LIQUID ROCKET COMBUSTION CHAMBER ACOUSTIC CHARACTERIZATION DOI 10.5028/jatm.2010.02038810

Authors

  • Rogério Pirk Institute of Aeronautics and Space São José dos Campos – Brazil
  • Carlos d'Andrade Souto Institute of Aeronautics and Space São José dos Campos – Brazil
  • Dimas Donizeti da Silveira Institute of Aeronautics and Space São José dos Campos – Brazil
  • Cândido Magno de Souza Institute of Aeronautics and Space São José dos Campos – Brazil
  • Luiz Carlos Sandoval Góes Technological Institute of Aeronautics São José dos Campos – Brazil

Keywords:

Combustion chamber, Combustion instability, Acoustic resonance, Liquid rocket engine (LRE)

Abstract

Over the last 40 years, many solid and liquid rocket motors have experienced combustion instabilities. Among other causes, there is the interaction of acoustic modes with the combustion and/or fluid dynamic processes inside the combustion chamber. Studies have been showing that, even if less than 1% of the available energy is diverted to an acoustic mode, combustion instability can be generated. On one hand, this instability can lead to ballistic pressure changes, couple with other propulsion systems such as guidance or thrust vector control, and in the worst case, cause motor structural failure. In this case, measures, applying acoustic techniques, must be taken to correct/minimize these influences on the combustion. The combustion chamber acoustic behavior in operating conditions can be estimated by considering its behavior in room conditions. In this way, acoustic tests can be easily performed, thus identifying the cavity modes. This paper describes the procedures to characterize the acoustic behavior in the inner cavity of four different configurations of a combustion chamber. Simple analytical models are used to calculate the acoustic resonance frequencies and these results are compared with acoustic natural frequencies measured at room conditions. Some comments about the measurement procedures are done, as well as the next steps for the continuity of this research. The analytical and experimental procedures results showed good agreement. However, limitations on high frequency band as well as in the identification of specific kinds of modes indicate that numerical methods able to model the real cavity geometry and an acoustic experimental modal analysis may be necessary for a more complete analysis. Future works shall also consider the presence of passive acoustic devices such as baffles and resonators capable of introducing damping and avoiding or limiting acoustic instabilities.

Downloads

Published

2011-07-29

Issue

Vol. 2 No. 3 (2010): Sep./Dec. 2010

Section

Original Papers

License

This work is licensed under a Creative Commons — Attribution 4.0 International — CC BY 4.0. Authors are free to Share (copy and redistribute the material in any medium or format) and Adapt (remix, transform, and build upon the material for any purpose, even commercially). JATM allow the authors to retain publishing rights without restrictions.