• Title/Summary/Keyword: rocket exhaust flow

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A CFD Study for Rocket Exhaust Flow using Single Species, Unreacted Flow Model (단일화학종 비반응 해석 모델을 사용한 로켓 연소후류 유동해석 연구)

  • Kang, Sun-Il;Huh, Hwan-Il
    • Aerospace Engineering and Technology
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    • v.11 no.1
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    • pp.126-134
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    • 2012
  • The Single Species, Unreacted Flow Model which is effectively applicable on the computational analysis of rocket exhaust flow is introduced in this paper. The basic concept of this model had been originated from chemically frozen analysis of hot air but it was complemented by compensating molecular weight and specific heat which was obtained CEA code analysis of exhaust plume. Comparing single species, unreacted model with the finite chemistry model, unreacted model can reduce calculation time to 1/5 while it makes similar simulation results.

A Study for Rocket Exhaust Flow Cooling due to the Central Spray Type Water Injection (중앙 분사 방식 냉각수 투입에 의한 로켓 연소 후류 냉각에 관한 연구)

  • Kang, Sun-Il;Nam, Jung-Won;Huh, Hwan-Il
    • Aerospace Engineering and Technology
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    • v.12 no.1
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    • pp.163-172
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    • 2013
  • In this study, the cooling of rocket exhaust plume by sprayed water inside plume were investigated as varying of sprayed water mass, location, and method using computational fluid analysis. For Analyze rocket exhaust plume, a single species unreacted analysis model based on the chemically frozen analysis was used and the discrete particle model which was a kind of Euler-Lagrangian analysis model was used for simulate sprayed water inside plume. It was confirmed that the temperature of plume was reduced without cooling when water mass was two times of plume mass through analysis results.

The Variation of Thrust Distribution of the Rocket Nozzle Exit Plane with the Various Position of Secondary Injection (2차 분사의 위치 변화에 따른 로켓노즐 출구에서의 추력 분포 변화)

  • Kim, Sung-Joon;Lee, Jin-Young;Park, Myung-Ho
    • Journal of Industrial Technology
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    • v.20 no.B
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    • pp.45-53
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    • 2000
  • A numerical study is done on the thrust vector control using gaseous secondary injection in the rocket nozzle. A commercial code, PHOENICS, is used to simulate the rocket nozzle flow. A $45^{\circ}-15^{\circ}$ conical nozzle is adopted to do numerical experiments. The flow in a rocket nozzle is assumed a steady, compressible, viscous flow. The exhaust gas of the rocket motor is used as an injectant to control the thrust vector of rocket at the constant rate of secondary injection flow. The injection location which is on the wall of rocket is chosen as a primary numerical variable. Computational results say that if the injection position is too close to nozzle throat, the reflected shock occurs. On the other hand, the more mass flow rate of injection is needed to get enough side thrust when the injection position is moved too far from the throat.

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Analysis of Performance of Turbine Exhaust Nozzle for Liquid Rocket Engine (액체로켓엔진의 터빈 배기노즐 성능 해석)

  • Cho, Won-Kook;Seol, Woo-Seok
    • 한국전산유체공학회:학술대회논문집
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    • 2008.03b
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    • pp.316-319
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    • 2008
  • A computational analysis has been conducted on the compressible flow in the turbine exhaust nozzle of the gas generator cycle liquid rocket engine. The commercial CFD code Fluent has been used. Four nozzle designs have been compared to select the turbine exhaust nozzle concept. Three candidates with single nozzle have comparable performance. The model with bifurcated nozzles shows significant performance loss. However it will be better in the view of balanced thrust distribution because of its symmetric geometry.

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Thermal Analysis of Exhaust Diffuser Cooling Channels for High Altitude Test of Rocket Engine (로켓엔진 고공환경 모사용 디퓨져의 냉각 채널 열 해석)

  • Cho, Kie-Joo;Kim, Yong-Wook;Kan, Sun-Il;Oh, Seung-Hyub
    • Aerospace Engineering and Technology
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    • v.9 no.2
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    • pp.193-197
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    • 2010
  • Water cooling ducts are installed in the exhaust diffuser for high altitude tests of rocket engine to protect diffuser from high-temperature combustion gas. The mass flow rate and pressure of cooling water is designed to prevent boiling of cooling water in the ducts. Therefore, the estimation of maximum temperature of duct wall is important parameter in design of cooling system, especially pressure of cooling water. The method for predicting maximum temperatures of duct walls with variation of coolant flow rates was derived theoretically.

Three-Dimensional Computations of Rocket Exhaust Plume (로켓 배기플룸에 관한 3차원 수치해석)

  • Kim Y.-M.
    • 한국전산유체공학회:학술대회논문집
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    • 1999.11a
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    • pp.71-76
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    • 1999
  • The base flow regions of a three-body sounding rocket containing multiple exhaust plumes were numerically investigated in three dimensions for a free stream Mach number of 2.7 at flight altitude 18.5 km. The flowfields were calculated using the full compressible Navier-Stokes equations with an one-equation turbulence model of Baldwin-Earth. The present calculations were executed based upon a chemically frozen, single perfect gas model assumption. Due to the symmetry of the three-body rocket of each single nozzle, only one fourth of the computational domain was considered for the analysis. The results indicate that a babe heating effect is not considerable due to the small expansion of the plumes. In the base, however, a low speed recirculating flow dominates the region.

