Spy Subs -Project 09852 Belgorod

Dr. Fox

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Apr 23, 2018
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Spy Subs -Project 09852 Belgorod

Russia is building a new military complex deep under the Arctic, and is bringing the new KANYON strategic nuclear weapon into service. The massive new Project 09852 Belgorod submarine will play a key role in both projects.

KC-139 "Belgorod" (KS-139 "Белгород") is an unfinished OSCAR-II cruise missile submarine which is being converted to serve as a Special Missions mother submarine (known as Project 09852). It will be crewed by the Russian Navy but operated under GUGI, the secretive Main Directorate Deep Sea Research organization. In order to conduct covert special missions, it will carry a deep diving midget submarine, large payloads and the new KANYON (Status-6) strategic nuclear torpedo weapon. The project started in 2010, with the refit commencing in 2012, and is expected to be completed this year.

On 1st March 2018 a video was released by the Russian MoD (Океанская многоцелевая система с беспилотными подводными аппаратами оснащенная ядерной энергетической установкой : Министерство обороны Российской Федерации) inviting people to name Russia's newest weapon(s). The clip showed the Belgorod launching a KANYON and Harpsichord-2P-PM AUV:

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Pr09852 Belgorod Specifications (Provisional)
Displacement: greater than 14,700 tonnes surfaced (est. 17,000 tonnes), 24,000 tonnes submerged (estimated 30,0000 tonnes)
Length: 184 meters
Beam: 18.2 meters
Speed: < 32 knots
Range: Unlimted
Endurance: Approximately 4 months
Operating depth: Estimated as 500-520 meters per OSCAR-II SSGN
Propulsion: nuclear (2 x pressurized water reactor OK-650M.02 with a capacity of 190 MW driving two steam turbines and twin screws. Plus at least two outboard thrusters.
Crew: TBC. estimated 110
Armament: 6 x KANYON nuclear torpedoes (if fitted), 2 x 650 mm and 4 x 533 mm torpedo tubes with up to 28 torpedoes

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‘HARMONY’ submarine detection network

Analysis suggests that the main special mission of Belgorod will be the covert placement of large underwater systems on the sea floor. Russia is working on a new multi-sensor submarine detection network similar in concept to the US Navy’s classic SOSUS system which is intended to detect submarines operating under the arctic at ranges of 100km or more. According the sources quoted in the Russian media (Izvestia, 20th July 2016) the new complex will involve ‘underwater sensors’ (sonar arrays and possibly pressure/wake detectors) and sonar buoys, and will communicate with control stations via satellites. The system itself, or components of it, are codenamed HARMONY.

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The Arctic Ocean has two basins in the middle, divided in half by a massive mountainous ridge. The basins are surrounded by shelfs where the sea floor drops from about 1,000m down to around 4,000m. Given that the midget submarines carried by Belgorod can dive to about 1,000m, these shelves represent the edge of where the sensor arrays might be placed. Additionally there are areas with mountain peeks at less than 1,000m where arrays could be placed.

This system will require the exact placement of a series of underwater constructions. Placement under the ice cap (which is implied) will be extremely complex, especially considering the need to power the system. Cables from the shore are difficult to place without surface ships above which is both impracticable and indiscrete, and are vulnerable to USN tracing and interference. The answer that the Russian planners have come up with it to place a series of self-contained nuclear power plants. These ATGU (Automated installation of the nuclear turbine generator) will be carried into position on the back of the submarine, and placed by the midget submarine (see below).

The ATGU has an integral Pressurized Water Reactor, a small-sized turbine generator installation, a simple thermal-hydraulic circuit and the minimum of ancillary equipment. It is enclosed in a cylindrical ‘Energokapsule’ which is 14m (45ft) long and 8m (25ft) in diameter.

According to the manufacturers the integral reactor allows for a simplified arrangement of the circulation path, reducing flow resistance. This provides a relatively high power level when operating on natural circulation (at least 65% of the max). It is still a relatively small low-density reactor however at 44 kW / l. It has moderate heat fluxes and significant reserves of coolant boiling.

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The ATGU is a general purpose installation intended for on-land and undersea applications, and is likely to be passed off as having civilian applications even when carried by a Navy submarine. The ATGU will connect to one or more sensor arrays by a relatively short (and therefore light) cable. Any large sensor systems are likely to be carried on the Belgorod’s back in the same manner as the ATGU.

