Мы используем файлы cookie.
Продолжая использовать сайт, вы даете свое согласие на работу с этими файлами.

STS-107

Подписчиков: 0, рейтинг: 0

STS-107
Spacehab S107e05359.jpg
Spacehab's Research Double Module in Columbia's payload bay during STS-107
Names Space Transportation System-113
Mission type Microgravity research
Operator NASA
COSPAR ID 2003-003A
SATCAT no. 27647
Mission duration 15 days, 22 hours, 20 minutes, 32 seconds
Distance travelled 6,600,000 miles (10,600,000 km)
Orbits completed 255
Spacecraft properties
Spacecraft Space Shuttle Columbia
Launch mass 263,706 pounds (119,615 kg)
Landing mass 232,793 pounds (105,593 kg) (expected)
Payload mass 32,084 pounds (14,553 kg)
Crew
Crew size 7
Members
Start of mission
Launch date January 16, 2003 15:39:00 (2003-01-16UTC15:39Z) UTC
Launch site Kennedy LC-39A
End of mission
Decay date February 1, 2003, 13:59:32 (2003-02-01UTC13:59:33Z) UTC
Disintegrated during reentry
Landing site Kennedy SLF Runway 33 (planned)
Orbital parameters
Reference system Geocentric
Regime Low Earth
Perigee altitude 170 miles (270 km)
Apogee altitude 177 miles (285 km)
Inclination 39.0 degrees
Period 90.1 minutes
STS-107 Flight Insignia.svg Crew of STS-107, official photo.jpg
Rear (L-R): David Brown, Laurel Clark, Michael Anderson, Ilan Ramon;
Front (L-R): Rick Husband, Kalpana Chawla, William McCool
 

STS-107 was the 113th flight of the Space Shuttle program, and the 28th flight of Space Shuttle Columbia. The mission ended, on February 1, 2003, with the Space Shuttle Columbia disaster which killed all seven crew members and destroyed the space shuttle. It was the 88th post-Challenger disaster mission.

The flight launched from Kennedy Space Center in Florida on January 16, 2003. It spent 15 days, 22 hours, 20 minutes, 32 seconds in orbit. The crew conducted a multitude of international scientific experiments. The disaster occurred during reentry while the Columbia was over Texas.

Immediately after the disaster, NASA convened the Columbia accident Investigation Board to determine the cause of the disintegration. The source of the failure was determined to have been caused by a piece of foam that broke off during launch and damaged the thermal protection system (reinforced carbon-carbon panels and thermal protection tiles) on the leading edge of the orbiter's left wing. During re-entry the damaged wing slowly overheated and came apart, eventually leading to loss of control and disintegration of the vehicle. The cockpit window frame is now exhibited in a memorial inside the Space Shuttle Atlantis Pavilion at the Kennedy Space Center.

The damage to the thermal protection system on the wing was similar to that Atlantis had sustained in 1988 during STS-27, the second mission after the Space Shuttle Challenger disaster. However, the damage on STS-27 occurred at a spot that had more robust metal (a thin steel plate near the landing gear), and that mission survived the re-entry.

Mission highlights

STS-107 carried the SPACEHAB Double Research Module on its inaugural flight, the Freestar experiment (mounted on a Hitchhiker Program rack), and the Extended Duration Orbiter pallet. SPACEHAB was first flown on STS-57.

One of the experiments, a video taken to study atmospheric dust, may have detected a new atmospheric phenomenon, dubbed a "TIGER" (Transient Ionospheric Glow Emission in Red).

On board Columbia was a copy of a drawing by Petr Ginz, the editor-in-chief of the magazine Vedem, who depicted what he imagined the Earth looked like from the Moon when he was a 14-year-old prisoner in the Terezín concentration camp. The copy was in the possession of Ilan Ramon and was lost in the disintegration. Ramon also traveled with a dollar bill received from the Lubavitcher Rebbe.

An Australian experiment, created by students from Glen Waverley Secondary College, was designed to test the reaction of zero gravity on the web formation of the Australian garden orb weaver spider.

Major experiments

Examples of some of the experiments and investigations on the mission.

In SPACEHAB RDM:

  • 9 commercial payloads with 21 investigations,
  • 4 payloads for the European Space Agency with 14 investigations
  • 1 payload for ISS Risk Mitigation
  • 18 payloads NASA's Office of Biological and Physical Research (OBPR) with 23 investigations

In the payload bay attached to RDM:

  • Combined Two-Phase Loop Experiment (COM2PLEX),
  • Miniature Satellite Threat Reporting System (MSTRS)
  • Star Navigation (STARNAV).

FREESTAR

  • Critical Viscosity of Xenon- 2 (CVX-2)
  • Low Power Transceiver (LPT)
  • Mediterranean Israeli Dust Experiment (MEIDEX)
  • Space Experiment Module (SEM- 14)
  • Solar Constant Experiment-3 (SOLCON-3)
  • Shuttle Ozone Limb Sounding Experiment (SOLSE-2)

Additional payloads

  • Shuttle Ionospheric Modification with Pulsed Local Exhaust Experiment (SIMPLEX)
  • Ram Burn Observation (RAMBO).