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Numerical Analysis of Rocket Exhaust Plume with Equilibrium Chemistry and Thermal Radiation (화학 평형과 열복사를 포함한 로켓 플룸 유동 해석)

  • Shin Jae-Ryul;Choi Jeong-Yeol;Choi Hwan-Seck
    • Journal of the Korean Society of Propulsion Engineers
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    • v.9 no.1
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    • pp.35-45
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    • 2005
  • Numerical study is carried out to investigate the effects of chemistry and thermal radiation on the rocket plume flow field at various altitudes. Navier-Stokes equations for compressible flows were solved by a fully-implicit TVD code based on the finite volume method. An infinitely fast chemistry module for hydrocarbon mixture with detailed thermo-chemical properties and a thermal radiation module for optically thick media were incorporated with the fluid dynamics code. The plume flow fields of a kerosene-fueled rocket flying at Mach number zero at sea-level, 1.16 at altitude of 5.06 km and 2.90 at 17.34 km were numerically analyzed. Results showed the plume structures at different altitude conditions with the effects of chemistry and radiation. It is understood that the excess temperature by the chemical reactions in the exhaust gas may not be ignored in the view point of propulsion performance and thermal protection of the rocket base, especially at higher altitude conditions.

Numerical Study of Rocket Exhaust Plume with Equilibrium Chemical Reaction and Thermal Radiation (평형화학반응과 복사열전달을 고려한 로켓 플룸 유동 해석)

  • Shin J.-R.;Choi J.-Y.;Choi H.-S.
    • 한국전산유체공학회:학술대회논문집
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    • 2004.03a
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    • pp.146-153
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    • 2004
  • The Numerical study has been carried out to investigate the effects of chemical reaction and thermal radiation on the rocket plume flow-field at various altitudes. The theoretical formulation is based on the Navier-Stokes equations for compressible flows along with the infinitely fast chemistry and thermal radiation. The governing equations were solved by a finite volume fully-implicit TVD(Total Variation Diminishing) code which uses Roe's approximate Riemann solver and MUSCL(Monotone Upstream-centered Schemes for Conservation Laws) scheme. LU-SGS (Lower Upper Symmetric Gauss Seidel) method is used for the implicit solution strategy. An equilibrium chemistry module for hydrocarbon mixture with detailed thermo-chemical properties and a thermal radiation module for optically thin media were incorporated with the fluid dynamics code. In this study, kerosene-fueled rocket was assumed operating at O/F ratio of 2.34 with a nozzle expansion ratio of 6.14. Flight conditions considered were Mach number zero at ground level, Mach number 1.16 at altitude 5.06km and Mach number 2.9 at altitude 17.34km. Numerical results gave the understandings on the detailed plume structures at different altitude conditions. The diffusive effect of the thermal radiation on temperature field and the effect of chemical recombination during the expansion process could be also understood. By comparing the results from frozen flow and infinitely fast chemistry assumptions, the excess temperature of the exhaust gas resulting from the chemical recombination seems to be significant and cannot be neglected in the view point of performance, thermal protection and flow physics.

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A Study on Flow Characteristics with the Installed Location Change of Mechanical Deflector (기계적 편향판 설치위치의 변화에 따른 유동특성에 대한 연구)

  • Kim, Kyoung-Ryun;Park, Jong-Ho
    • The KSFM Journal of Fluid Machinery
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    • v.18 no.5
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    • pp.49-53
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    • 2015
  • Thrust vector control is the method which generates the side force and roll moment by controlling exhausted gas directly in a rocket nozzle. TVC is classified by mechanical and fluid dynamic methods. Mechanical methods can change the flow direction by several objects installed in a rocket nozzle exhaust such as tapered ramp tabs and jet vane. Fluid dynamic methods control the flight direction with the injection of secondary gaseous flows into the rocket nozzle. The tapered ramp tabs of mechanical methods are used in this paper. They installed at the rear in the rocket nozzle could be freely moved along axial and radial direction on the mounting ring to provide the mass flow rate which is injected from the rocket nozzle. TVC of the tapered ramp tabs has the potential to produce both large axial thrust and high lateral force. We have conducted the experimental research and flow analysis of ramp tabs to show the performance and the structural integrity of the TVC. The experiments are carried out with the supersonic cold flow system and the schlieren graph. This paper provides to analyze the location of normal shock wave and distribution of surface pressure on the region enclosed by the tapered ramp tabs.

Numerical Analysis for Drag Force of Underwater Vehicle with Exhaust Injected inside Supercavitation Cavity (초공동 수중비행체의 공동영역 내부에서 분사된 배기가스가 수중비행체의 항력에 미치는 영향에 대한 수치해석적 연구)

  • Yoo, Sang Won;Lee, Woo Keun;Kim, Tea Soon;Kwack, Young Kyun;Ko, Sung Ho
    • Transactions of the Korean Society of Mechanical Engineers B
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    • v.39 no.12
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    • pp.913-919
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    • 2015
  • A supercavitating vehicle has a speed of more than 300 km/h in water. A numerical analysis of the flow around a supercavitating vehicle must deal with a multiphase flow consisting of the water, vapor and exhaust gas because the vehicle is powered by roket propulsion. The effect of the exhaust gas on the vehicle is an important part in the study of the performance of the supercavitating vehicle. In the present study, the effect of the exhaust gas on the drag of vehicle was investigated by conducting numerical analysis. When there is no exhaust gas, drag of vehicle is affected by re-entrant. In the case with rocket propulsion, the exhaust gas reduces the influence of re-entrant. The exhaust gas also creates Mach disk and it changes drag profile.