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NASA TV's This Week @NASA, A
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The crew of STS-131 returned
…
04/23/10
| Description |
The crew of STS-131 returned home to Houston following their fifteen days in space aboard shuttle Discovery. * The first images are in from NASA's Solar Dynamics Observatory, or SDO, and scientists who study the sun say they are a stunning treasure trove of data about Earth's star. * NASA helped celebrate Earth Day's fortieth anniversary with nine consecutive days of activities and public exhibits on the National Mall in Washington. * Robonaut 2, or R2, as it, or he, is also known, is scheduled to become the first human-like robot to take up permanent residence on the International Space Station. * Hundreds of students from middle schools, high schools, and colleges representing 20 states were in northern Alabama for the annual Space Launch Initiative, or LaunchFest. * The STS-130 crew paid a visit to NASA Headquarters where they played highlights of their February mission to the International Space Station for employees and guests. The six-astronaut crew of space shuttle Endeavour was commanded by George Zamka, Terry Virts was the pilot, Mission Specialists were Nicholas Patrick, Bob Behnken, Steve Robinson and Kay Hire. * On April 24, 1990, the Hubble Space Telescope launched aboard Space Shuttle Discovery from the Kennedy Space Center in Florida. Since then, the observatory orbiting 350 miles above Earth has produced hundreds of thousands of unprecedented images of different corners of the universe. |
| Date |
04/23/10 |
|
Female Astronauts
| Title |
Female Astronauts |
| Full Description |
Astronauts Dr. N. Jan Davis (left) and Dr. Mae C. Jemison (right) were mission specialists on board the STS-47 mission. Born on November 1, 1953 in Cocoa Beach, Florida, Dr. N. Jan Davis received a Master degree in Mechanical Engineering in 1983 followed by a Doctorate in Engineering from the University of Alabama in Huntsville in 1985. In 1979 she joined NASA Marshall Space Flight Center as an aerospace engineer. A veteran of three space flights, Dr. Davis has logged over 678 hours in space since becoming an astronaut in 1987. She flew as a mission specialist on STS-47 in 1992 and STS-60 in 1994, and was the payload commander on STS-85 in 1997. In July 1999, she transferred to the Marshall Space Flight Center, where she became Director of Flight Projects. Dr. Mae C. Jemison, the first African-American woman in space, was born on October 17, 1956 in Decatur, Alabama but considers Chicago, Illinois her hometown. She received a Bachelor degree in Chemical Engineering (and completed the requirements for a Bachelor degree in African and Afro-American studies) at Stanford University in 1977, and a Doctorate degree in medicine from Cornell University in 1981. After receiving her doctorate, she worked as a General Practitioner while attending graduate engineering classes in Los Angeles. She was named an astronaut candidate in 1987, and flew her first flight as a science mission specialists on STS-47, Spacelab-J, in September 1992, logging 190 hours, 30 minutes, 23 seconds in space. In March 1993, Dr. Jemison resigned from NASA, thought she still resides in Houston, Texas. She went on to publish her memoirs, Find Where the Wind Goes: Moments from My Life, in 2001. The astronauts are shown preparing to deploy the lower body negative pressure (LBNP) apparatus in this 35mm frame taken in the science module aboard the Earth-orbiting Space Shuttle Endeavor. Fellow astronauts Robert L. Gibson (Commander), Curtis L. Brown (Junior Pilot), Mark C. Lee (Payload Commander), Jay Apt (Mission Specialist), and Mamoru Mohri (Payload Specialist) joined the two on their maiden space flight. The Spacelab-J mission was a joint effort between Japan and the United States. |
| Date |
09/15/1992 |
| NASA Center |
Johnson Space Center |
|
TRMM Looks at the Rain Fueli
…
| Title |
TRMM Looks at the Rain Fueling Hurricane Ivan on September 15, 2004 |
| Abstract |
