THERMAL SCIENCE

International Scientific Journal

INFLUENCE OF COMBUSTION INSTABILITIES ON THE HEATER APPLIANCE WITH ATMOSPHERIC GAS BURNER AND THEIR ELIMINATION BY CROSS FLOW OF AIR

ABSTRACT
This paper presents results of experimental investigation on elimination of combustion oscillations caused by new low pollution burner which was integrated in a gas heater. The method is known as a passive method, based on introducing the air in the combustion chamber. Because the efficacy of the method is highly dependent of the way the air is injected some methods were investigated and compared. The paper also presents effects on pollution characteristics during its operation in the unstable regime.
KEYWORDS
PAPER SUBMITTED: 2015-12-11
PAPER REVISED: 2016-05-12
PAPER ACCEPTED: 2016-05-18
PUBLISHED ONLINE: 2016-05-30
DOI REFERENCE: https://doi.org/10.2298/TSCI151211126F
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2016, VOLUME 20, ISSUE Issue 5, PAGES [1753 - 1763]
REFERENCES
  1. Barrere M., Rocket Propulsion, Elsevir Publishing Company 1960
  2. Culick F.E.C., Combustion Instabilities in Liquid Rocket Engines: Fundamentals and Control, California Institute of Technology, Short Course, © 2002 by F.E.C. Culick 2002
  3. Harrje D., Liquid Propellant Rocket Combustion Instability, NASA SP-194, 1972
  4. Joanes H., The Application of Combustion Principles to Domestic Gas Burners Design, British Gas, Taylor & Francies e-Library 2005
  5. Milić D., et al., Investigation of Pressure Pulsations in the Furnace and Flue Gas Tract of the Pulverized Coal Combustion Utility Boiler, Thermal Science, 14 (2010) 1, pp. 261-270
  6. Min-Ki K., et al., An Experimental Investigation of Acoustic and Combustion Wave Interaction Characteristics in Dump Combustor, proc. of the 46th Joint Propulsion Conference AIAA, Nashvile, USA 2010
  7. Eric M., Matthew C., Investigation of Combustion Control in a Dump Combustor Using the Feedbeck Free Fluidi Oscillator, proc. of 51st Joint Propulsion Conference AIAA, Grapevine, USA 2013
  8. Bade P., Tomarchio M., Tricks and Tools for Solving Abnormal Combustion Noise Problems, Sound and Vibration July (2008), pp. 12-17
  9. Bade P., How to Solve Abnormal Combustion Noise Problems, Sound and Vibration July (2004), pp. 22-27
  10. Eseri M., Cummings A., Combustion oscillations in gas fired appliances: Eigen-frequencies and stability regimes, Applied Acoustics, 64 (2003), pp. 565-580
  11. Noiray N., et al., Passive control of combustion instabilities involving flames anchored on perforated plates, proc. of the Combustion Institute www.elsevier.com/locate/proci 31 (2007), pp. 1283-1290
  12. Epperlein J., et.al., Thermoacoustic and Rijke Tube: Experiments, Identification, and Modeling, IEEE Control System Magazine, 35 (2015), pp. 57-77
  13. Denk K., et al., Acoustic Excitation Effect on NO Reduction in a Laminar Methane-air Flame, Energy Procedia, 61 (2014), pp. 2890-2893
  14. Dunn-Rankin D, Lean Combustion: Technology and Control, Elsevier 2008
  15. TESTO, TESTO 350-XL Instruction manual, Testo AG Germany
  16. Stephanie, B., Measurement Good Practice Guide Issue 2, National Physical Laboratory, Teddigton, UK, 1999
  17. Minilizer ML1, User manual, NTi Audio AG, Switzerland 2011
  18. Laera D., et al, Modeling of Thermoacoustic Combustion Instabilities Phenomena: Application to an Experimental Test Rig, Energy Procedia, 45 (2014), pp. 1392-1401
  19. Li L., et al., A Passive Mehod to Control Combustion Instabilities with Perforated Liner, Chinese Journal of Aeronautics, 23 (2010), pp.623-630

© 2024 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, National Institute of the Republic of Serbia, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence