International Journal of Aeronautical and Space Sciences

The Korean Society for Aeronautical and Space Sciences (한국항공우주학회)
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Longitudinal Modal Analysis of a LOX-filled Tank Using the Virtual Mass Method

  • Lee, SangGu (Department of Mechanical and Aerospace Engineering, Seoul National University) ;
  • Sim, JiSoo (Korea Aerospace Industries, LTD.) ;
  • Shin, SangJoon (Department of Mechanical and Aerospace Engineering, Seoul National University) ;
  • Kim, Youdan (Department of Mechanical and Aerospace Engineering, Seoul National University)
  • Received : 2017.02.03
  • Accepted : 2017.11.02
  • Published : 2017.12.30
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Abstract

For liquid rocket engine(LRE)-based space launch vehicles, longitudinal instability, often referred to as the pogo phenomenon in the literature is predicted. In the building block of system-level task, accurate dynamic modeling of a fluid-filled tank is an essential. This paper attempts to apply the virtual mass method that accounts for the interaction of the vehicle structure and the enclosed liquid oxygen to LOX-filled tanks. The virtual mass method is applied in a modal analysis considering the hydroelastic effect of the launch vehicle tank. This method involves an analysis of the fluid in the tank in the form of mass matrix. To verify the accuracy of this method, the experimental modal data of a small hemispherical tank is used. Finally, the virtual mass method is applied to a 1/8-scale space shuttle external tank. In addition, the LOX tank bottom pressure in the external tank model is estimated. The LOX tank bottom pressure is the factor required for the coupling of the LOX tank with the propulsion system. The small hemispherical tank analysis provides relatively accurate results, and the 1/8-scale space shuttle external tank provides reasonable results. The LOX tank bottom pressure is also similar to that in the numerical results of a previous analysis.

Keywords

References

  1. Larsen, C. E., "NASA Experience with Pogo in Human Spaceflight Vehicles", NATO RTO Symposium ATV-152 on Limit-Cycle Oscillations and Other Amplitude-Limited, Self-Excited Vibrations, Norway, 5-8 May, 2008.
  2. Kana, D. D. and Nagy, A., "An Experimental Study of Axisymmetric Modes in Various Propellant Tanks Containing Liquid", Technical Report, SwRI Project No. 02-2583, May 1971.
  3. Bernstein, M., Coppolino, R., Zalesak, J. and Mason, P. W., "Development of Technology for Fluid-Structure Interaction Modeling of a 1/8-Scale Dynamic Model of the Shuttle External Tank(ET)", Technical Report, NASA CR-132549, August 1974.
  4. Coppolino, R., "A Numerically Efficient Finite Element Hydroelastic Analysis. Volume 1: Theory and Results", Technical Report, NASA CR-2662, April 1976.
  5. Coppolino, R., "A Numerically Efficient Finite Element Hydroelastic Analysis. Volume 2: Implementation in NASTRAN", Technical Report, NASA CR-2662, April 1974.
  6. Blanchard, U. J., Miserentino, R. and Leadbetter, A., "Experimental Investigation of the Vibration Characteristics of a Model of an Asymmetric Multielement Space", Technical Report, NASA TN D-8448, September 1977.
  7. Oppenheim, B. W. and Rubin, S., "Advanced Pogo Stability Analysis for Liquid Rockets", Journal of Spacecraft and Rockets, Vol. 30, No. 3, May-June 1993.
  8. Lock, M. H. and Rubin, S., "Analysis of Pogo on the Space Shuttle: Accumulator Design Guidelines and Planar Multiengine Model", Technical Report, NASA CR-151135, September 1976.
  9. Lee, S. G., Sim, J. S. and Shin, S. J., "Comparison and Application of Virtual Mass Method and Phantom Boundary for Hydroelastic Analyses for Three-Dimensional Tanks", KSAS 2016 Fall Conference, Jeju, Korea, 2016.

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  1. Pressure mode analysis of nonuniform cross-sectional pipes and preliminary evaluation of a pogo suppressor pp.2041-3025, 2019, https://doi.org/10.1177/0954410018823627