Deep diving midget submarine

The ATGU and other payloads will be placed on the sea floor by a nuclear powered deep submergence midget submarine, termed an ACS (deep nuclear station). Russia has used large ‘mother submarines’ to carry its special mission midget subs into position since the 1980s. The Russian approach is to dock the midget submarine with the underside of the mother submarine, making it invisible to the observers when on the surface. This positioning has actually been used since the 1960s when deep diving capsules where towed underneath specially modified submarines. This arrangement was continued with the emergence of the Project 1851 X-RAY Class nuclear powered midget submarine in the 1980s. The X-RAY was a close equivalent to the US Navy’s NR-1 submersible and is 44m (145ft) long and equipped with grabbers and manipulators.

There are currently four ACS midget submarines operational with the Russian Navy which are designed to be carried by mother submerines:

  • AC-23, the original Project 1851 Nelma (X-RAY) submarine. 44m long, can dive to about 1,000m (3,000ft)
  • AC-21, an improved Project 18511 Halibut (PALTUS) class boat. About 55m long and can probably dive to around 1,000m (3,000ft) per the X-RAY
  • AC-35, the second Project 18511 PALTUS. Slight differences to the first.
  • AC-31, Project 10831 LOSHARIK. Significantly larger at 70m and probably deeper diving.
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The LOSHARIK will reportedly be docked with Belgorod (as well as with BS-64 Podmoskovye, a project 09787 DELTA-IV STRETCH which is also an incredible 174m (570ft) long). Additionally the three smaller X-RAY / PALTUS boats can be docked.

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KANYON (Status-6) strategic weapon

Although the Belgorod conversion has been followed by some analysts since around 2010, it only made headlines (indirectly) in November 2015 when it appeared on the infamous ‘leaked’ STATUS-6 presentation. The submarine was depicted in the top left, stating that it would carry six of the new nuclear powered nuclear armed strategic torpedoes known as Skif (NATO: KANYON). These torpedoes are massive at 24m (80ft) long and 1.6m (5.25ft) in diameter, and are designed to strike coastal cities. They can be thought of as an SLBM but in a torpedo form.

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When first revealed in the leak, many observers were quick to dismiss the KANYON as impractical. The stated specifications, especially the warhead, seemed ‘optimistic’. And although it is nearly impossible to counter with current weapon systems, it made no sense as a First Strike weapon because it is comparatively noisy and slow; even at an incredible 100kt speed it would take 4 days to reach its target at maximum range. It is also unsuitable for striking moving targets such as carrier battle groups. The remaining option, which does make some sense, is as a Second Strike weapon intended to be fired in retaliation. Any difficulties countering it can only be made more difficult still in the event of a nuclear war, and the system can likely function without satellite input, making it less vulnerable than SLBMs/ICBMs (can be debated!).

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Its deployment on Belgorod is not straightforward however. Structurally the submarine is ideal with massive missile bas either side of the hull which will now be empty. These are more than large enough for the KANYON tubes which will probably be angled to fire out through the side, thus minimizing changes to the forward hull and avoiding compromising the sonar spaces. And the gigantic submarine probably has enough reserve buoyancy to carry the system plus the midget sub and ATGU payload.

However, carrying a special mission submarine and payload, and carrying a strategic weapon are contradictory missions. Some would say mutually exclusive. That the boat is slated for both missions seems clear, so the question is how? It is possible that she will deploy in one role or the other depending on the patrol pattern, covering for the only other KANYON submarine, the purpose built Project 09851 KHABAROVSK.

Automamous Underwater Vehicles (AUS)

Belgorod will almost certainly field UUVs (AUVs in Russian parlance: Automamous Underwater Vehicles). These carry an array of sonars including side-scanning, and are abl to map the sea floor in great detail and locate items such as wreckage and sensor arrays.

These will likely be similar to the Harpsichord-1R (Клавесин-1R) AUV which is reported to be carried by the pr.09787 - DELTA-IV STRETCH. This can dive to 2,000m and operate automatously.

