• Title/Summary/Keyword: Propellant Pressurization

Search Result 51, Processing Time 0.02 seconds

Rounded Entry Orifice Characteristics for Pressurization Control (가압제어용 둥근 유입형 오리피스 특성)

  • Chung, Yong-Gahp;Kwon, Oh-Sung;Jang, Je-Sung;Shin, Dong-Sung;Han, Sang-Yeop
    • 한국전산유체공학회:학술대회논문집
    • /
    • 2008.03b
    • /
    • pp.401-404
    • /
    • 2008
  • Pressurization system in a liquid-propellant launcher supplies the controlled gas into the ullage volume of propellant tanks to feed propellants to combustion chamber by pressurizing propellants stored in propellant tanks. The ullage part of propellant tank should be constantly pressurized to supply the propellants stored in propellant tanks to turbo-pump or combustion chamber by pressurant pressurization system. Pressurant used to pressurize propellants is generally stored in a series of tanks at cryogenic temperature and high preassure inside an oxidizer tank. The reason is to store the quantity of pressurant as much as possible and to make pressurant tanks as small as (i.e. as light as) possible. However for test convenience pressurant tank is located at STP (standard temperature and pressure) environment in this study. Orifices are widely adapted to several pressurization systems in liquid rocket propulsion systems. Discharge coefficients of orifices are essentially needed for the optimized design of pressurization system in liquid rocket propulsion system. For this study gaseous nitrogen was served as pressurant and rounded entry orifices were employed. The forty-two (42) rounded entry orifices (the radii of curvatures are 0.5 and 1.0) have been tested experimentally in the supersonic flow region. The discharge coefficients of rounded entry orifices with inside diameters ranging from about 1.4 to 5.0mm was measured with 0.95 ${\sim}$ 0.99.

  • PDF

Study on Temperature Characteristic of Pressurization System Using Helium Gas (헬륨 가압시스템에 대한 온도특성 연구(II))

  • Chung Yonggahp;Cho Namkyung;Kil Kyoungsub;Kim Youngmog
    • Proceedings of the Korean Society of Propulsion Engineers Conference
    • /
    • v.y2005m4
    • /
    • pp.168-175
    • /
    • 2005
  • The pressurization system in a liquid rocket propulsion system provides a controlled gas pressure in the ullage space of the vehicle propellant tanks. It is advantage to employ a hot gas heat exchanger in the pressurization system to increase the specific volume of the pressurant and thereby reduce over-all system weight. A significant improvement in pressurization-system performance can be achieved, particularly in a cryogenic system, where the gas supply is stored inside the cryogenic propellant tank. The temperature characteristic of cryogenic pressurant is very important to develop some components in pressurization system. Numerical modeling and Test data were studied using SINDA/FLUINT Program and PTF(Propellant-feeding Test Facility).

  • PDF

Optimum Configuration for Pressurization System of Propellant Tank (추진제 탱크 가압 시스템의 최적 구성)

  • Jung, Young-Suk;Cho, Nam-Kyung;Oh, Seung-Hyub
    • Aerospace Engineering and Technology
    • /
    • v.9 no.1
    • /
    • pp.133-142
    • /
    • 2010
  • Propulsion system of launch vehicle is composed with subsystems as propellant tank, pressurization system, propellant fill/drain system, valve operating system, purge system and so on. Among others, pressurization system is the most important subsystem, because of the real-time control part for pressure control of propellant tank. Therefore, it is the subsystem that must be primarily considered on conceptual design process. In this paper, the data of the previously developed pressurization systems were collected and the optimum configuration was selected by analysis of advantage and disadvantage of the systems.

The Way of Determinating the Optimal Parameters of the Propellant Tank Pressurization Gas in the Feeding System for Liquid Rocket Engine (액체로켓 추진기관의 추진제탱크 가압시스템 최적변수 설계 방법)

  • Bershadskiy V.A.;Cho Kie-Joo;Lim Seok-Hee;Jung Young-Suk;Cho Gyu-Sik;Oh Seung-Hyub
    • Journal of the Korean Society of Propulsion Engineers
    • /
    • v.9 no.2
    • /
    • pp.62-69
    • /
    • 2005
  • The design method to calculate the main features of propellant tank pressurization system during the development procedure of propellant feed system of the liquid rocket engine was suggested. We have considered the influences of parameters of pressurization gas on the efficiency of the thermodynamic processes in the tank. The optimum value of temperature and velocity of pressurization gas at the entrance of tank are obtained by the suggested way.

The Solenoid Valve Development Tests for Propellant Tank Pressurization System (추진제 탱크 가압용 솔레노이드 밸브 개발 시험)

  • Kim, Byung-Hun;Koh, Hyeon-Seok;Kwon, Oh-Sung;Han, Sang-Yeop
    • Proceedings of the Korean Society of Propulsion Engineers Conference
    • /
    • 2011.11a
    • /
    • pp.813-816
    • /
    • 2011
  • The actuation and leakage tests of solenoid valve for propellant tank pressurization system have been conducted. The response time of solenoid valve manufactured is satisfactory to perform requirement. However, leakage was found at the upper part seat of relief valve inside solenoid valve. Solenoid valve was disassembled in order to discover leakage causes. We found out that the upper seat of relief valve was damaged. Through this study, the development possibility of propellant tank pressurization solenoid valve was confirmed.

