Soyuz-2

The 2.1a version includes conversion from analog to digital flight control system and uprated engines on the booster and the first stage with improved injection systems. The new digital flight control and telemetry systems allow the rocket to launch from a fixed rather than angled launch platform and adjust its heading in flight. A digital control system also enables the launch of larger commercial satellites with wider and longer payload fairings such as the ST-type fairing. These fairings introduce too much aerodynamic instability for the old analog system to handle. This stage continues to use the RD-0110 engine.

The 2.1a/ST version is sometimes called Soyuz ST-A. The first launch, from Guiana, (17 December 2011 for Pléiades-HR 1A, SSOT, ELISA (4 satellites)) was a success.

The 2.1b version adds an upgraded engine (RD-0124) with improved performance to the second stage. First launch took place from Plesetsk Cosmodrome Site 43 on 26 July 2008 with a classified military payload.[14]

The 2.1b/ST version is sometimes called Soyuz ST-B. The first launch, from Guiana, was a success (21 October 2011), for the first two Galileo IOV satellites.

The first flight vehicle of the 2.1v version was finished in 2009. It is a "light" version of the Soyuz-2 without the side boosters (blocks B, V, G and D). The Block A engine was replaced by the more powerful NK-33-1, which as of 2009, was to eventually be replaced with the RD-193. The new launcher version was able to deliver up to 2.8 tonnes in low Earth orbit.[15]

The Soyuz-2.1a/1b versions launched from the Vostochny Cosmodrome and the Guiana Space Centre have a series of modifications over the stock units. Some of these might later be implemented on all the Soyuz-2, while some are particular requirements to the space port design.

Modifications for the Guiana Space Centre (GSC) version includes:

• First use of a mobile service tower at the ELS that enabled vertical payload integration.[6]
• European supplied payload adapters.[6]
• European supplied KSE (French: Kit de Sauvegarde Européenne, lit. 'European Safeguard Kit'), a system to locate and transmit a flight termination signal.[6] It would activate the engine shutdown command and leave the vehicle in a ballistic trajectory.[16]
• Adaptation of the S-Band telemetry system on all stages from the 5 TM bands available at Baikonur, and Plesetsk to the 3 allowed at the GSC range.[6]
• Adaptation of the S-Band telemetry coding and frequency to the IRIG standard used at GSC.[6]
• Adaptation of the oxygen purge system for directing to the outside the mobile gantry.[6]
• Adaptation to the tropical GSC climate including the adaptation of the air conditioning system to local specifications and protective measures to avoid icing.[6] All holes and cavities were studied and certified to be adequately protected against intrusion of insects and rodents.[16]
• The four boosters and the core stage were upgraded with pyrotechnic devices to breach the fuel tanks to assure that they would sink in the ocean. The other stages were shown to lose structural integrity on impact and thus proven to sink.[16]
• At least initially, the boosters and core stage would use the pyrotechnically ignited 14D22 (RD-107A) and 14D23 (RD-108A) rather than the chemically ignited 14D22 kHz and 14D23 kHz used on the rest of the Soyuz-2.[16]

Modifications for the Vostochny Cosmodrome version includes:[17]

• New and upgraded computer, N.A.Semikhatov NPO Automatika's Malachite-7, with six times more performance, better obsolescence protection, reduced weight.[18][19][20]
• The new computer enabled a significant reduction on the cable network complexity thanks to multiplexing lines and using common buses.[17][20][21]
• New nickel-cadmium batteries that eliminate the need for a dedicated battery charging station.[18]
• The inclusion of on-board video system, that will enable real-time views of the launch.[18]
• Since the launch pad at Vostochny also has a mobile gantry for vertical payload integration, similar to the ELS at Guiana, it has the necessary piping to direct the oxygen purges outside the gantry.[17]

On 1 October 2015 it was announced that parts of the assembly complex for the Soyuz-2 at Vostochny Cosmodrome were designed for a different modification of the rocket and are too small, so that the planned first launch in December 2015 was under question.[22] The first launch occurred on 28 April 2016 at 02:01:21 UTC.[23]

On 8 November 2004, at 18:30 GMT (21:30 Moscow Time), the first Soyuz-2 carrier rocket, in the Soyuz-2.1a configuration, was launched from the Plesetsk Cosmodrome in Russia. The rocket followed a sub-orbital trajectory, with the third stage and boilerplate payload re-entering over the Pacific Ocean.

The first attempt at launching a Soyuz-2 to orbit, with the MetOp-A satellite, occurred on 17 July 2006. It was scrubbed two hours before the launch by an automatic sequence, after the onboard computer failed to check the launch azimuth. Fuelling of the rocket was underway at the time, and all launch complex equipment and on-board preliminary checks had proceeded without incident. The rocket was left fuelled on the launch pad, for the next attempt on 18 July. Launch was eventually conducted on 19 October.

First crewed launch of Soyuz-2 took place 9 April 2020, carrying Soyuz MS-16 to the ISS.

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