Length – 6.5m
Diameter – 1m
Weight in air - about 3.700 kg
Range: - about 27 nm
Operating depth: 6,000m (according to Rubin. Some reports suggest ~2,000 m)

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Before conversion: OSCAR-II Class

The OSCAR-II class is a large Cruise Missile submarine (SSGN) designed during the Cold War to take out the US Navy’s Carrier Battle Groups. These are massive and expensive boats, each costing around half an Aircraft Carrier. They are the second largest submarines ever built, behind only the Project 971 TYPHOON.

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The OSCAR-II Class carry a formidable battery of 24 x P-700 GRANIT supersonic anti-ship missiles. These have a range of 340 nm and can carry a 500kt thermonuclear warhead.

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Unlike the TYPHOON, the OSCAR-II remains in active service. KC-139 Belgorod is being modified for a different role however.

Belgorod was never finished as an OSCAR-II. In 2006 it was decided to mothball her while she was only 80% complete in order to make space in the workshop for other projects. In 2012 it was decided to finish her as a Special Mission mother sub as project 09852.

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Yes lets keep a series of mini nuclear reactors deep underwater - It's Safe and nothing will happen! !!(y):D

On a serious note!!

This looks like the start of a serious conflict for resources!!! .... hope we don't find a Black marker ! (Deadspace reference)!
 
Yes lets keep a series of mini nuclear reactors deep underwater - It's Safe and nothing will happen! !!(y):D

Very safe actually. The recording devices used by the Americans during Operation Ivy Bells were nuclear-electrical powered. Several iterations were deployed during the operation over a 10 year span without incident, and these aren't the only examples of a persistent underwater nuclear power-generation system.

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Very safe actually. The recording devices used by the Americans during Operation Ivy Bells were nuclear-electrical powered. Several iterations were deployed during the operation over a 10 year span without incident, and these aren't the only examples of a persistent underwater nuclear power-generation system.

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Nice reply! (y)(y)

These recording devices are self contained correct as you mentioned - Is the data transmitted or the whole device has to be recovered?
 
Very safe actually. The recording devices used by the Americans during Operation Ivy Bells were nuclear-electrical powered. Several iterations were deployed during the operation over a 10 year span without incident, and these aren't the only examples of a persistent underwater nuclear power-generation system.

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Hey, is the information from the underwater listening network integrated with the Submarines real time?
 
Hey, is the information from the underwater listening network integrated with the Submarines real time?

These recording devices are self contained correct as you mentioned - Is the data transmitted or the whole device has to be recovered?

Because of the way underwater communications work the data from listening pods has to be recovered, it's not real time. With the Ivy Bells pods, which didn't penetrate or splice into the lines themselves and where fitted over the intact cables, data would need to be recovered every month. Splicing directly into the cable would give a listener the capability to collect data in real time should they choose the proper transmission method, but also interrupts the flow of data while the tap is being installed, so detection is a greater risk.

Why they aren't transmitting in real time is due to the difficultly of transmitting large amounts of information covertly from an underwater platform. Acoustic methods such as pings or pulses could produce a recordable signal over a long range and transmit data in real time, but is hardly secure and any listening device could pick up these signals. That's kind of the reason submarines don't often use active sonar either and why torpedoes are hard-lined generally or use passive-active listening, rather then active sonar. Hard-lines are how we prefer to communicate with ROVs that are operating autonomously and we'd like to keep a watch on. The problem here is that there is a physical line that connects the ROV with its mothership. Connecting a physical line from a submarine to tap pod is impractical at best.

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Other methods like LED communication are too slow and have low transfer rates. Good for communication between submarines over large distances when the messages are short, but bad for anything like intelligence gathering where the flow of information can be a torrent at times. You could float a comms buoy too, but unless you have a tether you could use to recover it they're expendable and noticeable.

Ideally you'd like to have penetrated the receiver, not the transmission lines or sender so you can read the signals in plain text. Loitering around cables is generally going to be noticed above or below water, like Russian activity near under sea cabled around Syria. Yantar, a Russian surveillance vessel has been particularly active in recent years. That's a problem for the cable's owners, but also for Russian intelligence efforts since their activities are being logged. It's probable that Yantar was also assisting in the recovery efforts of stricken Russian aircraft that crashed in the vicinity around 2016.

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