NASA's TRMM spacecraft is used by meteorologists to understand Hurricane Ivan. TRMM snapped this view of Hurricane Ivan on September 15, 2004 just before the storm strikes land. The cloud cover is taken by TRMM's Visible and Infrared Scanner (VIRS). The rain structure is taken by TRMM's Precipitation Radar (PR). It looks underneath of the storm's clouds to reveal the underlying rain structure. Blue represents areas with at least 0.25 inches of rain per hour. Green shows at least 0.5 inches of rain per hour. Yellow is at least 1.0 inches of rain and Red is at least 2.0 inches of rain per hour. High vertical bands on the outside of the storm indicated that Hurricane Ivan was very likely to spawn tornados in Florida and Georgia. |
| Completed |
2004-09-15 |
|
TRMM Looks at the Rain Fueli
…
| Title |
TRMM Looks at the Rain Fueling Hurricane Ivan on September 15, 2004 |
| Abstract |
NASA's TRMM spacecraft is used by meteorologists to understand Hurricane Ivan. TRMM snapped this view of Hurricane Ivan on September 15, 2004 just before the storm strikes land. The cloud cover is taken by TRMM's Visible and Infrared Scanner (VIRS). The rain structure is taken by TRMM's Precipitation Radar (PR). It looks underneath of the storm's clouds to reveal the underlying rain structure. Blue represents areas with at least 0.25 inches of rain per hour. Green shows at least 0.5 inches of rain per hour. Yellow is at least 1.0 inches of rain and Red is at least 2.0 inches of rain per hour. High vertical bands on the outside of the storm indicated that Hurricane Ivan was very likely to spawn tornados in Florida and Georgia. |
| Completed |
2004-09-15 |
|
TRMM Looks at the Rain Fueli
…
| Title |
TRMM Looks at the Rain Fueling Hurricane Ivan on September 15, 2004 |
| Abstract |
NASA's TRMM spacecraft is used by meteorologists to understand Hurricane Ivan. TRMM snapped this view of Hurricane Ivan on September 15, 2004 just before the storm strikes land. The cloud cover is taken by TRMM's Visible and Infrared Scanner (VIRS). The rain structure is taken by TRMM's Precipitation Radar (PR). It looks underneath of the storm's clouds to reveal the underlying rain structure. Blue represents areas with at least 0.25 inches of rain per hour. Green shows at least 0.5 inches of rain per hour. Yellow is at least 1.0 inches of rain and Red is at least 2.0 inches of rain per hour. High vertical bands on the outside of the storm indicated that Hurricane Ivan was very likely to spawn tornados in Florida and Georgia. |
| Completed |
2004-09-15 |
|
TRMM Looks at the Rain Fueli
…
| Title |
TRMM Looks at the Rain Fueling Hurricane Ivan on September 15, 2004 |
| Abstract |
NASA's TRMM spacecraft is used by meteorologists to understand Hurricane Ivan. TRMM snapped this view of Hurricane Ivan on September 15, 2004 just before the storm strikes land. The cloud cover is taken by TRMM's Visible and Infrared Scanner (VIRS). The rain structure is taken by TRMM's Precipitation Radar (PR). It looks underneath of the storm's clouds to reveal the underlying rain structure. Blue represents areas with at least 0.25 inches of rain per hour. Green shows at least 0.5 inches of rain per hour. Yellow is at least 1.0 inches of rain and Red is at least 2.0 inches of rain per hour. High vertical bands on the outside of the storm indicated that Hurricane Ivan was very likely to spawn tornados in Florida and Georgia. |
| Completed |
2004-09-15 |
|
TRMM Looks at the Rain Fueli
…
| Title |
TRMM Looks at the Rain Fueling Hurricane Ivan on September 15, 2004 |
| Abstract |
NASA's TRMM spacecraft is used by meteorologists to understand Hurricane Ivan. TRMM snapped this view of Hurricane Ivan on September 15, 2004 just before the storm strikes land. The cloud cover is taken by TRMM's Visible and Infrared Scanner (VIRS). The rain structure is taken by TRMM's Precipitation Radar (PR). It looks underneath of the storm's clouds to reveal the underlying rain structure. Blue represents areas with at least 0.25 inches of rain per hour. Green shows at least 0.5 inches of rain per hour. Yellow is at least 1.0 inches of rain and Red is at least 2.0 inches of rain per hour. High vertical bands on the outside of the storm indicated that Hurricane Ivan was very likely to spawn tornados in Florida and Georgia. |
| Completed |
2004-09-15 |
|
Hurricane Ivan Rain Accumula
…
| Title |
Hurricane Ivan Rain Accumulation September 2-19, 2004 (wide view) |
| Abstract |
This animation shows rain accumulation between Hurricane Frances and Hurricane Ivan. The green path is the path Hurricane Frances took between August 25, 2004, and September 9, 2004. The red path is Hurricane Ivan from September 2, 2004, to September 19, 2004. |
