- Mir Docking Module
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Mir docking module 
The docking module seen in the payload bay of the Space Shuttle Atlantis on STS-74, prior to docking with Mir. Station statistics Part of: Mir Launch date: 12 November 1995 Launch vehicle: Space Shuttle Atlantis
(STS-74)Permanently docked: 15 November 1995 Reentry: 23 March 2001 Mass: 4.3 metric tonnes Length: 4.7 metres Diameter: 2.9 metres References: [1][2][3] Configuration 
The docking module shown isolated in its basic configuration. Various additional external fixtures are not shown. Mir docking module The Stykovochnyy Otsek (Russian: стыковочный отсек, English: Docking compartment), GRAU index 316GK, otherwise known as the Mir docking module or SO, was the sixth module of the Russian space station Mir, launched in November 1995 aboard the Space Shuttle Atlantis.[4] The module, built by RKK Energia, was designed to help simplify space shuttle dockings to Mir during the Shuttle-Mir programme, preventing the need for the periodic relocation of the Kristall module necessary for dockings prior to the compartment's arrival.[3] The module was also used to transport two new photovoltaic arrays to the station, as a mounting point for external experiments, and as a storage module when not in use for dockings.[1]
Contents
Development
The final configuration of Mir, showing the docking module (brown) with a docked Space Shuttle.
Interior of Docking Module
Docking Module cutaway
interior view of Rassvet, compared to the Mir Docking Module above
Rassvet a mirror image of the Mir Docking ModuleThe docking module originated in the 1992 design version of the cancelled Mir-2 space station, which featured a combined docking compartment and airlock to facilitate docking missions during the Soviet Buran space shuttle programme (this module, SO-1, was eventually incorporated into the Russian Orbital Segment of the International Space Station as Pirs). When the Shuttle-Mir programme began, engineers realised that in order to enable US space shuttles to dock to Mir, the Kristall module would have to be relocated to the forward port of the core module and back to its own lateral port each time a shuttle docked, a process which was not only time consuming but would also be entirely reliant on Kristall's Lyappa arm, which, should it fail, would prevent any further shuttle missions to the station. Adding a small extension to Kristall, however, would provide the shuttles the clearance they needed to dock without necessitating the relocation of the module on each occasion, and it was decided to base the design of the new module loosely on that of the Mir-2 docking compartment.[1]
Discussions on providing a docking module for the Shuttle-Mir programme began in May 1993 and approval was granted on 1 November, with the draft plan being developed by December. The module consisted of what were essentially two Soyuz TM-16 type Soyuz orbital modules cut in half, with a cylindrical central portion mounted in the centre of the two halves which incorporated docking apparatus (the other two halves were not used). An APAS-89 docking port was mounted on each end. Mounting points were also provided for two boxes (containing new solar arrays) and other external experiments, and the module was provided with its own thermal control, television transmission, and telemetry systems. Rather than being covered in a newly-manufactured white thermal blanket, the module was flown with an unusual orange blanket, which was selected from pre-existing stock for financial reasons.[5] Development of the simplified module was given priority over the more complex Mir-2 type SO-1, and the flight model, the first to make use of NASA's new Space Station Processing Facility, was delivered to Kennedy Space Centre on 7 June 1995 alongside the new solar arrays which were to be launched with it.[1]
The module was launched aboard the Space Shuttle Atlantis on 12 November 1995 on mission STS-74 and both the module and Atlantis docked to Mir on 15 November, leaving STS-71 as the only Shuttle-Mir docking mission requiring Kristall to be relocated.[6]
Solar arrays & MEEP