Because much of the data was transmitted during the mission, there was still large return on the mission objectives even though Columbia was lost on re-entry. NASA estimated that 30% of the total science data was saved and collected through telemetry back to ground stations. Around 5-10% more data was saved and collected through recovering samples and hard drives intact on the ground after the Space Shuttle Columbia disaster, increasing the total data of saved experiments despite the disaster from 30% to 35-40%.

About 5-6 Columbia payloads encompassing many experiments were successfully recovered in the debris field. Scientists and engineers were able to recover 99% of the data for one of the six FREESTAR experiments, Critical Viscosity of Xenon-2 (CVX-2), that flew unpressurized in the payload bay during the mission after recovering the viscometer and hard drive damaged but fully intact in the debris field in Texas. NASA recovered a commercial payload, Commercial Instrumentation Technology Associates (ITA) Biomedical Experiments-2 (CIBX-2), and ITA was able to increase the total data saved from STS-107 from 0% to 50% for this payload. This experiment studied treatments for cancer, and the micro-encapsulation experiment part of the payload was completely recovered, increasing from 0% data to 90% data after recovering the samples fully intact for this experiment. In this same payload were numerous crystal-forming experiments by hundreds of elementary and middle school students from all across the United States. Miraculously most of their experiments were found intact in CIBX-2, increasing from 0% data to 100% fully recovered data. The BRIC-14 (moss growth experiment) and BRIC-60 (Caenorhabditis elegans ringworm experiment) samples were found intact in the debris field within a 12 miles (19 km) radius in east Texas. 80-87% of these live organisms survived the catastrophe. The moss and ringworms experiments' original primary mission was not nominal due to the lack of having the samples immediately after landing in its original state (they were discovered many months after the crash), but these samples helped the scientific community greatly in the field of astrobiology and helped form new theories about microorganisms surviving a long trip in outer space while traveling on meteorites or asteroids.

Re-entry

FLIR imaging photograph of Columbia's disintegration captured by an AH-64D Apache's FLIR camera during training with RNLAF (Royal Netherlands Air Force) personnel out of Fort Hood, Texas.

KSC landing was planned for Feb. 1 after a 16-day mission, but Columbia and crew were lost during re-entry over East Texas at about 9 a.m. EST, 16 minutes prior to the scheduled touchdown at KSC.

— NASA

Columbia began re-entry as planned, but the heat shield was compromised due to damage sustained during the initial ascent. The heat of re-entry was free to spread into the damaged portion of the orbiter, ultimately causing its disintegration and the loss of all hands.

The accident triggered a 7-month investigation and a search for debris, and over 85,000 pieces were collected over the course of the initial investigation. This amounted to roughly 38 percent of the orbiter vehicle.

Crew

Position Astronaut
Commander United States Rick D. Husband, USAF
Second and last spaceflight
Pilot United States William C. McCool, USN
Only spaceflight
Mission Specialist 1 United States David M. Brown, USN
Only spaceflight
Mission Specialist 2 United States Kalpana Chawla
Second and last spaceflight
Mission Specialist 3 United States Michael P. Anderson, USAF
Second and last spaceflight
Mission Specialist 4 United States Laurel B. Clark, USN
Only spaceflight
Payload Specialist 1 Israel Ilan Ramon, IAF
Only spaceflight

Insignia

STS-107 Robbins Medallion

The mission insignia itself is the only patch of the shuttle program that is entirely shaped in the orbiter's outline. The central element of the patch is the microgravity symbol, µg, flowing into the rays of the astronaut symbol.

The mission inclination is portrayed by the 39-degree angle of the astronaut symbol to the Earth's horizon. The sunrise is representative of the numerous experiments that are the dawn of a new era for continued microgravity research on the International Space Station and beyond. The breadth of science and the exploration of space is illustrated by the Earth and stars. The constellation Columba (the dove) was chosen to symbolize peace on Earth and the Space Shuttle Columbia. The seven stars also represent the mission crew members and honor the original astronauts who paved the way to make research in space possible. Six stars have five points, the seventh has six points like a Star of David, symbolizing the Israeli Space Agency's contributions to the mission.

An Israeli flag is adjacent to the name of Payload Specialist Ramon, who was the first Israeli in space. The crew insignia or 'patch' design was initiated by crew members Dr. Laurel Clark and Dr. Kalpana Chawla. First-time crew member Clark provided most of the design concepts as Chawla led the design of her maiden voyage STS-87 insignia. Clark also pointed out that the dove in the Columba constellation was mythologically connected to the explorers the Argonauts who released the dove.

Gallery

See also

Public Domain This article incorporates public domain material from websites or documents of the National Aeronautics and Space Administration.

Literature

External links


Новое сообщение