Abstract
Compression ignition of homogeneous charges in internal combustion (IC) engines is expected to offer high efficiency of DI diesel engines without high levels of NOx and particulate emissions. This study is intended to find ways of extending the rich limit of HCCI operation, one of the problems yet to be overcome. Exhaust emissions characteristics are also explored through analyses of the combustion products. DME fuel, either mixed with air before induction or directly injected into the combustion chamber of a rapid compression and expansion machine, is compressed to ignite under various conditions of compression ratio, equivalence ratio, and injection timing. The characteristics of the resulting combustion and exhaust emissions are discussed in terms of the rate of heat release computed from the measured pressure, and the concentrations of THC, CO, and NOx are measured by FT-IR and CLD. The experimental data to date show that operation without knock is possible with mixtures of higher equivalence ratio when DME is directly injected rather than when it is inducted in the form of a perfectly homogeneous fuel-air mixture. Although fuel injected early in the compression stroke promotes homogeneity of the DME-air mixture in the cylinder, it causes the mixture to ignite too early to secure good thermal efficiency and knock-free operation at high loads. Low temperature reactions occur at about 660K regardless of the fueling methods, fuel injection timing and equivalence ratio. The main components of hydrocarbon emissions turned out to be unburned fuel (DME), formaldehyde and methane.
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References
Cho, S. H., Kim, K. S. and Lim, M. T. (2004). Development of a rapid compression expansion machine and compression ignition combustion of homogeneous premixtures. Korean Society of Automotive Engineers 12,2, 83–90.
Chung, J. W., Kang, J. H., Kim, N. H., Kang, W. and Kim, B. S. (2008). Effects of the fuel injection ratio on the emission and compression performances of the partially premixed charge compression ignition combustion engine applied with the split injection method. Int. J. Automotive Technology 9,1, 1–8.
Dec, J. E., Hwang, W. and Sjoberg, M. (2006). An investigation of thermal stratification in HCCI engines using chemiluminescence imaging. SAE Paper No. 2006-01-1518.
Gray, A. W. and Ryan, T. W. (1997). Homogeneous charge compression ignition (HCCI) of diesel fuel. SAE Paper No. 971676.
Hamada, K., Niijima, S., Yoshida, K., Shoji, H., Shimada, K. and Shibano, K. (2005). The effects of the compression ratio, equivalence ratio, and intake air temperature on ignition timing in an HCCI engine using DME fuel. SAE Paper No. 2005-32-0002.
Iida, N., Yamasaki, Y., Sato, S., Kumano, K., Kojima, Y. (2004). Study on auto-ignition and combustion mechanism of HCCI engine. SAE Paper No. 2004-32-0095.
Inagaki, K., Fuyuto, T., Nishikawa, K., Nakakita, K. and Sakata, I. (2006). Dual-fuel PCI combustion controlled by in-cylinder stratification of ignitability. SAE Paper No. 2006-01-0028.
Kumano, K. and Iida, N. (2004). Analysis of the effect of charge inhomogeneity on HCCI combustion by chemiluminescence measurement. SAE Paper No. 2004-01-1902.
Lim, O. T., Nakano, H. and Iida, N. (2006). The research about the effects of thermal stratification on n-heptane/iso-octane-air mixture HCCI combustion using a rapid compression machine. SAE Paper No. 2006-01-3319.
Longbao, Z., Hewu, W., Deming, J. and Zuohua, H. (1999). Study of performance and combustion characteristics of a DME-fueled light-duty direct-injection diesel engine. SAE Paper No. 1999-02-3669.
Ogawa, H., Miyamoto, N. and Yagi, M. (2003). Chemicalkinetic analysis on PAH formation mechanisms of oxygenated fuels. SAE Paper No. 2003-01-3190.
Sato, S. and Iida, N. (2003). Analysis of DME homogeneous charge compression ignition combustion. JSAE Paper No. 20030236.
Sjöberg, M. and Dec, J. E. (2006). Smoothing HCCI heatrelease rates using partial fuel stratification with two-stage ignition fuels. SAE Paper No. 2006-01-0629.
Sjöberg, M., Dec, J. E. and Cernansky, N. P. (2005). Potential of thermal stratification and combustion retard for reducing pressure-rise rates in HCCI engines, Based on multi-zone modeling and experiments. SAE Paper No. 2005-01-0113.
Teng, H., McCandless, J. C. and Schneyer, J. B. (2004). Thermodynamic properties of dimethyl ether — An alternative fuel for compression-ignition engines. SAE Paper No. 2004-01-0093.
Thring, R. H. (1989). Homogeneous-charge compressionignition engine. SAE Paper No. 892068.
Yao, M., Zheng, Z., Xu, S. and Fu, M. (2003). Experimental study on the combustion process of dimethyle ether (DME). SAE Paper No. 2003-01-3194.
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Jung, G.S., Sung, Y.H., Choi, B.C. et al. Effects of mixture stratification on HCCI combustion of DME in a rapid compression and expansion machine. Int.J Automot. Technol. 10, 1–7 (2009). https://doi.org/10.1007/s12239-009-0001-9
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DOI: https://doi.org/10.1007/s12239-009-0001-9