AN INTRODUCTION TO A HOMOGENEOUS CHARGE COMPRESSION IGNITION ENGINE

Authors

  • A.A. Hairuddin Faculty of Health, Engineering and Sciences, School of Mechanical and Electrical Engineering, University of Southern Queensland, Toowoomba, 4350 QLD, Australia
  • A.P. Wandel Faculty of Health, Engineering and Sciences, School of Mechanical and Electrical Engineering, University of Southern Queensland, Toowoomba, 4350 QLD, Australia
  • T. Yusaf Faculty of Health, Engineering and Sciences, School of Mechanical and Electrical Engineering, University of Southern Queensland, Toowoomba, 4350 QLD, Australia

DOI:

https://doi.org/10.15282/jmes.7.2014.3.0101

Keywords:

Diesel; HCCI; gasoline; natural gas; hydrogen

Abstract

Homogeneous charge compression ignition (HCCI) engine technology is relatively new and has not matured sufficiently to be commercialised compared with conventional engines. It can use spark ignition or compression ignition engine configurations, capitalizing on the advantages of both: high engine efficiency with low emissions levels. HCCI engines can use a wide range of fuels with low emissions levels. Due to these advantages, HCCI engines are suitable for use in a hybrid engine configuration, where they can reduce the fuel consumption even further. However, HCCI engines have some disadvantages, such as knocking and a low to medium operating load range, which need to be resolved before the engine can be commercialised. Therefore, a comprehensive study has to be performed to understand the behaviour of HCCI engines.

References

Kamil M, Rahman MM, Bakar RA. Performance evaluation of external mixture formation strategy in hydrogen fueled engine. Journal of Mechanical Engineering and Sciences. 2011;1:87-98.

Hamada KI, Rahman MM, Abdullah MA, Bakar RA, A. Aziz AR. Effect of mixture strength and injection timing on combustion characteristics of a direct injection hydrogen-fueled engine. International Journal of Hydrogen Energy. 2013;38:3793-801.

Hamada KI, Rahman MM, Aziz ARA. Parametric study of instantaneous heat transfer based on multidimensional model in direct-injection hydrogen-fueled engine. International Journal of Hydrogen Energy. 2013;38:12465-80.

Hamada KI, Rahman MM, Aziz ARA. Influence of engine speed and mixture strength on instantaneous heat transfer for direct injection hydrogen fuelled engine. Energy Education Science and Technology Part A: Energy Science and Research. 2012;30:153-72.

Kamil M, Rahman MM, Bakar RA. Modeling of common rail fuel injection system of four cylinder hydrogen fueled engine. Journal of Engineering and Technology. 2010;1:42-52.

Kamil M, Rahman MM, Bakar RA, Kadirgama K. Modeling of SI engine for duel fuels of hydrogen, gasoline and methane with port injection feeding system. Energy Education Science and Technology Part A: Energy Science and Research. 2012;29:1399-416.

Bates B, Kundzewicz ZW, Wu S, Palutikof J. Climate change and water: Intergovernmental Panel on Climate Change; 2008.

Graham RL, Turner MG, Dale VH. How increasing CO2 and climate change affect forests. BioScience. 1990:575-87.

Houghton JT, Ding Y, Griggs DJ, Noguer M, van der Linden PJ, Dai X, et al. Climate change 2001: the scientific basis2001.

Bodansky D. The Copenhagen climate change conference: a postmortem. American Journal of International Law. 2010;104:230-40.

Rob G. Watching Earth's Climate Change in the Classroom. 2005.

Jonathan P. Responses to questions on the design elements of a mandatory market-based greenhouse gas regulatory system. World Resources Institute, Washington. 2006.

Aziz Hairuddin A, Wandel AP, Yusaf T. Effect of different heat transfer models on a diesel homogeneous charge compression ignition engine. International Journal of Automotive and Mechanical Engineering. 2013;8:1292-304.

Kamil M, Rahman MM, Bakar RA. Integrated simulation model for composition and properties of gases in hydrogen fueled engine. International Journal of Automotive and Mechanical Engineering. 2013;8:1242-155.

Kamil M, Rahman MM, Bakar RA. An integrated model for predicting engine friction losses in internal combustion engines. International Journal of Automotive and Mechanical Engineering. 2014;9:1695-708.

Ogden JM, Steinbugler MM, Kreutz TG. A comparison of hydrogen, methanol and gasoline as fuels for fuel cell vehicles: implications for vehicle design and infrastructure development. Journal of Power Sources. 1999;79:143-68.

Trimm DL, Önsan ZI. Onboard fuel conversion for hydrogen-fuel-cell-driven vehicles. Catalysis Reviews. 2001;43:31-84.

Chan C. The state of the art of electric and hybrid vehicles. Proceedings of the IEEE. 2002;90:247-75.

Cho HM, He B-Q. Spark ignition natural gas engines—A review. Energy Conversion and Management. 2007;48:608-18.

Taylor AM. Science review of internal combustion engines. Energy Policy. 2008;36:4657-67.

