Numerical investigations on HCCI engine with increased induction induced swirl and engine speed

详细信息    查看全文

• 作者：T. Karthikeya Sharma ; G. Amba Prasad Rao…
• 关键词：HCCI engine ; ECFM ; 3Z ; swirl ratio ; emissions and performance
• 刊名：Journal of Central South University
• 出版年：2015
• 出版时间：October 2015
• 年：2015
• 卷：22
• 期：10
• 页码：3837-3848
• 全文大小：2,715 KB
• 参考文献：[1]NAJAFABADI I M, ABDUL N A. Homogeneous charge compression ignition combustion: Challenges and proposed solutions [J]. Journal of Combustion, 2013, Doi.10.1155/2013/783789.
  [2]SHARMA T K, RAO G A P, MADHU M K. Effect of swirl on performance and emissions of CI engine in HCCI mode [J]. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 2014, DOI: 10.1007/s40430-014-0247-7.
  [3]CIPOLLA G, VASSALLO A, CATANIA A E, EZIO S, STAN C, DRISCHMANN L. Combined application of CFD modeling and pressure-based combustion diagnostics for the development of a low compression ratio high-performance diesel engine [J]. SAE Technical Paper, No. 2007-24-0034.
  [4]COLIN O, BENKENIDA A. The 3-zone extended coherent flame model (ECFM3Z) for computing premixed/diffusion combustion [J]. Oil & Gas Science and Technology鈥揜ev. IFP, 2004, 59(6): 593鈥?09.CrossRef
  [5]RAVET F, ABOURI D, ZELLAT M, DURANTI S. Advances in combustion modeling in STAR-CD: Validation of ECFM CLE-H model to engine analysis [C]// 18th Int Multidimensional Engine Users鈥?Meeting at the SAE Congress. Detroit, 2008: 1鈥?.
  [6]SUBRAMANIAN G, VERVISH L, RAVET F. New developments in turbulent combustion modeling for engine design: ECFM-CLEH combustion submodel [J]. SAE International, No. 2007-01-0154.
  [7]HOSSAINPOUR S, BINESH A R. Investigation of fuel spray atomization in a DI heavy-duty diesel engine and comparison of various spray breakup models [J]. Fuel, 2009, 88(5): 799鈥?05.CrossRef
  [8]BAI C, GOSMAN A D. Development of methodology for spray impingement simulation [J]. SAE Technical Paper, No. 950283-1995.
  [9]REITZ R D, DIWAKAR R. Structure of high-pressure fuel spray [J]. SAE Technical Paper Series, SAE Paper No. 870598-1987.
  [10]REITZ R D, DIWAKAR R. Effect of drop breakup on fuel sprays [J]. SAE Technical Paper Series, SAE Paper No. 860649-1986.
  [11]ANGELBERGER C, POINSOT T, DELHAY B. Improving near-wall combustion and wall heat transfer modeling in SI engine computations [J]. SAE Technical Paper, No. 972881-1997.
  [12]BOWMAN E J, SIEBERS A, ALTENDORF K. Bafilomycins: A class of inhibitors of membrane ATPases from microorganisms, animal cells, and plant cells [J]. Proceedings of the National Academy of Sciences, 1988, 85(21): 7972鈥?976.CrossRef
  [13]HEYWOOD J B. Internal combustion engine fundamentals [M]. New York: McGraw-Hill Company, 1988.
  [14]KARLSSON A, MAGNUSSON I, BALTHASAR M, MAUSS F. Simulation of soot formation under diesel engine conditions using a detailed kinetic soot model [J]. SAE Technical Paper, No. 981022-1998.
  [15]MOUREAU V, LARTIGUE G, SOMMERER Y, ANGELBERGER C, COLIN O, POINSOT T. Numerical methods for unsteady compressible multi-component reacting flows on fixed and moving grids [J]. Journal of Computational Physics, 2005, 202(2): 710鈥?36.MATH MathSciNet CrossRef
  [16]VENKATESWARAN S P, NAGARAJAN G. Effects of the Re-entrant bowl geometry on a DI turbocharged diesel engine performance and emissions鈥擜 CFD approach [J]. Journal of Engineering for Gas Turbines and Power, 2010, 132(2): 1113鈥?122.
  [17]MARC Z, DURANTI S, LIANG Yong-jun, KRALJ C, SCHMIDT G, DUCLOS J M. Towards a universal combustion model in STAR-CD for IC engines: From GDI to HCCI and application to DI diesel combustion optimization [C]// Proceeding of 14th International Multidimensional Engine User鈥檚 Meeting, SAE Cong. 2005: 1鈥?.
  [18]BAKHSHAN Y, TARAHOMI A R. Multi-dimensional simulation of n-heptane combustion under HCCI engine condition using detailed chemical kinetics [J]. Journal of Engine Research, 2011, 22: 3鈥?2.
  [19]GANESH D, NAGARAJAN G. Homogeneous charge compression ignition (HCCI) combustion of diesel fuel with external mixture formation [J]. Energy, 2010, 35(1): 148鈥?57.CrossRef
  [20]ANNARITA V, MAGI V. A comprehensive investigation on the emissions of ethanol HCCI engines [J]. Applied Energy, 2012, 93: 277鈥?87.CrossRef
  [21]DEMBINSKI H W R, HANS-ERIK A. Optical study of swirl during combustion in a CI engine with different injection pressures and swirl ratios compared with calculations [J]. SAE Technical Paper, No. 2012-01-0682.
  [22]MAGNUS S, DEC J E. Effects of engine speed, fueling rate, and combustion phasing on the thermal stratification required to limit HCCI knocking intensity [J]. SAE Technical Paper, No. 2005-01-2125.
  [23]GU Yong-xian, MAYOR J R, DAHM W J A. Turbulence-augmented minimization of combustion time in mesoscale internal combustion engines [C]// 44th AIAA Aerospace Sciences Meeting and Exhibit. AIAA, 2006: 16293鈥?6312.
  [24]KURNIAWAN H W, SHAHRIR A, KAMARUZZAMAN S, ZULKIFLI M N, AZHARI S. CFD investigation of fluid flow and turbulence field characteristics in a four-stroke automotive direct injection engine [J]. Journal of Institution of Engineers, 2008, 69(1): 1鈥?2.
  [25]KRISHNA B M, MALLIKARJUNA J M. Effect of engine speed on in-cylinder tumble flows in a motored internal combustion engine-An experimental investigation using particle image velocimetry [J]. Journal of Applied Fluid Mechanics, 2011, 4(1): 1鈥?4.
  [26]GORYNTSEV D, SADIKI A, KLEIN M, JANICKA J. Large eddy simulation based analysis of the effects of cycle-to-cycle variations on air鈥揻uel mixing in realistic DISI IC-engines [J]. Proceedings of the Combustion Institute, 2009, 32(2): 2759鈥?766.CrossRef
  
