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R-27 Zyb

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(Redirected from SS-N-6 Serb)
R-27 missile at Korolyov Rocket and Space Technics Museum, Peresvet
Place of originUSSR
Service history
In service1968 - 1988
Used bySoviet Navy
Production history
DesignerMakeyev Rocket Design Bureau
Designed1962 - 1968
ManufacturerZlatoust Machine-Building Plant
Krasnoyarsk Machine-Building Plant[1]
No. built~1800 produced
VariantsR-27
R-27U
R-27K
Specifications
MassR-27/R27-U: 14,200 kg (31,300 lb)
R-27K: 13,250 kg (29,210 lb)
LengthR-27/R27-U: 8.890 m (29.17 ft)
R-27K: 9.000 m (29.528 ft)
DiameterR-27/R27-U/R-27K: 1.500 m (4.92 ft)

Main
armament
R-27: Single warhead, 1 MT yield
R-27U: Single warhead, 1 MT yield or 3 x 0.2 MT Warheads
Payload capacityR-27: 650 kg (1,430 lb) Single Warhead[1]
R-27U:
650 kg (1,430 lb) Single Warhead or
3x 0.2 MT Warheads 170 kg (370 lb) each[1]
PropellantN2O4/UDMH
Operational
range
R-27: 2,400 km (1,500 mi)[1]
R-27U: 3,000 km (1,900 mi)[1]
Flight ceilingR-27: 620 km (390 mi)
Boost timeR-27: 128.5 Seconds
AccuracyR-27: CEP 1.9 km (1.2 mi)[1]
R-27U: CEP
1.3–1.8 km (0.81–1.12 mi)[1]
R-27K: CEP 0.37 km (0.23 mi)
Launch
platform
Yankee-class submarine

The R-27 Zyb (Russian: Р-27 «Зыбь», lit.'Ripple') was a submarine-launched ballistic missile developed by the Soviet Union and employed by the Soviet Navy from 1968 through 1988. NATO assigned the missile the reporting name SS-N-6 Serb. In the USSR, it was given the GRAU index 4K10. It was a liquid fuel rocket using a hypergolic combination of unsymmetrical dimethylhydrazine (UDMH) as fuel, and nitrogen tetroxide (NTO) as oxidizer.[1] Between 1974 and 1990, 161 missile launches were conducted, with an average success rate of 93%.[2] Total production was 1800 missiles.

The R-27[3] missiles were deployed on the Yankee I submarines, including the K-219.

Technical details

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The missile's body is an all-welded construction made of hard-worked AMg6 (АМг6) aluminium-magnesium-alloy panels, which underwent a two-step process of deep industrial etching and mechanical milling, reducing the plate thickness to one-fifth and one-ninth of the thickness of the original plate.[4]: 87 

The outer surface of the missile was covered with a protective heat- and moisture-resistant Asbestos-based coating. In order to fit the R-27 into the corresponding launch tube, the missile was built without fins, but instead has several rows of rubber shock absorbers to keep the missile's skin from scratching along the side of the launch tube when fired.

The missile's tip featured a single, 650-kg detachable warhead with a yield of 1 MT. A high-explosive linear-shaped charge was used to separate the warhead from the missile.[5]

Directly beneath the warhead, the instrumentation necessary for guidance of the missile was housed inside of a hemispherical compartment formed by the upper bulkhead of the oxidiser tank. This design decision allowed the easy removal of the guidance system from the missile for maintenance and removed the need for a service hatch.

To maximize the volume of propellant available inside the missile, the upper oxidiser tank and the lower fuel tank shared one common bulkhead instead of one bulkhead each as it was absolutely necessary to use every bit of volume available to be able to fit the missile into a submarine.