Mohanamurugan S, Sendilvelan S. Emission and combustion characteristics of different fuel In A HCCI engine. International Journal of Automotive and Mechanical Engineering. 2011;3:279-92.

Raitanapaibule K, Aung K. Performance predictions of a hydrogen-enhanced natural gas HCCI engine. International Mechanical Engineering Congress and Exposition: American Society of Mechanical Engineers; 2005. p. 289-94.

Gharehghani A, Hosseini R, Yusaf T. Investigation of the effect of additives to natural gas on heavy-duty si engine combustion characteristics. Journal of Mechanical Engineering and Sciences. 2013;5:677-87.

Noor MM, Wandel AP, Yusaf T. The simulation of biogas combustion in a mild burner. Journal of Mechanical Engineering and Sciences. 2014;6:995-1013.

Epping K, Aceves S, Bechtold R, Dec J. The potential of HCCI combustion for high efficiency and low emissions. SAE Technical Paper No. 2002-01-1923; 2002.

Christensen M, Johansson B. Influence of mixture quality on homogeneous charge compression ignition. SAE Technical Paper No. 982454; 1998.

Kong S-C, Reitz RD. Use of detailed chemical kinetics to study HCCI engine combustion with consideration of turbulent mixing effects. Journal of Engineering for Gas Turbines and Power. 2002;124:702-7.

Najt PM, Foster DE. Compression-ignited homogeneous charge combustion. SAE Technical Paper No. 830264; 1983.

Kong S-C, Reitz RD. Numerical study of premixed HCCI engine combustion and its sensitivity to computational mesh and model uncertainties. Combustion Theory and Modelling. 2003;7:417-33.

Soylu S. Examination of combustion characteristics and phasing strategies of a natural gas HCCI engine. Energy conversion and management. 2005;46:101-19.

Killingsworth NJ, Aceves SM, Flowers DL, Krstic M. A simple HCCI engine model for control. Computer Aided Control System Design, 2006 IEEE International Conference on Control Applications. IEEE International Symposium on Intelligent Control. 2006, p. 2424-9.

Mack JH, Aceves SM, Dibble RW. Demonstrating direct use of wet ethanol in a homogeneous charge compression ignition (HCCI) engine. Energy. 2009;34:782-7.

Aceves S, Flowers D. Engine shows diesel efficiency without the emissions. Lawrence Livermore National Laboratory. 2004.

Christensen M, Johansson B, Einewall P. Homogeneous charge compression ignition (HCCI) using iso-octane, ethanol and natural gas - A comparison with spark ignition operation. SAE Paper 971676; 1997.

Hiltner J, Fiveland S, Agama R, Willi M. System efficiency issues for natural gas fueled HCCI engines in heavy-duty stationary applications. SAE Technical Paper; 2002.

Kawano D, Suzuki H, Ishii H, Goto Y, Odaka M, Murata Y, et al. Ignition and combustion control of diesel HCCI. SAE Technical Paper No. 2005-01-2132; 2005.

Pitz JW, Westbrook CK. Combustion Chemistry. 2011.

Swami Nathan S, Mallikarjuna J, Ramesh A. An experimental study of the biogas–diesel HCCI mode of engine operation. Energy Conversion and Management. 2010;51:1347-53.

Yap D, Peucheret S, Megaritis A, Wyszynski M, Xu H. Natural gas HCCI engine operation with exhaust gas fuel reforming. International Journal of Hydrogen Energy. 2006;31:587-95.

Andreae MM, Cheng WK, Kenney T, Yang J. On HCCI engine knock. SAE Technical Paper No. 2007-01-1858; 2007.

Jun D, Ishii K, Iida N. Autoignition and combustion of natural gas in a 4 Stroke HCCI engine. JSME International Journal Series B. 2003;46:60-7.

Yelvington PE, Green WH. Prediction of the knock limit and viable operating range for a homogeneous-charge compression-ignition (HCCI) engine. SAE Technical Paper No. 2003-01-1092; 2003.

Volkswagen. Volkswagen Aktiengesellschaft - 2009 Annual Report. Wolfsburg; 2009.

Audi. 2012.

Wurms R, Grigo M, Hatz W. Audi FSI technology improved performance and reduced fuel consumption. ATA-TORINO-. 2003;56:118-25.

Böhme J, Jung M, Fröhlich G, Pfannerer D, Märkle T, Felsmann C. The new 1.8 l four cylinder T-FSI engine by Audi. MTZ worldwide. 2006;67:2-5.

Barber E, Reynolds B, Tierney W. Elimination of combustion knock-Texaco combustion process. SAE Technical Paper NO. 510173; 1951.

Takagi Y. A new era in spark-ignition engines featuring high-pressure direct injection. Symposium (International) on Combustion. 1998; 27(2),2055-68.

Yao M, Zheng Z, Liu H. Progress and recent trends in homogeneous charge compression ignition (HCCI) engines. Progress in Energy and Combustion Science. 2009;35:398-437.