| Completed |
2004-09-16 |
|
Hurricane Ivan Rain Accumula
…
| Title |
Hurricane Ivan Rain Accumulation September 2-19, 2004 (wide view) |
| Abstract |
This animation shows rain accumulation between Hurricane Frances and Hurricane Ivan. The green path is the path Hurricane Frances took between August 25, 2004, and September 9, 2004. The red path is Hurricane Ivan from September 2, 2004, to September 19, 2004. |
| Completed |
2004-09-16 |
|
Hurricane Ivan Rainfall Stru
…
| Title |
Hurricane Ivan Rainfall Structure with Cloud Overlay on September 16, 2004 |
| Abstract |
NASA's TRMM spacecraft is used by meteorologists to understand Hurricane Ivan. TRMM observed this view of Hurricane Ivan as the storm made landfall on September 16, 2004. The cloud cover is taken by TRMM's Visible and Infrared Scanner(VIRS). The rain structure is taken by TRMM's Tropical Microwave Imager (TMI). It looks underneath of the storm's clouds to reveal the underlying rain structure. Blue represents areas with at least 0.25 inches of rain per hour. Green shows at least 0.5 inches of rain per hour. Yellow is at least 1.0 inches of rain and red is at least 2.0 inches of rain per hour. |
| Completed |
2005-06-03 |
|
Hurricane Ivan Rainfall Stru
…
| Title |
Hurricane Ivan Rainfall Structure with Cloud Overlay on September 16, 2004 |
| Abstract |
NASA's TRMM spacecraft is used by meteorologists to understand Hurricane Ivan. TRMM observed this view of Hurricane Ivan as the storm made landfall on September 16, 2004. The cloud cover is taken by TRMM's Visible and Infrared Scanner(VIRS). The rain structure is taken by TRMM's Tropical Microwave Imager (TMI). It looks underneath of the storm's clouds to reveal the underlying rain structure. Blue represents areas with at least 0.25 inches of rain per hour. Green shows at least 0.5 inches of rain per hour. Yellow is at least 1.0 inches of rain and red is at least 2.0 inches of rain per hour. |
| Completed |
2005-06-03 |
|
Hurricane Ivan Rainfall Stru
…
| Title |
Hurricane Ivan Rainfall Structure seen by TRMM on September 16, 2004 |
| Abstract |
NASA's TRMM spacecraft is used by meteorologists to understand Hurricane Ivan. TRMM snapped this view of Hurricane Ivan on September 15, 2004, just before the storm strikes land. The cloud cover is taken by TRMM's Visible and Infrared Scanner (VIRS). The rain structure is taken by TRMM's Tropical Microwave Imager (TMI). It looks underneath of the storm's clouds to reveal the underlying rain structure. Blue represents areas with at least 0.25 inches of rain per hour. Green shows at least 0.5 inches of rain per hour. Yellow is at least 1.0 inches of rain and red is at least 2.0 inches of rain per hour. |
| Completed |
2004-09-16 |
|
Hurricane Ivan Rainfall Stru
…
| Title |
Hurricane Ivan Rainfall Structure seen by TRMM on September 16, 2004 |
| Abstract |
NASA's TRMM spacecraft is used by meteorologists to understand Hurricane Ivan. TRMM snapped this view of Hurricane Ivan on September 15, 2004, just before the storm strikes land. The cloud cover is taken by TRMM's Visible and Infrared Scanner (VIRS). The rain structure is taken by TRMM's Tropical Microwave Imager (TMI). It looks underneath of the storm's clouds to reveal the underlying rain structure. Blue represents areas with at least 0.25 inches of rain per hour. Green shows at least 0.5 inches of rain per hour. Yellow is at least 1.0 inches of rain and red is at least 2.0 inches of rain per hour. |
| Completed |
2004-09-16 |
|
Hurricane Ivan Rainfall Stru
…
| Title |
Hurricane Ivan Rainfall Structure seen by TRMM on September 16, 2004 |
| Abstract |
NASA's TRMM spacecraft is used by meteorologists to understand Hurricane Ivan. TRMM snapped this view of Hurricane Ivan on September 15, 2004, just before the storm strikes land. The cloud cover is taken by TRMM's Visible and Infrared Scanner (VIRS). The rain structure is taken by TRMM's Tropical Microwave Imager (TMI). It looks underneath of the storm's clouds to reveal the underlying rain structure. Blue represents areas with at least 0.25 inches of rain per hour. Green shows at least 0.5 inches of rain per hour. Yellow is at least 1.0 inches of rain and red is at least 2.0 inches of rain per hour. |
| Completed |
2004-09-16 |
|
Hurricane Ivan Rainfall Stru
…
| Title |
Hurricane Ivan Rainfall Structure seen by TRMM on September 16, 2004 |
| Abstract |