Another novelty was factory fueling with the subsequent "ampulization" of the tanks by welding filling and drain valves.[4]: 89  In conjunction with efforts to improve the corrosion resistance of materials as well as the tightness of seams and joints, these fabrication methods allowed the missile to have a lifetime of 5 years, which was later extended to 15 years.[4]: 89 

The missile was powered by an 4D10 rocket engine developed by OKB-2,[4]: 87  consisting of a single fixed thrust chamber producing a thrust of 23 ton-force and two smaller gimbaled thrust chambers mounted on the frustum-shaped bottom of the fuel tank[4]: 87  producing a total of 3 ton-force thrust. The engine was ignited using a squib[4]: 87  and burned a hypergolic propellant combination, dinitrogen tetroxide and unsymmetrical dimethylhydrazine, which was delivered into the combustion chamber via turbopumps. The 4D10's main chamber operates on a highly-efficient oxidiser-rich staged combustion cycle to maximize fuel efficiency, while the two smaller chambers use the more ordinary gas-generator cycle. Both the larger chamber and the smaller chambers could be throttled by either regulating the single propellant line leading to the main chamber or a shared oxidiser line leading to the smaller chambers.

One of the most important novelties on this missile is that the main chamber of this rocket motor was integrated into the missile by permanently welding it inside the fuselage instead of mounting the rocket motor onto a thrust structure below the fuselage, which is the usual practice in rocket design. As a result of this design practice, most of the engine could not be tested, repaired or maintained as soon as it was permanently welded inside the missile.

When the R-27 was fired underwater, the container housing them was first overpressurized before the container was flooded and the pressure was equalized. To reduce the effect of water hammer when igniting the rocket engine, the nozzles were housed inside of a watertight air-filled adapter connecting the bottom of the missile with its container. The two smaller chambers are ignited first, before finally igniting the main chamber. The missiles were fired from a depth of 40 to 50 meters under the sea. Preparations for launch would take 10 minutes, and a salvo could be fired with an interval of 8 seconds between each launch.

Variants

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R-27

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  • Total Mass: 14,200 kg
  • Diameter: 1.50 m
  • Total Length: 8.89 m
  • Span: 1.50 m
  • Payload: 650 kg
  • Warhead: single nuclear: 1.0 Mt
  • Maximum range: 2400 km
  • CEP: 1.9 km
  • Launch platform: project 667A submarines

R-27U (RSM-25)

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  • Total Mass: 14,200 kg
  • Diameter: 1.50 m
  • Total Length: 8.89 m
  • Span: 1.50 m
  • Payload: 650 kg
  • Warhead: 3 : 200 kt
  • Maximum range: 3,000 km
  • CEP: 1.3 km
  • Launch platform: project 667AU submarines

R-27K

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The 4K18 was a Soviet medium-range anti-ship ballistic missile (also known as R-27K, where "K" stands for Korabelnaya which means "ship-related") NATO SS-NX-13. The missile was a two-stage development of the single-stage R-27, the second stage containing the warhead as well as propulsion and terminal guidance.[6] Initial submarine testing began on 9 December 1972 on board the K-102, a project 605 class submarine, a modified Project 629/ NATO Golf class lengthened 17.1m (formerly B-121), to accommodate four launch tubes as well as the Rekord-2 fire control system, the Kasatka B-605 Target acquisition system and various improvements to the navigation and communications systems. Initial trials ended on 18 December 1972 because the Rekord-2 fire control system hadn't been delivered yet. After a number of delays caused by several malfunctions, test firings were finally carried out between 11 September and 4 December 1973. Following the initial trials, the K-102 continued making trial launches with both the R-27 and the R-27K, until it was accepted for service on 15 August 1975.[6]

Using external targeting data, the R-27K/SS-NX-13 would have been launched underwater to a range of between 350 and 400 nm (650–740 km), covering a "footprint" of 27 nm (50 km). The Maneuvering Re-Entry vehicle (MaRV) would then home in on the target with a CEP of 400 yards (370 m). Warhead yield was between 0.5-1 Mt.[6]

The missile system never became operational, since every launch tube used for the R-27K counted as a strategic missile in the SALT agreement, and they were considered more important.[6]

Although the R-27K could fit in the launch tubes of the Project 667A (NATO Yankee class), the subs lacked the necessary equipment to target and fire the missile.[6]

Zyb (Suborbital Launch Vehicle)