Main article: Mir Environmental Effects PayloadIn addition to simplifying space shuttle docking missions, Mir's docking module was also used as a carrier for two new photovoltaic arrays, mounted to the module in boxes, which were later deployed on Kvant-1 during spacewalks. The first, the Mir Cooperative Solar Array, was jointly designed by NASA and Russia in order to test designs for the future International Space Station. The array was 42 m² in area, and provided 6.7 kW of power when installed on the station during expedition EO-21 in 1996.[2][4] The array consisted of 42 US-built panels arranged in a 2.7 m (9 ft) wide and 18 m (59 ft) long array mounted to a Russian-built frame, and was instrumented to provide data for models being used to design the solar arrays for the ISS.[7] The second array was the Russian-built MSB array, which had originally been intended to be launched as part of Priroda before the redesign of the module deleted it.[1] It was installed on Kvant-1 during EVA 5 of EO-24, replacing the Kristall array which had previously been mounted there.[4]
The module was also used as a mounting point for the Mir Environmental Effects Payload (MEEP), a set of four experiments intended to study the effects of space debris impacts and exposure to the space environment on a variety of materials.[8] The materials used in the experiments were being considered for use on the ISS, and by exposing them at a similar orbital altitude to that flown by the station, the experiments provided an assessment of the performance of those materials in a similar space environment.[8] MEEP also fulfilled the need to examine the occurrence and effects of man-made debris and natural micrometeoroids through capture and impact studies.[8] The experiments were installed on the docking module during STS-76,[9] and retrieved during STS-86.[10]
Docking missions
Orbiter Mission Date docked (UTC) Date undocked (UTC) Notes Atlantis STS-74 14 November 1995 07:17 18 November 1995 08:15:44 The module was docked to Atlantis's orbiter docking system by the orbiter's SRMS robotic arm on 14 November, then both Atlantis and the module docked to the station the next day.[6] Atlantis STS-76 24 March 1996 02:34:05 29 March 1996 01:08:03 The crew of Atlantis installed the Mir Environmental Effects Payload (MEEP) on the exterior of the docking module.[9] Atlantis STS-79 19 September 1996 03:13:18 24 September 1996 01:31:34 [11] Atlantis STS-81 15 January 1997 03:54:49 20 January 1997 02:15:44 [12] Atlantis STS-84 17 May 1997 02:33:20 22 May 1997 01:03:56 [13] Atlantis STS-86 27 September 1997 19:58 3 October 1997 17:28:15 The crew of Atlantis retrieved the Mir Environmental Effects Payload (MEEP) from the exterior of the docking module.[10] Endeavour STS-89 24 January 1998 20:14:15 29 January 1998 16:56 [14] Discovery STS-91 4 June 1998 16:58 8 June 1998 16:01 [15] See also
References
- ^ a b c d e Hendrickx, Bart (2000). "The Development of Mir and its Modules". In Hall, Rex. The History of Mir 1986–2000. London: British Interplanetary Society. pp. 3–20. ISBN 0-9506597-4-6.
- ^ a b Wade, Mark (5 March 2011). "Mir-Shuttle Docking Module". Encyclopedia Astronautica. http://www.astronautix.com/craft/mirodule.htm. Retrieved 19 March 2011.
- ^ a b Anatoly Zak (26 January 2010). "Mir: Docking compartment". Russian Space Web. http://www.russianspaceweb.com/mir_docking.html. Retrieved 19 March 2011.
- ^ a b c Harland, David (30 November 2004). The Story of Space Station Mir. New York: Springer-Verlag New York Inc. ISBN 978-0-387-23011-5.
- ^ Linenger, Jerry (1 January 2001). Off the Planet: Surviving Five Perilous Months Aboard the Space Station Mir. New York, USA: McGraw-Hill. pp. 79–80. ISBN 978-0071372305.
- ^ a b "STS-74". NASA. 1 April 2010. http://www.nasa.gov/mission_pages/shuttle/shuttlemissions/archives/sts-74.html. Retrieved 20 March 2011.
- ^ "Mir Cooperative Solar Array". NASA. 1 May 1997. http://www.grc.nasa.gov/WWW/RT/RT1996/6000/6910s.htm. Retrieved 20 March 2011.
- ^ a b c "STS-76 Mir Environmental Effects Payload (MEEP)". NASA. March 1996. http://www.nasa.gov/centers/langley/news/releases/1996/Mar96/96_13.html. Retrieved 8 March 2011.
- ^ a b Jim Dumoulin (29 June 2001). "STS-76 Mission Summary". NASA. http://science.ksc.nasa.gov/shuttle/missions/sts-76/mission-sts-76.html. Retrieved 30 March 2007.
