THERMAL SCIENCE

International Scientific Journal

Juan Pablo Gómez Montoya

,

Andrés A. Amell Arrieta

,

Jaime F. Zapata Lopez

SPARK IGNITION ENGINE PERFORMANCE AND EMISSIONS IN A HIGH COMPRESSION ENGINE USING BIOGAS AND METHANE MIXTURES WITHOUT KNOCK OCCURRENCE

ABSTRACT
With the purpose to use biogas in an internal combustion engine with high compression ratio and in order to get a high output thermal efficiency, this investigation used a diesel engine with a maximum output power 8.5 kW, which was converted to spark ignition mode to use it with gaseous fuels. Three fuels were used: Simulated biogas, biogas enriched with 25% and 50% methane by volume. After conversion, the output power of the engine decreased by 17.64% when using only biogas, where 7 kW was the new maximum output power of the engine. The compression ratio was kept at 15.5:1, and knocking did not occur during engine operation. Output thermal efficiency operating the engine in SI mode with biogas enriched with 50% methane was almost the same compared with the engine running in diesel-biogas dual mode at full load and was greater at part loads. The dependence of the diesel pilot was eliminated when biogas was used in the engine converted in SI mode. The optimum condition of experiment for the engine without knocking was using biogas enriched with 50% methane, with 12 degrees of spark timing advance and equivalence ratio of 0.95, larger output powers and higher values of methane concentration lead the engine to knock operation. The presence of CO2 allows operating engines at high compression ratios with normal combustion conditions. Emissions of nitrogen oxides, carbon monoxide and unburnt methane all in g/kWh decreased when the biogas was enriched with 50% methane.
KEYWORDS
high compression ratio SI engines, knock, biogas enrichment with methane
PAPER SUBMITTED: 2014-08-29
PAPER REVISED: 2015-06-25
PAPER ACCEPTED: 2015-08-27
PUBLISHED ONLINE: 2015-09-06
DOI REFERENCE: https://doi.org/10.2298/TSCI140829119G
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2015, VOLUME 19, ISSUE Issue 6, PAGES [1919 - 1930]
REFERENCES
  1. Patel, S., et al., Biogas Potential on Long Island, New York: A quantification study, Journal of Renewable Sustainable Energy, 3, 043118, (2011)
  2. Bond, T., Templeton, R., History and Future of Domestic Biogas Plants in the Developing World, Energy for Sustainable Development. 15 (2011), 4, pp. 347-354
  3. Porpatham, E., et al., Investigation on the Effect of Concentration of Methane in Biogas When Used as a Fuel for a Spark Ignition Engine, Fuel, 87 (2008), pp. 1651-1659
  4. Arroyo, J., et al., Efficiency and Emissions of a Spark Ignition Engine Fueled with Synthetic Gases Obtained from Catalytic Decomposition of Biogas, International Journal of Hydrogen Energy, 38 (2013), 9, pp. 3784-3792
  5. Porpatham, E., et al., Effect of Hydrogen Addition on the Performance of a Biogas Fuelled Spark Ignition Engine, International Journal of Hydrogen Energy, 32 (2007), 12, pp. 2057-2065
  6. Lee, K., et al., Generating Efficiency and NOx Emissions of a Gas Engine Generator Fueled with a Biogas-Hydrogen Blend and Using an Exhaust Gas Recirculation System, International Journal of Hydrogen Energy, 35 (2010), 11, pp. 5723-5730
  7. Huang, J., et al., Assessment of Simulated Biogas as a Fuel for the Spark Ignition Engine, Fuel, 77 (1998), 15, pp. 1793-1801
  8. Henham, A., et al., Combustion of Simulated Biogas in a Dual-Fuel Diesel Engine, Energy Conversion and Management, 39 (1998), 16-18, pp. 2001-2009
  9. Bedoya., I., Study of the Influence of the Mixing System and the Quality of Pilot Fuel in the Performance of a Dual Engine, MSc. thesis, University of Antioquia, Medellin, Colombia, 2007
  10. Korakianitis, T., et al., Natural-Gas Fueled Spark-Ignition (SI) and Compression-Ignition (CI) Engine Performance and Emissions, Progress in Energy and Combustion Science, (2010), 1 pp. 1-24
  11. Combustion Gasification and Propulsion Laboratory, Strategic Development of Bio-Energy (SDB) Project, Final Report, Indian Institute of Science, Bangalore, India, 2006
  12. Sopena, C., et al., Conversion of a Commercial Spark Ignition Engine to Run on Hydrogen: Performance Comparison Using Hydrogen and Gasoline, International Journal of Hydrogen Energy, 35 (2010), 3, pp. 1420-1429
  13. Porpatham, E., et al., Effect of Compression Ratio on the Performance and Combustion of a Biogas Fuelled Spark Ignition Engine, Fuel, 95 (2012), 0, pp. 247-256
  14. Heywood, J.B., Internal Combustion Engines Fundamentals, McGraw-Hill Inc., New York, USA, 1988
  15. Dasappa S., et al., On the Estimation of Power from a Diesel Engine Converted for Gas Operation - A Simple Analysis, Proceedings (ASTRA), 17th National Conference on IC Engines and Combustion, Bangalore, India, 2001
  16. Lancaster, D., Effects of Engine Variables on Turbulence in a Spark-Ignition Engine, SAE Paper, 760159 (1976), Vol. 85, pp. 671-688.
  17. Leiker, M., et al., Evaluation of Antiknocking Property of Gaseous Fuels by Means of Methane Number and its Practical Application to Gas Engines, ASME paper, 72-DGP-4.
  18. Malenshek, M., et al., Methane Number Testing of Alternative Gaseous Fuels, Fuel, 88 (2009), 4, pp. 650-656
  19. Tabaczynski, R., et al., Turbulent Entrainment Model for Spark-Ignition Engines, SAE, 770647 (1977), pp. 2414-2433
  20. Moreno, F., et al., Efficiency and Emissions in a Vehicle Spark Ignition Engine Fueled with Hydrogen and Methane Blends, International Journal of Hydrogen Energy, 37 (2012), 15, pp. 11495-11503
  21. Bari, S., Effect of Carbon Dioxide on the Performance of Biogas/Diesel Dual-Fuel Engine, Renewable Energy, (1996), 9, pp. 1007-1010
  22. Hacohen, J., et al., Flame Speeds in a Spark Ignited Engine, SAE Paper, 942050 (1994)
  23. Bell, S. R., et al., Fuel Composition Effects on Emissions From a Spark-Ignited Engine Operated on Simulated Biogases, Transactions of the ASME, 123 (2001)
  24. Wahono, S. K., et al., Biogas Purification Process to Increase Gen—Set Efficiency, Proceedings (International Workshop on Advanced Material for New and Renewable Energy), 11th American Institute of Physics Conference, USA, 2009
  25. Tutak, W., et al., Generator Gas as a Fuel to Power a Diesel engine, Thermal Science, 18 (2014), 1, pp. 205-216
  26. Porpatham, E., et al., Effect of Swirl on the Performance and Combustion of a Biogas Fuelled Spark Ignition Engine, Energy Conversion and Management, 76 (2013), 0, pp. 463-471
  27. Carrera, J., et al., Numerical Study on the Combustion Process of a Biogas Spark-Ignition Engine, Thermal Science, 17 (2013), 1, pp. 241
  28. Chandra, R., et al., Performance evaluation of a constant speed IC engine on CNG, Methane Enriched Biogas and Biogas, Applied Energy, 88 (2011), 11, pp. 3969-3977
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Spark ignition engine performance and emissions in a high compression engine using biogas and methane mixtures without knock occurrence

© 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