  • PDF

Determination of The Cryogenic Propellant Parameters at Pressurization of The Propulsion System Tank by Bubbling (버블링을 이용한 추진기관 가압 시스템에서 극저온 추진제 변수의 결정)

  • Bershadskiy Vitaly A.;Jung, Young-Suk;Lim, Seok-Hee;Cho, Gyu-Sik;Cho, Kie-Joo;Kang, Sun-Il;Oh, Seung-Hyub
    • Journal of the Korean Society of Propulsion Engineers
    • /
    • v.10 no.4
    • /
    • pp.1-10
    • /
    • 2006
  • In this paper, a calculation method of the thermodynamic parameters of cryogenic propellant is proposed when a cryogenic propellant tank is pressurized by gaseous helium(GHe) bubbling. Temperature of cryogenic propellant and mass of dissolved GHe into propellant were analyzed at the various operation of pressurization of tile liquid oxygen(LOX) and hydrogen($LH_2$) tank using helium bubbling. It was evaluated how the GHe bubbling influences to the thermodynamic parameters of LOX and $LH_2$ with results of the analysis. With the proposed calculation method, It will be able to confirm the feasibility of GHe bubbling as a pressurization system of cryogenic propellant tank and to optimize the pressurization system using GHe bubbling.

Study on the Temperature Characteristic of Pressurization System Using Cryogenic Helium Gas (극저온 헬륨가스 가압시스템에 대한 온도특성 연구(I))

  • Chung Yonggahp;Kim Yoo
    • Journal of the Korean Society of Propulsion Engineers
    • /
    • v.9 no.3
    • /
    • pp.66-73
    • /
    • 2005
  • The pressurization system in a liquid rocket propulsion system provides a controlled gas pressure in the ullage space of the vehicle propellant tanks. It is advantage to employ a hot gas heat exchanger in the pressurization system to increase the specific volume of the pressurant and thereby reduce over-all system weight. A significant improvement in pressurization-system performance can be achieved, particularly in a cryogenic system, where the gas supply is stored inside the cryogenic propellant tank. In this study liquid nitrogen was used instead of liquid oxygen as a simulant. The temperature characteristic of cryogenic pressurant is very important to develop some components in pressurization system. Numerical modeling and test data were studied using SINDA/FLUINT Program and PTF(Propellant-feeding Test facility).

Calculation of pressurization efficiency of cryogenic propellant tank (극저온 추진제탱크 가압효율 계산)

  • Kwon, Oh-Sung;Kim, Byung-Hun;Kil, Gyoung-Sub;Han, Sang-Yeop
    • Aerospace Engineering and Technology
    • /
    • v.12 no.2
    • /
    • pp.83-90
    • /
    • 2013
  • In this paper, the energy flows related to cryogenic propellant tank ullage were understood and pressurization efficiency of the tank was calculated using propellant feeding test data with the help of calculation program. The related energy flow terms and calculation method of each terms were described. Three test data of different tank pressure and incoming pressurant temperature were used. Under the test conditions, the pressurization efficiency was low in the range of 13.9%~19.3%. The proportion of energy loss to the incoming pressurant energy was in the range of 55.2%~67.6%. The energy loss to the propellant tank wall was the biggest one. If the temperature of incoming pressurant was the same, the rates of each energy flows to the incoming energy were almost the same regardless of the propellant tank pressure. The collapse factor of propellant tank was calculated using test data, and the relation of it to the heat loss rate was observed.

A Study on Crack Propagation of Solid Propellant by Rapid Pressurization (고속가압에 의한 고체추진제의 균열진전평가에 관한 연구)

  • Ha, Jaeseok;Kim, Jaehoon;Yang, Hoyoung
    • Journal of the Korean Society of Propulsion Engineers
    • /
    • v.16 no.6
    • /
    • pp.79-84
    • /
    • 2012
  • An experiment of rapid pressurization-induced crack propagation of solid propellant was conducted by using a windowed test chamber. A pre-cracked specimen of solid propellant is installed in the chamber, and highly compressed nitrogen gas in an accumulator pressurizes the chamber until the chamber pressure reaches set-up pressure to make the chamber depressurization. Pressure-time trace was obtained from the experimental result, and pressurization rate was defined from the trace. In this study, three pressurization rates (64.34, 73.86 and 85.44 MPa/s) are considered, and propagation lengths are measured. Also, a progression of the crack propagation recorded by a high-speed digital camera is presented.

A Study on Crack Propagation of Solid Propellant by Rapid Pressurization (고속압력하중부가에 의한 고체추진제의 균열진전평가에 관한 연구)

  • Ha, Jae-Seok;Kim, Jae-Hoon;Yang, Ho-Young
    • Proceedings of the Korean Society of Propulsion Engineers Conference
    • /
    • 2012.05a
    • /
    • pp.539-544
    • /
    • 2012
  • An experiment of rapid pressurization-induced crack propagation of solid propellant was conducted by using a windowed test chamber. A pre-cracked specimen of solid propellant is installed in the chamber, and highly compressed nitrogen gas in a accumulator pressurizes the chamber until the chamber pressure reaches set-up pressure to make the chamber depressurization. Pressure-time trace was obtained from the experimental result, and pressurization rate was defined from the trace. In this study, three pressurization rates (64.34, 73.86 and 85.44 MPa/s) are considered, and propagation lengths are measured. Also, a progression of the crack propagation recorded by a high-speed digital camera is presented.

  • PDF