be used on the motor's joints.

Another objective of the test was to assess the performance of the propellant bore -- the hole down the middle -- of the rocket motor. When a motor is ignited, a controlled burn begins down its middle, creating the motor's thrust. The test results will show how motors react during the first few seconds following ignition and provide engineers more information on the firing stability of motors -- crucial information for human spaceflight.

Additionally, a powerful X-ray was used during the test to scrutinize how the motor nozzle performs during launch and ascent.

Static firings are part of the ongoing verification of components, materials and manufacturing processes required by the Space Shuttle program.

Test data will be analyzed and the results for each objective provided in a final report. Following the test, the motor's metal casings and its nozzle components will be refurbished for reuse.

ATK Thiokol manufactures the Shuttle's Solid Rocket Motor. The Shuttle's Reusable Solid Rocket Motor is the largest solid rocket motor ever flown, the only one rated for human flight and the first designed for reuse. It is the primary component of the Shuttle's twin Solid Rocket Boosters. These solid propellant rockets take the Shuttle to an altitude of 28 miles at a speed of 3,094 mph before they separate and fall into the ocean to be retrieved, then refurbished and prepared for another flight.