NASA's TRMM spacecraft is used by meteorologists to understand Hurricane Ivan. TRMM snapped this view of Hurricane Ivan on September 15, 2004, just before the storm strikes land. The cloud cover is taken by TRMM's Visible and Infrared Scanner (VIRS). The rain structure is taken by TRMM's Tropical Microwave Imager (TMI). It looks underneath of the storm's clouds to reveal the underlying rain structure. Blue represents areas with at least 0.25 inches of rain per hour. Green shows at least 0.5 inches of rain per hour. Yellow is at least 1.0 inches of rain and red is at least 2.0 inches of rain per hour. |
| Completed |
2004-09-16 |
|
Hurricane Ivan Rainfall Stru
…
| Title |
Hurricane Ivan Rainfall Structure seen by TRMM on September 16, 2004 |
| Abstract |
NASA's TRMM spacecraft is used by meteorologists to understand Hurricane Ivan. TRMM snapped this view of Hurricane Ivan on September 15, 2004, just before the storm strikes land. The cloud cover is taken by TRMM's Visible and Infrared Scanner (VIRS). The rain structure is taken by TRMM's Tropical Microwave Imager (TMI). It looks underneath of the storm's clouds to reveal the underlying rain structure. Blue represents areas with at least 0.25 inches of rain per hour. Green shows at least 0.5 inches of rain per hour. Yellow is at least 1.0 inches of rain and red is at least 2.0 inches of rain per hour. |
| Completed |
2004-09-16 |
|
| Photo Description |
Following initial captive flight tests last year at NASA's Dryden Flight Research Center, Edwards Air Force Base, California, the X-34 technology demonstrator began a new series of tests last week in which it is being towed behind a semi-truck and released to coast on the Edwards dry lakebed. On July 20, 2000, it was towed and released twice at speeds of five and 10 miles per hour. On July 24, 2000, it was towed and released twice at 10 and 30 miles per hour. Twelve tests are planned during which the X-34 will be towed for distances up to 10,000 feet and released at speeds up to 80 miles per hour. The test series is expected to last at least six weeks. |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
July 20, 2000 |
|
| Photo Description |
Following initial captive flight tests last year at NASA's Dryden Flight Research Center, Edwards Air Force Base, California, the X-34 technology demonstrator began a new series of tests last week in which it is being towed behind a semi-truck and released to coast on the Edwards dry lakebed. On July 20, 2000, it was towed and released twice at speeds of five and 10 miles per hour. On July 24, 2000, it was towed and released twice at 10 and 30 miles per hour. Twelve tests are planned during which the X-34 will be towed for distances up to 10,000 feet and released at speeds up to 80 miles per hour. The test series is expected to last at least six weeks. |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
July 20, 2000 |
|
| Photo Description |
Following initial captive flight tests last year at NASA's Dryden Flight Research Center, Edwards Air Force Base, California, the X-34 technology demonstrator began a new series of tests last week in which it is being towed behind a semi-truck and released to coast on the Edwards dry lakebed. On July 20, 2000, it was towed and released twice at speeds of five and 10 miles per hour. On July 24, 2000, it was towed and released twice at 10 and 30 miles per hour. Twelve tests are planned during which the X-34 will be towed for distances up to 10,000 feet and released at speeds up to 80 miles per hour. The test series is expected to last at least six weeks. |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
July 20, 2000 |
|
| Photo Description |
Following initial captive flight tests last year at NASA's Dryden Flight Research Center, Edwards Air Force Base, California, the X-34 technology demonstrator began a new series of tests last week in which it is being towed behind a semi-truck and released to coast on the Edwards dry lakebed. On July 20, 2000, it was towed and released twice at speeds of five and 10 miles per hour. On July 24, 2000, it was towed and released twice at 10 and 30 miles per hour. Twelve tests are planned during which the X-34 will be towed for distances up to 10,000 feet and released at speeds up to 80 miles per hour. The test series is expected to last at least six weeks. |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
