Long Duration Exposure Facility Explained

Long Duration Exposure Facility
Mission Type:Materials research
Operator:NASA
Cospar Id:1984-034B
Satcat:14898
Mission Duration:2076 days
Orbits Completed:32,422
Distance Travelled:1374052506km (853,796,644miles)
Manufacturer:Langley
Dry Mass:3629kg (8,001lb)[1]
Launch Mass:9724kg (21,438lb)
Launch Date: UTC
Launch Rocket:
STS-41-C
Launch Site:Kennedy LC-39A
Recovery By:
STS-32
Recovery Date: UTC
Landing Date:January 20, 1990, 09:35:37 UTC
Landing Site:Edwards Runway 22
Orbit Reference:Geocentric
Orbit Regime:Low Earth
Orbit Periapsis:473km (294miles)
Orbit Apoapsis:483km (300miles)
Orbit Inclination:28.5 degrees
Orbit Eccentricity:7.29E-4
Orbit Period:94.2 minutes
Apsis:gee

NASA's Long Duration Exposure Facility, or LDEF (pronounced "eldef"), was a cylindrical facility designed to provide long-term experimental data on the outer space environment and its effects on space systems, materials, operations and selected spores' survival.[2] [3] It was placed in low Earth orbit by in April 1984. The original plan called for the LDEF to be retrieved in March 1985, but after a series of delays it was eventually returned to Earth by in January 1990.[3]

It successfully carried science and technology experiments for about 5.7 years that have revealed a broad and detailed collection of space environmental data. LDEF's 69 months in space provided scientific data on the long-term effects of space exposure on materials, components and systems that has benefited NASA spacecraft designers to this day.

History

Researchers identified the potential of the planned Space Shuttle to deliver a payload to space, leave it there for a long-term exposure to the harsh outer space environment, and retrieve it for analysis on a separate mission. The LDEF concept evolved from a spacecraft proposed by NASA's Langley Research Center in 1970 to study the meteoroid environment, the Meteoroid and Exposure Module (MEM).[2] The project was approved in 1974 and LDEF was built at NASA's Langley Research Center.

LDEF was intended to be reused, and redeployed with new experiments, perhaps every 18 months.[4] but after the unintended extension of mission 1 the structure itself was treated as an experiment and intensively studied before being placed into storage.

Launch and deployment

The STS-41-C crew of deployed LDEF on April 7, 1984, into a nearly circular orbit at an altitude of 257 nautical miles.

Design and structure

The LDEF structure shape was a 12 sided prism (to fit the shuttle orbiter payload bay), and made entirely from stainless steel. There were 5 or 6 experiments on each of the 12 long sides and a few more on the ends. It was designed to fly with one end facing earth and the other away from earth. Attitude control of LDEF was achieved with gravity-gradient stabilization and inertial distribution to maintain three-axis stability in orbit. Therefore, propulsion or other attitude control systems were not required, making LDEF free of acceleration forces and contaminants from jet firings. There was also a magnetic/viscous damper to stop any initial oscillation after deployment.

It had two grapple fixtures. An FRGF and an active (rigidize sensing) grapple used to send an electronic signal to initiate the 19 experiments that had electrical systems.[5] This activated the Experiment Initiate System (EIS) which sent 24 initiation signals to the 20 active experiments. There were six initiation indications which were visible to the deploying astronauts next to the active grapple fixture.

Engineers originally intended that the first mission would last about one year, and that several long-duration exposure missions would use the same frame. The exposure facility was actually used for a single 5.7-year mission.

Experiments

The LDEF facility was designed to glean information vital to the development of the Space Station Freedom (that was eventually built as the International Space Station) and other spacecraft, especially the reactions of various space building materials to radiation, extreme temperature changes and collisions with space matter.

Some of the experiments had a cover that opened after deployment and was designed to close after about a year,[6] e.g., Space Environment Effects (M0006).[7]

There was no telemetry, but some active experiments recorded data on a magnetic tape recorder that was powered by a lithium sulfur dioxide battery, e.g., the Advanced Photovoltaic Experiment (S0014), which recorded data once a day,[8] the German Solar cell study (S1002), and the Space Environment Effects on Fiber Optics Systems (M004).[7]

Six of the seven active experiments that needed to record data used one or two Experiment Power and Data System (EPDS) modules. Each EPDS contained a processing and control module, a magnetic tape recorder and two LiSO2 batteries.[9] One experiment (S0069) used a 4-track magnetic tape module not as part of an EPDS.

Fifty-seven science and technology experiments — involving government and university investigators from the United States, Canada, Denmark, France, Germany, Ireland, the Netherlands, Switzerland, and the United Kingdom — flew on the LDEF mission.[3] Interstellar gases also would be trapped in an attempt to find clues into the formation of the Milky Way and the evolution of heavier elements. Some examples are investigation of exposure effects on:

and physics in low gravity – e.g. crystal growth.[10]

At least one of the on-board experiments, the Thermal Control Surfaces Experiment (TCSE), used the RCA 1802 microprocessor.[11]

Experiment results

EXOSTACK

In the German experiment EXOSTACK, 30% of Bacillus subtilis spores survived the nearly 6 years exposure to outer space when embedded in salt crystals, whereas 80% survived in the presence of glucose, which stabilize the structure of the cellular macromolecules, especially during vacuum-induced dehydration.[12] [13]

If shielded against solar UV, spores of B. subtilis were capable of surviving in space for up to 6 years, especially if embedded in clay or meteorite powder (artificial meteorites). The data may support the likelihood of interplanetary transfer of microorganisms within meteorites, the so-called lithopanspermia hypothesis.[13]