- ^ a b Jim Dumoulin (29 June 2001). "STS-86 Mission Summary". NASA. http://science.ksc.nasa.gov/shuttle/missions/sts-86/mission-sts-86.html. Retrieved 30 March 2007.
- ^ "STS-79". NASA. 23 November 2007. http://www.nasa.gov/mission_pages/shuttle/shuttlemissions/archives/sts-79.html. Retrieved 18 April 2011.
- ^ "STS-81". NASA. 23 November 2007. http://www.nasa.gov/mission_pages/shuttle/shuttlemissions/archives/sts-81.html. Retrieved 18 April 2011.
- ^ "STS-84". NASA. 23 November 2007. http://www.nasa.gov/mission_pages/shuttle/shuttlemissions/archives/sts-84.html. Retrieved 18 April 2011.
- ^ "STS-89". NASA. 23 November 2007. http://www.nasa.gov/mission_pages/shuttle/shuttlemissions/archives/sts-89.html. Retrieved 18 April 2011.
- ^ "STS-91". NASA. 23 November 2007. http://www.nasa.gov/mission_pages/shuttle/shuttlemissions/archives/sts-89.html. Retrieved 18 April 2011.
Mir Soviet modules 
Russian/American modules Other subsystems Visiting spacecraft Other articles Shuttle-Mir programme · Deorbit of Mir · MirCorp
List of Mir spacewalks · List of human spaceflights to Mir · List of Mir Expeditions · List of Mir visitors · List of unmanned spaceflights to Mir← 1994 · Orbital launches in 1995 · 1996 → Intelsat 704 | Express 1 | Tsikada 1 · Faisat 1 · Astrid 1 | Apstar-2 | USA-108 | STS-63 (SPARTAN-204 · ODERACS 2A · ODERACS 2B · ODERACS 2C · ODERACS 2D · ODERACS 2E · ODERACS 2F | Progress M-26 | Foton #10 | STS-67 | Kosmos 2306 | Kosmos 2307 · Kosmos 2308 · Kosmos 2309 | Soyuz TM-21 | SFU · Himawari 5 | Kosmos 2310 | Intelsat 705 | Kosmos 2311 | USA-109 | Gurwin 1 · EKA-2 · UNAMSAT-A | Brasilsat B2 · Hot Bird 1 | Orbcomm FM1 · Orbcomm FM2 · OrbView-1 | Ofek-3 | AMSC-1 | Progress M-27 | ERS-2 | USA-110 | Intelsat 706 | Spektr | GOES 9 | Kosmos 2312 | USA-111 | Kosmos 2313 | DirecTV-3 | STEP-3 | STS-71 | Kosmos 2314 | Kosmos 2315 | Helios 1A · CERISE · UPMSat | USA-112 | STS-70 (TDRS-7) | Progress M-28 | Kosmos 2316 · Kosmos 2317 · Kosmos 2318 | USA-113 | Interbol 1 · Maigon 4 | PAS-4 | Koreasat 1 | Molniya 3-59 | GEMStar 1 | JCSAT-3 | N-Star A | Kosmos 2319 | Sich 1 · FASat-Alfa | Soyuz TM-22 | STS-69 (SPARTAN-201 · WSF) | Telstar 402R | Resurs-F2 #10 | Kosmos 2320 | Kosmos 2321 | Progress M-29 | Luch-1 | Astra 1E | STS-73 | USA-114 | METEOR | Kosmos 2322 | Radarsat-1 · SURFSAT | USA-115 | STS-74 (SO) | ISO | Gals 2 | AsiaSat 2 | SOHO | USA-116 | Télécom 2C · INSAT-2C | Kosmos 2323 · Kosmos 2324 · Kosmos 2325 | Galaxy 3R | Progress M-30 | Kosmos 2326 | IRS-1C · Skipper | EchoStar I | RXTEPayloads are separated by bullets ( · ), launches by pipes ( | ). Manned flights are indicated in bold text. Uncatalogued launch failures are listed in italics. Payloads deployed from other spacecraft are denoted in brackets. Categories:
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