The Experimental Study about a Performance and Fine Particle Number Emissions with Several ETBE Contents and a Different Ignition Timing

doi:10.15231/jksc.2018.23.4.008

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2018 Vol.23, Issue 4 Preview Page Next Page

Research Article

The Experimental Study about a Performance and Fine Particle Number Emissions with Several ETBE Contents and a Different Ignition Timing ETBE 함량 및 점화시기 변화에 따른 성능 및 미세입자 배출특성에 관한 실험적 연구: 송호영, 김홍집
Hoyoung Song, Hongjip Kim

30 December 2018. pp. 8-14

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Abstract

It has been known that oxygenates increase octane number of gasolines. There are MTBE and bio-ethanol known as typical oxygenates and a lot of increasing interests have been given to the researches on ETBE to alternate these oxygenates. In this study, the performance and emissions of fine particle number with changing ETBE contents and spark ignition timing in single cylinder engines have been studied. There were trends that oxygen contents and RON increased with increasing ETBE contents of gasolines. And the ignition delay became longer and the burning velocity was reduced with increasing oxygen contents. Net caloric value and RON of gasoline has affected BMEP and BSFC for various ignition timings. Knocking intensity sharply increased with advancing ignition timing, but the difference in the knocking intensity of high RON fuels was relatively low. And fine particle number emissions rapidly increased with advancing ignition timing.

Keywords

Particle number

ETBE(Ethyl Tertiary-Butyl Ether)

MPI(Multi-Point Injection)

Single cylinder engine

Knocking

RON(Research Octane Number)

References

H.Y. Song, K.K. Kim, T.Y. Lim, H.J. Kim, The Experimental Study of the Effect of Oxygenates on Exhaust Emissions and Fuel Economy of MPI and GDi Vehicles, Trans. Korean Soc. Auto. Eng., 25(5) (2017) 632-640.
C. OH, G. Cha, Influence of Oxygenate Content on Particulate Matter Emission in Gasoline Direct Injection Engine, Int. J. Automot. Techn., 14(6) (2013) 829-836.
M.H. Lee, S.W. Kim, J.G. Kim, J.R. Kim, E.S. Yim, D.G. Kim, The Fuel Properties and Exhaust Emission Characteristics according to the Oxygenated Fuel Additive Type, KSAE Spring Conference, 2009, 470-476.
Combustion Analyser User Manual 7.0.6, Version 1.5, DEWETRON, 27-35.
E. Hu, J. Ku, G. Yin, C.C. Li, X. Lu, Z. Huang, Laminar Flame Characteristics and Kinetic Modeling Study of Ethyl Tertiary Butyl Ether compared with Methyl Tertiary Butyl Ether, Ethanol, Iso-Octane and Gasoline, Energy Fuels, 32(3) (2018) 3935-3949.
S.H. Lee, S.M. Oh, K.Y. Kang, J.H. Cho, K.O. Cha, Particulate Emissions from a Direct Injection Spark-Ignition Engine Fuelled with Gasoline and LPG, Trans. Korean Soc. Auto. Eng., 19(3) (2011) 65-72.
S. Sakai, M. Hageman, D. Rothamer, Effect of Equivalence Ratio on the Particulate Emissions from a Spark-Ignited, Direct-Injected Gasoline Engine, SAE Technical Paper, 2013, 2013-01-1560
Z. Wang, Y. Wang, R.D. Reitz, Pressure Oscillation and Chemical Kinetics Coupling during Knock Processes in Gasoline Engine Combustion, Energy Fuels, 26(12) (2012) 7107-7119.
S.S. Merola, B.M. Vaglieco, Knock Investigation by Flame and Radical Species Detection in Spark Ignition Engine for Different Fuels, Energy Convers. Manage., 48 (2017) 2897-2910.
Pan J, Sheppard DGW, Tindall A, Berzins M, Pennignton SV, and Wake JM, End Gas Inhomogeneity, Autoignition and Knock, SAE Technical Paper, 1998, 982616.

Information

Publisher :The Korean Society of Combustion
Publisher(Ko) :한국연소학회
Journal Title :Journal of the Korean Society of Combustion
Journal Title(Ko) :한국연소학회지
Volume : 23
No :4
Pages :8-14
DOI :https://doi.org/10.15231/jksc.2018.23.4.008

[1] H.Y. Song, K.K. Kim, T.Y. Lim, H.J. Kim, The Experimental Study of the Effect of Oxygenates on Exhaust Emissions and Fuel Economy of MPI and GDi Vehicles, Trans. Korean Soc. Auto. Eng., 25(5) (2017) 632-640.

[2] C. OH, G. Cha, Influence of Oxygenate Content on Particulate Matter Emission in Gasoline Direct Injection Engine, Int. J. Automot. Techn., 14(6) (2013) 829-836.

[3] M.H. Lee, S.W. Kim, J.G. Kim, J.R. Kim, E.S. Yim, D.G. Kim, The Fuel Properties and Exhaust Emission Characteristics according to the Oxygenated Fuel Additive Type, KSAE Spring Conference, 2009, 470-476.

[4] Combustion Analyser User Manual 7.0.6, Version 1.5, DEWETRON, 27-35.

[5] E. Hu, J. Ku, G. Yin, C.C. Li, X. Lu, Z. Huang, Laminar Flame Characteristics and Kinetic Modeling Study of Ethyl Tertiary Butyl Ether compared with Methyl Tertiary Butyl Ether, Ethanol, Iso-Octane and Gasoline, Energy Fuels, 32(3) (2018) 3935-3949.

[6] S.H. Lee, S.M. Oh, K.Y. Kang, J.H. Cho, K.O. Cha, Particulate Emissions from a Direct Injection Spark-Ignition Engine Fuelled with Gasoline and LPG, Trans. Korean Soc. Auto. Eng., 19(3) (2011) 65-72.

[7] S. Sakai, M. Hageman, D. Rothamer, Effect of Equivalence Ratio on the Particulate Emissions from a Spark-Ignited, Direct-Injected Gasoline Engine, SAE Technical Paper, 2013, 2013-01-1560

[8] Z. Wang, Y. Wang, R.D. Reitz, Pressure Oscillation and Chemical Kinetics Coupling during Knock Processes in Gasoline Engine Combustion, Energy Fuels, 26(12) (2012) 7107-7119.

[9] S.S. Merola, B.M. Vaglieco, Knock Investigation by Flame and Radical Species Detection in Spark Ignition Engine for Different Fuels, Energy Convers. Manage., 48 (2017) 2897-2910.

[10] Pan J, Sheppard DGW, Tindall A, Berzins M, Pennignton SV, and Wake JM, End Gas Inhomogeneity, Autoignition and Knock, SAE Technical Paper, 1998, 982616.

Journal of the Korean Society of Combustion ISSN:1226-0959(Print) 2466-2089(Online) 한국연소학회지

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