July 20, 2000 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
30 Apr 1999 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
30 Apr 1999 |
|
| Photo Description |
This is the X-34 Technology Testbed Demonstrator being delivered to NASA Dryden FRC. The X-34 will demonstrate key vehicle and operational technologies applicable to future low-cost resuable launch vehicles. |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
16 Apr 1999 |
|
| Photo Description |
This is the X-34 Technology Testbed Demonstrator being mated with the L-1011 mothership. The X-34 will demonstrate key vehicle and operational technologies applicable to future low-cost resuable launch vehicles. |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
March 11, 1999 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
30 Apr 1999 |
|
| Photo Description |
This is the X-34 Technology Testbed Demonstrator being delivered to NASA Dryden FRC. The X-34 will demonstrate key vehicle and operational technologies applicable to future low-cost resuable launch vehicles. |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
16 Apr 1999 |
|
| Photo Description |
This is the X-34 Technology Testbed Demonstrator being delivered to NASA Dryden FRC. The X-34 will demonstrate key vehicle and operational technologies applicable to future low-cost resuable launch vehicles. |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
16 Apr 1999 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
30 Apr 1999 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
30 Apr 1999 |
|
| Photo Description |
This is the X-34 Technology Testbed Demonstrator being delivered to NASA Dryden FRC. The X-34 will demonstrate key vehicle and operational technologies applicable to future low-cost resuable launch vehicles. |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
1999 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
30 Apr 1999 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
30 Apr 1999 |
|
| Photo Description |
This is the X-34 Technology Testbed Demonstrator being delivered to NASA Dryden FRC. The X-34 will demonstrate key vehicle and operational technologies applicable to future low-cost resuable launch vehicles. |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
16 Apr 1999 |
|
| Photo Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Project Description |
unknown |
| Photo Date |
30 Apr 1999 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
30 Apr 1999 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
April 16, 1999 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
June 29, 1999 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
June 29, 1999 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
1999 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
October 1999 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
30 Apr 1999 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
June 29, 1999 |
|
| Photo Description |
unknown |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
October 1999 |
|
| Photo Description |
This is an artist concept of the X-34 Technology Testbed Demonstrator. The X-34 will demonstrate key vehicle and operational technologies applicable to future low-cost resuable launch vehicles. |
| Project Description |
The unpiloted X-34 is a technology testbed demonstrator that is designed to demonstrate key vehicle and operational technologies applicable to future low-cost reusable launch vehicles. The vehicle structure is all-composite with a one-piece delta wing design. The vehicle is 58.3 feet long and has a 27.7-foot wingspan. The suborbital vehicle was designed and built by Orbital Sciences Corporation, Dulles, Virginia, and is powered by an oxygen and kerosene Fastrac engine that was designed and built by NASA?s Marshall Space Flight Center (MSFC), Huntsville, Alabama. Fastrac is only the second American-made engine of the 29 engines developed in the last 25 years. The vehicle is designed to reach speeds of up to Mach 8 and altitudes of up to approximately 250,000 feet. Specific technologies built into the vehicle include composite structures, composite reusable propellant fuel tanks, an advanced thermal protection system, low-cost avionics, leading-edge tiles, and autonomous flight operation systems. The project?s goal is to reduce the cost of launching payloads into orbit from $10,000 per pound today to one of $1,000 per pound, thereby improving U.S. economic competitiveness. NASA and Orbital, using a small workforce, plan to demonstrate the ability to fly the X-34 every two weeks. The X-34 was expected in early 2000 to undergo testing in New Mexico, California, and Florida. The first of three X-34 vehicles, a structural test vehicle designated A-1, began captive-carry flights at Edwards Air Force Base, California, in June 1999. Technicians from Dryden Flight Research Center, Edwards, California, have assisted in upgrading the A-1 vehicle with structural modifications and integrating avionics, hydraulics, landing gear, and other hardware needed to turn it into a flight vehicle--now known as A-1A--for unpowered glide tests in New Mexico. Following a series of tow tests on the ground at Dryden, the X-34 A-1A will be used to conduct unpowered test flights at the U.S. Army?s White Sands Missile Range, New Mexico, according to plans current in early 2000. This test series was expected to use Orbital?s L-1011 carrier aircraft to air-launch the X-34. Powered flights, using the second and third vehicle (designated A-2 and A-3 respectively), are scheduled to be conducted at the Dryden Flight Research Center, California, and the Kennedy Space Center, Florida. The X-34 vehicle A-3 was expected in early 2000 to be brought to Dryden for envelope expansion to the maximum capability of an approximate speed of Mach 8 and altitude of 250,000 feet. Plans called for A-3 to explore additional reusable launch vehicle technologies as carry-on experiments. Dryden?s project manger was Seunghee Lee as of early 2000. |
| Photo Date |
1999 |
|
Launch of Jupiter-C/Explorer
…
| Name of Image |
Launch of Jupiter-C/Explorer 1 |
| Date of Image |
1958-01-31 |
| Full Description |
Launch of Jupiter-C/Explorer 1 at Cape Canaveral, Florida on January 31, 1958. After the Russian Sputnik 1 was launched in October 1957, the launching of an American satellite assumed much greater importance. After the Vanguard rocket exploded on the pad in December 1957, the ability to orbit a satellite became a matter of national prestige. On January 31, 1958, slightly more than four weeks after the launch of Sputnik.The ABMA (Army Ballistic Missile Agency) in Redstone Arsenal, Huntsville, Alabama, in cooperation with the Jet Propulsion Laboratory, launched a Jupiter from Cape Canaveral, Florida. The rocket consisted of a modified version of the Redstone rocket's first stage and two upper stages of clustered Baby Sergeant rockets developed by the Jet Propulsion Laboratory and later designated as Juno boosters for space launches |
|
Launch, Jupiter-C, Explorer
…
| Name of Image |
Launch, Jupiter-C, Explorer 1 |
| Date of Image |
1958-01-31 |
| Full Description |
Launch of Jupiter-C/Explorer 1 at Cape Canaveral, Florida on January 31, 1958. After the Russian Sputnik 1 was launched in October 1957, the launching of an American satellite assumed much greater importance. After the Vanguard rocket exploded on the pad in December 1957, the ability to orbit a satellite became a matter of national prestige. On January 31, 1958, slightly more than four weeks after the launch of Sputnik.The ABMA (Army Ballistic Missile Agency) in Redstone Arsenal, Huntsville, Alabama, in cooperation with the Jet Propulsion Laboratory, launched a Jupiter from Cape Canaveral, Florida. The rocket consisted of a modified version of the Redstone rocket's first stage and two upper stages of clustered Baby Sergeant rockets developed by the Jet Propulsion Laboratory and later designated as Juno boosters for space launches |
|
U.S. Army Redstone Rocket
| Name of Image |
U.S. Army Redstone Rocket |
| Date of Image |
1953-08-30 |
| Full Description |
U.S. Army Redstone Rocket: The Redstone ballistic missile was a high-accuracy, liquid-propelled, surface-to-surface missile developed by the Army Ballistic Missile Agency, Redstone Arsenal, in Huntsville, Alabama, under the direction of Dr. von Braun. The Redstone rocket was also known as "Old Reliable" because of its many diverse missions. The first Redstone Missile was launched from Cape Canaveral, Florida on August 30, 1953. |
|
NASA Studies Lightning Storm
…
| Name of Image |
NASA Studies Lightning Storms Using High-Flying, Uninhabited Vehicle |
| Date of Image |
2001-01-01 |
| Full Description |
