[1]ISO 8178-4. Reciprocating Internal Combustion Engines-exhaust Emission Measurement[S]. Geneva: International Standard,1996.
[2]HE Shuang, DU Baoguo, FENG Liyan, et al. A Numerical Study on Combustion and Emission Characteristics of a Medium-speed Diesel Engine Using, In-cylinder Cleaning Technologies[J]. Energies,2015,8(5):4118-4137.
[3]SAVVA N S, HOUNTALA D T. Evolution and Application of a Pseudo-multi-zone model for the Prediction of NOx, Emissions from Large-scale Diesel Engines at Various Operating Conditions[J]. Energy Conversion & Management,2014,85(9):373-388.
[4]SU Liwang, LI Xiangrong, ZHANG Zheng, et al. Numerical Analysis on the Combustion and Emission Characteristics of Forced Swirl Combustion System for DI Diesel Engines[J]. Energy Conversion & Management,2014,86(10):20-27.
[5]WEI Shengli, WANG Feihu, LENG Xianyin, et al. Numerical Analysis on the Effect of Swirl Ratios on Swirl Chamber Combustion System of DI Diesel Engines[J]. Energy Conversion & Management,2013,75(4):184-190.
[6]RAKOPOULOS C D, KOSMADAKIS G M, PARIOTIS E G. Investigation of Piston Bowl Geometry and Speed Effects in a Motored HSDI Diesel Engine Using a CFD Against a Quasi-dimensional Model[J]. Energy Conversion & Management,2010,51(3):470-484.
[7]LI Jing, YANG W M, AN Hui, et al. Effects of Piston Bowl Geometry on Combustion and Emission Characteristics of Biodiesel Fueled Diesel Engines[J]. Fuel,2013,120(1):66-73.
[8]GAFOOR C P A, GUPTA R. Numerical Investigation of Piston Bowl Geometry and Swirl Ratio on Emission from Diesel Engines[J]. Energy Conversion & Management,2015,101(1):541-551.
[9]TAGHAVIFAE H, KHALILARYA S, JAFARMADAR S. Engine Structure Modifications Effect on the Flow Behavior, Combustion, and Performance Characteristics of DI Diesel Engine[J]. Energy Conversion & Management,2014,85(9):20-32.
[10]JAFARMADAR S, TAGHAVIFAE H,
TAGH-
AVIFAE H, et al. Numerical Assessment of Flow Dynamics for Various DI Diesel Engine Designs Considering Swirl Number and Uniformity Index[J]. Energy Conversion & Management,2016,110:347-355.
[11]HANJALIC K, POPOVAC M, HADZIABDIC M. A Robust Near-wall Elliptic-relaxation Eddy-viscosity Turbulence Model for CFD[J]. International Journal of Heat & Fluid Flow,2004,25(6):1047-1051.
[12]赵昌普,朱云尧,杨俊伟,等. 燃烧室形状对增压中冷柴油机燃烧和排放影响的数值模拟[J]. 内燃机学报,2013,31(4):318-323.
ZHAO Changpu, ZHU Yunyao, YANG Junwei, et al. Effects of Combustion Chamber Geometry on the Combustion and Emissions of Turbocharged Inter-cooling Diesel Engine[J]. Transactions of CSICE,2013,31(4):318-323.
[13]赵昌普,宋崇林,李晓娟,等. 喷油定时和燃烧室形状对柴油机燃烧和排放的影响的研究[J]. 燃烧科学与技术,2009,15(5):393-398.
ZHAO Changpu, SONG Chonglin, LI Xiaojuan, et al. Effects of Fuel Injection Timing and Combustion Chamber Geometry on Combustion Process and Emissions of Diesel Engine[J]. Journal of Combustion Science and Technology,2009,15(5):393-398.
[14]ULUDOGAN A, FOSTER D E, REITZ R D. Modeling the Effect of Engine Speed on the Combustion Process and Emissions in a di Diesel Engine[J]. Sae Technical Papers,1996,962056.
[15]周龙保. 内燃机学[M]. 北京: 机械工业出版社,2006.
ZHOU Longbao.Internal Combustion Engine[M]. Beijing: Mechanical Industry Press,2006.
[16]MOBASHERI R, PENG Zhijun. The Development and Application of Homogeneity Factor on DI Diesel Engine Combustion and Emissions[J]. SAE Technical Papers, 2013,2013-01-0880. |