• 作者单位：T. Karthikeya Sharma (1)
  G. Amba Prasad Rao (1)
  K. Madhu Murthy (1)
  
  1. Department of Mechanical Engineering, NIT Warangal, 506004, T.S, India
  
• 刊物类别：Engineering
• 刊物主题：Engineering, general
  Metallic Materials
  Chinese Library of Science
  
• 出版者：Central South University, co-published with Springer
• ISSN：2227-5223

文摘

Homogeneous charge compression ignition (HCCI) mode of combustion is popularly known for achieving simultaneous reduction of NO _x as well as soot emissions as it combines the compression ignition (CI) and spark ignition (SI) engine features. In this work, a CI engine was simulated to work in HCCI mode and was analyzed to study the effect of induction induced swirl under varying speeds using three-zone extended coherent flame combustion model (ECFM-3Z, compression ignition) of STAR-CD. The analysis was done considering speed ranging from 800 to 1600 r/min and swirl ratios from 1 to 4. The present study reveals that ECFM-3Z model has well predicted the performance and emissions of CI engine in HCCI mode. The simulation predicts reduced in-cylinder pressures, temperatures, wall heat transfer losses, and piston work with increase in swirl ratio irrespective of engine speed. Also, simultaneous reduction in CO₂ and NO _x emissions is realized with higher engine speeds and swirl ratios. Low speeds and swirl ratios are favorable for low CO₂ emissions. It is observed that increase in engine speed causes a marginal reduction in in-cylinder pressures and temperatures. Also, higher turbulent energy and velocity magnitude levels are obtained with increase in swirl ratio, indicating efficient combustion necessitating no modifications in combustion chamber design. The investigations reveal a total decrease of 38.68% in CO₂ emissions and 12.93% in NO _x emissions when the engine speed increases from 800 to 1600 r/min at swirl ratio of 4. Also an increase of 14.16% in net work done is obtained with engine speed increasing from 800 to 1600 r/min at swirl ratio of 1. The simulation indicates that there is a tradeoff observed between the emissions and piston work. It is finally concluded that the HCCI combustion can be regarded as low temperature combustion as there is significant decrease in in-cylinder temperatures and pressures at higher speeds and higher swirl ratios. Keywords HCCI engine ECFM-3Z swirl ratio emissions and performance