A NASA team studying the causes of electrical storms and their effects on our home planet achieved a milestone on August 21, 2002, completing the study's longest-duration research flight and monitoring four thunderstorms in succession. Radio news media can talk with Dr. Richard Blakeslee, the project's principal investigator, and Tony Kim, project manager at the Marshall Space Flight Center (MSFC), about their results and how their work will help improve future weather forecasting ability. Based at the Naval Air Station Key West, Florida, researchers with the Altus Cumulus Electrification Study (ACES) used the Altus II remotely- piloted aircraft to study a thunderstorm in the Atlantic Ocean off Key West, two storms at the western edge of the Everglades, and a large storm over the northwestern corner of the Everglades. This photograph shows Tony Kim And Dr. Richard Blakeslee of MSFC testing aircraft sensors that would be used to measure the electric fields produced by thunderstorm as part of NASA's ACES. With dual goals of gathering weather data safely and testing the adaptability of the uninhabited aircraft, the ACES study is a collaboration among the MSFC, the University of Alabama in Huntsville, NASA's Goddard Space Flight Center in Greenbelt, Maryland, Pernsylvania State University in University Park, and General Atomics Aeronautical Systems, Inc. |
|
NASA Studies Lightning Storm
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| Name of Image |
NASA Studies Lightning Storms Using High-Flying, Uninhabited Vehicle |
| Date of Image |
2002-08-01 |
| Full Description |
A NASA team studying the causes of electrical storms and their effects on our home planet achieved a milestone on August 21, 2002, completing the study's longest-duration research flight and monitoring four thunderstorms in succession. Based at the Naval Air Station Key West, Florida, researchers with the Altus Cumulus Electrification Study (ACES) used the Altus II remotely-piloted aircraft to study thunderstorms in the Atlantic Ocean off Key West and the west of the Everglades. The ACES lightning study used the Altus II twin turbo uninhabited aerial vehicle, built by General Atomics Aeronautical Systems, Inc. of San Diego. The Altus II was chosen for its slow flight speed of 75 to 100 knots (80 to 115 mph), long endurance, and high-altitude flight (up to 65,000 feet). These qualities gave the Altus II the ability to fly near and around thunderstorms for long periods of time, allowing investigations to be to be conducted over the entire life cycle of storms. The vehicle has a wing span of 55 feet and a payload capacity of over 300 lbs. With dual goals of gathering weather data safely and testing the adaptability of the uninhabited aircraft, the ACES study is a collaboration among the Marshall Space Flight Center, the University of Alabama in Huntsville, NASA,s Goddard Space Flight Center in Greenbelt, Maryland, Pernsylvania State University in University Park, and General Atomics Aeronautical Systems, Inc. |
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NASA Studies Lightning Storm
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| Name of Image |
NASA Studies Lightning Storms Using High-Flying, Uninhabited Vehicle |
| Date of Image |
2002-08-01 |
| Full Description |
A NASA team studying the causes of electrical storms and their effects on our home planet achieved a milestone on August 21, 2002, completing the study's longest-duration research flight and monitoring four thunderstorms in succession. Based at the Naval Air Station Key West, Florida, researchers with the Altus Cumulus Electrification Study (ACES) used the Altus II remotely-piloted aircraft to study thunderstorms in the Atlantic Ocean off Key West and the west of the Everglades. Using special equipment aboard the Altus II, scientists in ACES will gather electric, magnetic, and optical measurements of the thunderstorms, gauging elements such as lightning activity and the electrical environment in and around the storms. With dual goals of gathering weather data safely and testing the adaptability of the uninhabited aircraft, the ACES study is a collaboration among the Marshall Space Flight Center, the University of Alabama in Huntsville, NASA's Goddard Space Flight Center in Greenbelt, Maryland, Pernsylvania State University in University Park, and General Atomics Aeronautical Systems, Inc. |
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