• Title/Summary/Keyword: Shkval torpedo

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Propulsion Technologies of Supercavitating Rocket Torpedo, Shkval (초공동 로켓 어뢰 Shkval 추진기술)

  • Kim, Yoon-Gon;Nah, Young-In
    • Proceedings of the Korean Society of Propulsion Engineers Conference
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    • 2011.11a
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    • pp.383-387
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    • 2011
  • The supercavitating rocket torpedo SHKVAL was analyzed in view of its system operation procedure and the structure and performance. 3 different propulsion systems installed in SHKVAL were 1st solid rocket booster for launch and acceleration, 2nd solid rocket booster for further acceleration, and Mg-rich Hydroreactive fuel rocket propulsion system for cruising. The gas generator used to help generate the supercavitation bubble was composed of a solid propellant gas generator and a hydroreactive fuel one. The structures and their performance were described based on as much knowledge as we have obtained from cumulative information and up-to-date analysis.

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Supercavitating Rocket System (초공동 로켓 시스템)

  • Kim, Kyung-Moo;Lee, Hyung-Jin;Khil, Tae-Ock
    • Journal of the Korea Institute of Military Science and Technology
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    • v.16 no.6
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    • pp.867-880
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    • 2013
  • The development for a high speed underwater vehicle has been demanded for a long time, and it is possible to realize using supercavitation. This paper introduces the main technologies that are necessary to develop a supercavitating rocket system, such as "Supercavitation" and "Hydroreactive technology", and describes the operating concepts and principles for its components specifically. Russia has obtained the key technologies of supercavitation and hydroreactive fuel technology for the first time. Russia has developed a supercavitating rocket torpedo, Shkval, and it was in service since 90's. Iran collaborated with Russia to develop a supercavitating rocket torpedo 'Hoot' and finished a test recently. This paper describes the analysis results related with the cavitator based on the technical reports for Shkval of Russia and Hoot of Iran.

Modelling cavitating flow around underwater missiles

  • Petitpas, Fabien;Saurel, Richard;Ahn, Byoung-Kwon;Ko, Sung-Ho
    • International Journal of Naval Architecture and Ocean Engineering
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    • v.3 no.4
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    • pp.263-273
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    • 2011
  • The diffuse interface model of Saurel et al. (2008) is used for the computation of compressible cavitating flows around underwater missiles. Such systems use gas injection and natural cavitation to reduce drag effects. Consequently material interfaces appear separating liquid and gas. These interfaces may have a really complex dynamics such that only a few formulations are able to predict their evolution. Contrarily to front tracking or interface reconstruction method the interfaces are computed as diffused numerical zones, that are captured in a routinely manner, as is done usually with gas dynamics solvers for shocks and contact discontinuity. With the present approach, a single set of partial differential equations is solved everywhere, with a single numerical scheme. This leads to very efficient solvers. The algorithm derived in Saurel et al. (2009) is used to compute cavitation pockets around solid bodies. It is first validated against experiments done in cavitation tunnel at CNU. Then it is used to compute flows around high speed underwater systems (Shkval-like missile). Performance data are then computed showing method ability to predict forces acting on the system.

Numerical Analysis of the Cavitation Around an Underwater Body with Control Fins (제어핀이 달린 수중 물체의 공동 수치해석)

  • Kim, Hyoung-Tae;Choi, Eun-Ji;Knag, Kyung-Tae;Yoon, Hyun-Gull
    • Journal of the Society of Naval Architects of Korea
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    • v.56 no.4
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    • pp.298-307
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    • 2019
  • The evolution of the cavity and the variation of the drag for an underwater body with control fins are investigated through a numerical analysis of the steady cavitating turbulent flow. The continuity and the steady-state RANS equations are numerically solved using a mixture fluid model for calculating the multiphase turbulent flow of air, water and vapor together with the SST $k-{\omega}$ turbulence model. The method of volume of fluid is applied by the use of the Sauer's cavitation model. Numerical solutions have been obtained for the cavity flow about an underwater body shaped like the Russian high-speed torpedo, Shkval. Results are presented for the cavity shape and the drag of the body under the influence of the gravity and the free surface. The evolution of the cavity with the body speed is discussed and the calculated cavity shapes are compared with the photographs of the cavity taken from an underwater launch experiment. Also the variation of the drag for a wide range of the body speed is investigated and analyzed in details.