Investigation of the Flow Characteristics in a Catalytic Muffler with Perforated Inlet Cone
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Investigation of the Flow Characteristics in a Catalytic Muffler with Perforated Inlet Cone

Authors: Gyo Woo Lee, Man Young Kim

Abstract:

Emission regulations for diesel engines are being strengthened and it is impossible to meet the standards without exhaust after-treatment systems. Lack of the space in many diesel vehicles, however, make it difficult to design and install stand-alone catalytic converters such as DOC, DPF, and SCR in the vehicle exhaust systems. Accordingly, those have been installed inside the muffler to save the space, and referred to the catalytic muffler. However, that has complex internal structure with perforated plate and pipe for noise and monolithic catalyst for emission reduction. For this reason, flow uniformity and pressure drop, which affect efficiency of catalyst and engine performance, respectively, should be examined when the catalytic muffler is designed. In this work, therefore, the flow uniformity and pressure drop to improve the performance of the catalytic converter and the engine have been numerically investigated by changing various design parameters such as inlet shape, porosity, and outlet shape of the muffler using the three-dimensional turbulent flow of the incompressible, non-reacting, and steady state inside the catalytic muffler. Finally, it can be found that the shape, in which the muffler has perforated pipe inside the inlet part, has higher uniformity index and lower pressure drop than others considered in this work.

Keywords: Catalytic muffler, Perforated inlet cone, Catalysts, Perforated pipe, Flow uniformity, Pressure drop.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1092824

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References:


[1] M. Y. Kim,"Performance Prediction of SCR-DeNOX System for Reduction of Diesel Engine NOX Emission", Transactions of the KSAE, Vol. 112003, pp. 71-76.
[2] J. H. Kim, M. Y. Kim, and H. G. Kim, "NO2-Assisted Soot Regeneration Behavior in a Diesel Particulate Filter with Heavy-Duty Diesel Exhaust Gases", Numerical Heat Transfer, Part A, Vol. 58, 2010, pp. 725-739
[3] S. Y. Lee, K. N. Kang, M. Y. Kim, and C. H. Lee; "A Numerical Study on the Urea Melting and Heat Transfer Characteristics with Three Different Types of Coolant Heaters", Proceedings of the KSAE Annual Conference; pp. 582-588; Daejeon, 2011. 11. 23-26.
[4] X. Zhang and P. Tennison, "Numerical Study of Flow Uniformity and Pressure Loss through a Catalytic Converter with Two Substrates"; SAE 2008-01-0614; 2008.
[5] Y. D. Kim, S. J. Jeong, and W. S. Kim, "An Numerical Study on the Flow Uniformity and Pressure Drop in Dual Monolith Catalytic Converter during the Rapid Acceleration/Deceleration Driving",Transactions of the KSAE, Vol. 15, 2007, pp. 63-71.
[6] X. Zhang, M. Romzek, M. Keck, and F. Kurz, "Numerical Optimization of Flow Uniformity inside Diesel Particular Filters", SAE 2005-01-3702, 2005.
[7] J. Y. Kim and S. H. Son, "Improving Flow Efficiency of a Catalytic Converter Using the Concept of Radially Variable Cell Density – Part I", SAE 1999-01-0769; 1999
[8] S. Y. Lee, S. S. Park, H. Y. Kim, and K. M. Cho, "Flow Analysis of CCC with the Change of Cell Shape", Transactions of the KSAE, Vol. 6, 1998, pp. 72-77.
[9] S. F. Benjamin, C. A. Roberts, and J. Wollin, "A Study of the Effect of Flow Pulsations on the Flow Distribution within Ceramic Contoured Catalyst Substrates", SAE 2001-01-1996; 2001.
[10] K. N. Kang, M. S. Jung, C. M. Kim, J. K. Lee, and M. Y. Kim, "Numerical Study on the Mixing Flow Characteristics with a Vane-Type Static Mixer in a Diesel Exhaust System for Urea SCR Application", Proceedings of the KSAE Spring Conference, pp. 532-538,Jeju, 2011. 5. 19-21.
[11] AVL FireTM, "Boost-Aftertreatment-CFD-Solver", pp.254-255, 2010.
[12] B. E. Launder and D. B. Spalding, "The Numerical Computation of Turbulent Flows", Computer Methods in Applied Mechanics and Engineering, Vol. 3, 1974, pp. 269-289.
[13] H. Weltens, H. Bressler, F. Terres, H. Neumaier, and D. Rammoser, "Optimization of Catalytic Converter Gas Flow Distribution by CFD Predictions", SAE 930780; 1993.