Onishi S, Jo SH, Shoda K, Do Jo P, Kato S. Active thermo-atmosphere combustion (ATAC)-a new combustion process for internal combustion engines. SAE Technical paper NO. 790501; 1979.

Premier A. HCCI could cut fuel consumption by 15%. Advanced Materials and Processes. 2007, 11,27.

Fengjun G, Yingnan G, Fafa L, Hua L, Honggang J, Manzhi T. Control of HCCI engine fueled with gasoline with electro-hydraulic variable valve system. 2nd International Asia Conference on Informatics in Control, Automation and Robotics. 2010, p. 250-3.

Wang Z, Shuai S-J, Wang J-X, Tian G-H. A computational study of direct injection gasoline HCCI engine with secondary injection. Fuel. 2006;85:1831-41.

Hosseini V, Checkel MD. Reformer gas application in combustion onset control of hcci engine. The Journal of Engine Research. 2009;14, 1-23.

Fuerhapter A, Unger E, Piock WF, Fraidl G. The new AVL CSI engine-HCCI operation on a multi cylinder gasoline engine. SAE Technical Paper No. 2004-01-0551; 2004.

Dec JE, Sjöberg M. HCCI Combustion: The sources of emissions at low loads and the effects of GDI fuel injection. 8th Diesel Engine Emissions Reduction Workshop. 2002, p. 25-9.

Kim DS, Lee CS. Improved emission characteristics of HCCI engine by various premixed fuels and cooled EGR. Fuel. 2006;85:695-704.

Zhong S, Wyszynski M, Megaritis A, Yap D, Xu H. Experimental investigation into HCCI combustion using gasoline and diesel blended fuels. SAE Technical Paper No. 2005-01-3733; 2005.

Carlucci A, De Risi A, Laforgia D, Naccarato F. Experimental investigation and combustion analysis of a direct injection dual-fuel diesel–natural gas engine. Energy. 2008;33:256-63.

Hairuddin AA, Wandel AP, Yusaf T. Hydrogen and natural gas comparison in diesel HCCI engines-a review. Proceedings of the 2010 Southern Region Engineering Conference (SREC 2010): Engineers Australia; 2010.

Saravanan N, Nagarajan G, Narayanasamy S. An experimental investigation on DI diesel engine with hydrogen fuel. Renewable Energy. 2008;33:415-21.

Saravanan N, Nagarajan G, Sanjay G, Dhanasekaran C, Kalaiselvan K. Combustion analysis on a DI diesel engine with hydrogen in dual fuel mode. Fuel. 2008;87:3591-9.

Verhelst S, Wallner T. Hydrogen-fueled internal combustion engines. Progress in Energy and Combustion Science. 2009;35:490-527.

Kong S-C. A study of natural gas/DME combustion in HCCI engines using CFD with detailed chemical kinetics. Fuel. 2007;86:1483-9.

Szwaja S, Grab-Rogalinski K. Hydrogen combustion in a compression ignition diesel engine. International Journal of Hydrogen Energy. 2009;34:4413-21.

Tomita E. Dual fuel HCCI combustion-High octane and high cetane number fuels. International Journal of Engine Research. 2005;6:453-63.

Tomita E, Kawahara N, Piao Z, Fujita S, Hamamoto Y. Hydrogen combustion and exhaust emissions ignited with diesel oil in a dual fuel engine. SAE Technical Paper No. 2001-01-3503; 2001.

Tomita E, Kawahara N, Piao Z, Yamaguchi R. Effects of EGR and early injection of diesel fuel on combustion characteristics and exhaust emissions in a methane dual fuel engine. SAE Technical Paper No. 2002-01-2723; 2002.

Liu C, Karim GA. A simulation of the combustion of hydrogen in HCCI engines using a 3D model with detailed chemical kinetics. International Journal of Hydrogen Energy. 2008;33:3863-75.

Saravanan N, Nagarajan G. An experimental investigation on hydrogen fuel injection in intake port and manifold with different EGR rates. International Journal of Energy and Environment. 2010;1:221-48.

Rahman MM, Hamada KI, Kadirgama K. Heat transfer of intake port for hydrogen fueled port injection engine: A steady state approach. International Journal of Physical Sciences. 2011;6:4036-43.

Rahman MM, Mohammed MK, Bakar RA. Effects of air fuel ratio and injection timing on performance for four-cylinder direct injection hydrogen fueled engine. European Journal of Scientific Research. 2009;25:214-25.

Akansu SO, Dulger Z, Kahraman N, Veziroǧlu TN. Internal combustion engines fueled by natural gas—hydrogen mixtures. International Journal of Hydrogen Energy. 2004;29:1527-39.

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Published

2014-12-31

How to Cite

[1]
A.A. Hairuddin, A.P. Wandel, and T. Yusaf, “AN INTRODUCTION TO A HOMOGENEOUS CHARGE COMPRESSION IGNITION ENGINE”, J. Mech. Eng. Sci., vol. 7, no. 1, pp. 1042–1052, Dec. 2014.

Issue

Vol. 7 (2014): December 2014

Section

Article

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