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In 1992, there was an ongoing effort to convert surplus Soviet Navy SLBMs which were taken out of service into launch vehicles. The Zyb sounding rocket was created on the basis of the R-27 specifically for performing experiments in a Microgravity environment. The rocket would be launched in a ballistic arc, exposing the payload to weightlessness for 17 to 24 minutes, depending on payload mass. The trajectory would reach its apogee at 1800 km or 1000 km for 650 kg and 1000 kg payload mass respectively. The rocket provided 1.5m3 of payload volume. The Zyb sounding rocket was launched a total of three times.[7]

Launch Date Payload Description
1 December 1991 Sprint Module Research on superconductivity.
9 December 1992 Efir Module Biotechnological research regarding electrophoresis. The 650 kg re-entry capsule was recovered intact, but the experiment had failed to perform.
1 December 1993 Efir Module Biotechnological research regarding electrophoresis. The 650 kg re-entry capsule was recovered intact, experiment successful.

Derived missiles

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In 1992, the Makeyev Rocket Design Bureau signed a contract with North Korea regarding the creation of a R-27 derived launch vehicle. As a result of this, the very similar North Korean Hwasong-10 "Musudan" IRBM was derived from the R-27,[8] the only major change from the original being a slightly extended fuselage. Prototypes of this missile were allegedly completed in 2000.[8] It is suspected that a modified subvariant of this missile was then sold to the Iranian Military in 2005 under the designation BM-25 "Khorramshahr".[9]

Operators

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Map with R-27 Zyb operators in blue with former operators in red
 Soviet Union
The Soviet Navy was the only operator of the R-27.
Iran Iran
Operates the Khorramshahr, a heavily modified design based on the R-27.
North Korea North Korea
possibly operates the Hwasong-10, a modified variant of the R-27, some sources suggest North Korea might have abandoned development of the design due to its complexity.[10]

See also

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References

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  1. ^ a b c d e f g h Oleg Bukharin; Pavel Podvig; Pavel Leonardovich Podvig (2004). Russian Strategic Nuclear Forces. MIT Press. p. 321. ISBN 9780262661812. Retrieved 12 April 2013.
  2. ^ DiGiulian, Tony. "R-27/R-27K/R-27U (RSM-25)". navweaps.com. Retrieved 9 August 2022.
  3. ^ Apalkov, Y. (2003). Корабли ВМФ СССР Том I – Подводные лодки. Часть 1 – Ракетные подводные крейсера стратегического назначения и многоцелевые подводные лодки.
    [Ships of the Soviet Navy Volume I - Submarines. Part 1 - Multi-purpose submarines and special-purpose submarines] (in Russian). Saint Petersburg. ISBN 5-8172-0069-4.
    {{cite book}}: CS1 maint: location missing publisher (link)
  4. ^ a b c d e f СКБ-385 КБ машиностроения ГРЦ КБ им.Академика В.П.Макеева [SKB-385 Design Bureau of Mechanical Engineering GRC Design Bureau named after Academician V.P. Makeev] (in Russian). Moscow: Военный Парад - Voyennyy Parad. 2007. ISBN 978-5-902975-10-6.
  5. ^ НЕКОТОРЫЕ КОНСТРУКТИВНЫЕ ОСОБЕННОСТИ БАЛЛИСТИЧЕСКИХ РАКЕТ ПОДВОДНЫХ ЛОДОК [Some design features of Submarine-launched ballistic missiles] (in Russian). Archived from the original on 29 January 2020.
  6. ^ a b c d e Polmar, Norman (2004). Coldwar submarines. USA: Potomac Books Inc. p. 180. ISBN 978-1-57488-594-1.
  7. ^ "Zyb". astronautix.com. Archived from the original on 2 March 2022.
  8. ^ a b "BM-25 Musudan (Hwasong-10)". missilethreat.csis.org. 31 July 2021. Retrieved 2 August 2022.
  9. ^ "Khorramshahr". missilethreat.csis.org. 31 July 2021. Retrieved 2 August 2022.
  10. ^ "North Korea's Army Day Military Parade: One New Missile System Unveiled | 38 North: Informed Analysis of North Korea". 38 North. 2018-02-08. Retrieved 2021-04-05.
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