SEEDS

The Space Exposed Experiment Developed for Students (SEEDS) allowed students the opportunity to grow control and experimental tomato seeds that had been exposed on LDEF comparing and reporting the results. 12.5 million seeds were flown, and students from elementary to graduate school returned 8000 reports to NASA. The L.A. Times misreported that a DNA mutation from space exposure could yield a poisonous fruit. While incorrect, the report served to raise awareness of the experiment and generate discussion.[14] Space seeds germinated sooner and grew faster than the control seeds. Space seeds were more porous than terrestrial seeds.[15]

Retrieval

At LDEF's launch, retrieval was scheduled for March 19, 1985, eleven months after deployment.[16] Schedules slipped, postponing the retrieval mission first to 1986, then indefinitely due to the Challenger disaster. After 5.7 years its orbit had decayed to about 175 nautical miles and it was likely to burn up on reentry in a little over a month.[17] [18]

It was finally recovered by on mission STS-32 on January 12, 1990.[19] Columbia approached LDEF in such a way as to minimize possible contamination to LDEF from thruster exhaust.[20] While LDEF was still attached to the RMS arm, an extensive 4.5 hour survey photographed each individual experiment tray, as well as larger areas.[20] Nevertheless, shuttle operations did contaminate experiments when concerns for human comfort out-weighed important LDEF mission goals.[21]

Columbia landed at Edwards Air Force Base on January 20, 1990.[16] With LDEF still in its bay, Columbia was ferried back on the Shuttle Carrier Aircraft to the Kennedy Space Center on January 26. Special efforts were taken to ensure protection against contamination of the payload bay during the ferry flight.[16]

Between January 30 and 31, LDEF was removed from Columbia's payload bay in KSC's Orbiter Processing Facility, placed in a special payload canister, and transported to the Operations and Checkout Building. On February 1, 1990, LDEF was transported in the LDEF Assembly and Transportation System to the Spacecraft Assembly and Encapsulation Facility – 2, where the LDEF project team led deintegration activities.[20]

Notes and References

  1. Web site: Long Duration Exposure Facility (LDEF) . NASA.
  2. Web site: The Long Duration Exposure Facility . 2013-07-29 . NASA . Langley Research Center . dead . https://web.archive.org/web/20131031184938/http://setas-www.larc.nasa.gov/LDEF/ . 2013-10-31 .
  3. Web site: Long Duration Exposure Facility (LDEF) . 2014-01-22 . Allen . Carlton . NASA.
  4. https://history.nasa.gov/SP-473/intro.htm LDEF intro
  5. https://web.archive.org/web/20160422155832/http://setas-www.larc.nasa.gov/LDEF/OVERVIEW/structure.html LDEF structure
  6. https://web.archive.org/web/20160422220813/http://setas-www.larc.nasa.gov/LDEF/OVERVIEW/tande.html LDEF Trays and Experiments
  7. https://history.nasa.gov/SP-473/ch4.htm#185 Electronics and Optics
  8. https://history.nasa.gov/SP-473/ch2.htm#88 Advanced Photovoltaic Experiment (S0014)
  9. http://adsabs.harvard.edu/full/1991NASCP3134.1533M LDEF Electronic Systems: Successes, Failures and Lessons, Miller et al. 1991
  10. https://history.nasa.gov/SP-473/ch1.1.htm#8 Growth of Crystals From Solutions in Low Gravity (A0139A)
  11. Web site: Thermal Control Surfaces Experiment (TCSE). NASA Online Archives. January 1999 . NASA. 21 May 2016. Wilkes . D. R. .
  12. Book: Paul Clancy . Looking for Life, Searching the Solar System . . Jun 23, 2005 .
  13. Space Microbiology . Microbiology and Molecular Biology Reviews . March 2010 . Gerda . Horneck . David M. Klaus . Rocco L. Mancinelli . 74 . 1 . 121–156 . 10.1128/mmbr.00016-09 . 20197502 . 2832349. 2010MMBR...74..121H .
  14. Web site: Attack of the Killer Space Tomatoes? Not! . Sindelar . Terri . NASA . Washington, D.C. . April 17, 1992.
  15. Hammond EC, Bridgers K, Berry FD . Germination, growth rates, and electron microscope analysis of tomato seeds flown on the LDEF . Radiat Meas . 26 . 6 . 851–61 . 1996 . 11540518 . 10.1016/S1350-4487(96)00093-5. 1996RadM...26..851H . 2060/19950017401 . 42665560 . free .
  16. News: Kay . Grinter . Retrieval of LDEF provided resolution, better data . 8 January 2010 . NASA . Spaceport News . 7 . 2014-01-22.
  17. https://web.archive.org/web/20160529014413/http://setas-www.larc.nasa.gov/LDEF/ archive of larc LDEF
  18. Dursch. Harry W.. Spear. W. Steve. Miller. Emmett A.. Bohnhoff-Hlavacek. Gail L.. Edelman . Joel. Analysis of systems hardware flown on LDEF. Results of the systems special investigation group. NASA Sti/Recon Technical Report N . April 1992. 92 . 31677 . 1992STIN...9231677D . November 11, 2022.
  19. Web site: LDEF Archive. Langley Research Center. July 16, 2010. dead. https://web.archive.org/web/20131031184938/http://setas-www.larc.nasa.gov/LDEF/. October 31, 2013.
  20. Web site: LDEF (Long Duration Exposure Facility) . 2014-01-22 . Kramer . Herbert J. . NASA . Earth Observation Portal.
  21. Web site: Zolensky. M.. Lessons Learned from Three Recent Sample Return Missions.