CRN Application to Predict the NOx Emissions for Industrial Combustion Chamber

Authors

  • Nguyen Thanh Hao Industrial University of HoChiMinh City, 12, NguyenVanBao, GoVap, HoChiMinh, Vietnam
  • Park Jungkyu Depatment of Mechanical Engineering, Konkuk University, 120 Neungdong, Gwangjin, Seoul, Korea

DOI:

https://doi.org/10.51983/ajeat-2013.2.1.653

Keywords:

Industrial Combustion Chamber, NOx Emissions, Chemical Reactor Networks (CRN), Computational Fluid Dynamics (CFD)

Abstract

The development of chemical reactor network (CRN) models to predict the NOx emissions is very important for the modern combustion system design. In this study, the new chemical reactor network models are constructed based on the computational fluid dynamics (CFD) to simulate the burning process of the industrial combustor. The boundary and the operating conditions used for these CRN models reflect the typical operating conditions of the industrial combustor. The global mechanism has been developed by GRI 3.0 in the UW chemical reactor code. For the reliability of the predictive models, the models were analyzed and compared to the experimental industrial combustor research. Finally, the CRN models have shown to be efficient estimating accurately NOx emissions with a very short response time.

References

S. L. Bragg, “Application reaction rate theory to combustion chamber analysis”, aeronautical research council pub. ARC 16170, Ministry of Defense, London, England, pp.1629-1633, 1953.

J. Swithenbank, Combustion fundamentals. AFOSR 70-2110 TR, 1970.

P. M. Rubin, and D. T. Pratt, “Zone combustion model development and use: Application to emissions control. American Society of Mechanical Engineers”, 91-JPGC-FACT-25, 1991.

T. Ruta, P. C. Malte, and J. C. Kramlich, “Investigation of NOx and CO formation in lean premixed, methane-air, high-intensity, confined flames at elevated pressures”, Proc. Combust. Inst., Vol.28, pp.2435-2441, 2000.

T. Rutar, and P. C. Malte, “NOx formation in high-pressure jet-stirred reactors with significance to lean-premixed combustion turbines”, ASME Journal of Engineering for Gas Turbines and Power, Vol.124, pp.776-783, 2002.

J. K. Park, “Modelling study of the effect of chemical additives on soot precursors reaction”, International Journal of Automotive Technology, Vol.7, No.4, pp.501-508, 2006.

Nguyen Thanh Hao, Nguyen Thanh Nam, Jungkyu Park, “A CRN simulation for emission pollutants prediction in lean premixed gas turbine combustor”, Asean Engineering Journal, vol.1, 2011.

B. R. A. Lee, “study on NOx formation pathway of methane-air lean premixed combustion by using PSR model”, Transaction of KSAE, Vol.17, No.5, pp.46-52, 2009.

G. Sturgess, and D. T. Shouse, “A hybrid model for calculating lean blow-outs in practical combustors”, AIAA pp. 96-3125, 1996.

A. M. Mellor, Editor. “NOx and CO emissions models for gasfired, lean premixed combustion turbine: Final report”, Vanderbit University, Nashville, TN, 1996.

R. J. Roby, M. S. Klassen, D. Vashistat, R. Joklik, A. Marshall, High fuel-air ratio (FAR) combustor modeling. Report to Naval Air Warfare Center, 2003.

I. V. Novosselov, Eight-step global kinetic mechanism of methane oxidation with nitric oxide formation for lean premixed combustion turbines. MSME Thesis, University of Washington, Seattle, WA, 2002.

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Published

05-05-2013

How to Cite

Thanh Hao, N., & Jungkyu, P. (2013). CRN Application to Predict the NOx Emissions for Industrial Combustion Chamber. Asian Journal of Engineering and Applied Technology, 2(1), 12–20. https://doi.org/10.51983/ajeat-2013.2.1.653

Issue

Vol. 2 No. 1 (2013): January-June 2013

Section

Articles

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Copyright (c) 2013 The Research Publication

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