Effects of scavenging port angle and combustion chamber geometry on combustion and emmission of a high-pressure direct-injection natural gas marine engine

References

• Beale, J.C., and R.D. Reitz. 1999. Modeling spray atomization with the Kelvin-Helmholtz/Rayleigh-Taylor hybrid model. Atomization and Sprays 9 (6):623–50.
   Web of Science ®Google Scholar
• Curran, H.J., P. Gaffuri, W.J. Pitz, and C.K. Westbrook. 2002. A comprehensive modeling study of iso-octane oxidation. Combustion and Flame 129 (3):253–80.
   Web of Science ®Google Scholar
• Dukowicz, J.K. 1980. A particle-fluid numerical model for liquid sprays. Journal of Computational Physics 35 (2):229–53.
   Web of Science ®Google Scholar
• Ge, L., T. Li, and B. Wang. 2016. Optimization of combustion chamber geometry for natural gas engines with diesel micro-pilot-induced ignition. Energy Conversion and Management 122 552–63.
   Google Scholar
• Hosseini, A.A., M. Ghodrat, and M. Moghiman. 2020. Numerical study of inlet air swirl intensity effect of a Methane-Air Diffusion Flame on its combustion characteristics. Case Studies in Thermal Engineering 18 18–35.
   Google Scholar
• Juliussen, L., S. Mayer, and M. Kryger. 2013. The MAN ME-GI engine: From initial system considerations to implementation and performance optimization. CIMAC Congress, Shanghai, China, May.
   Google Scholar
• Klausner, J., H. Schaumberger, and C. Trapp. 2010. The gas engine of the future–innovative combustion and high compression ratios for highest efficiencies. CIMAC Congress, Bergen, June 14–17.
   Google Scholar
• Le Moine, J., P.K. Senecal, S.A. Kaiser, V.M. Salazar, J.W. Anders, K.I. Svensson and C.R. Gehrke. 2015. A computational study of the mixture preparation in a direct–injection hydrogen engine. Journal of Engineering for Gas Turbines and Power 137 (11):111508.
   Google Scholar
• Liang, X., G. Shu, X. Sun, Y. Wang, Y. Wang, and H. Yu. 2017. Effect of different combustion models and alternative fuels on two‐stroke marine diesel engine performance. Apply Thermal Energy 115:597‐606.
   Google Scholar
• Liang, J., Z. Zhang, G. Li, Q. Wan, L. Xu, and S. Fan. 2019. Experimental and kinetic studies of ignition processes of the methane–n-heptane mixtures. Fuel 235:522–29. doi:10.1016/j.fuel.2018.08.041.
   Web of Science ®Google Scholar
• Liu, H., J. Li, J. Wang, C. Wu, B. Liu, J. Dong, T. Liu, Y. Ye, H. Wang, and M. Yao. 2019. Effects of injection strategies on low‐speed marine engines using the dual fuel of high‐pressure direct‐injection natural gas and diesel. Energy Science & Engineering 7(5):1994–2010. doi:10.1002/ese3.406.
   Web of Science ®Google Scholar
• Liu, J., J. Wang, and H. Zhao. 2019. Optimization of the combustion chamber and fuel injection of a diesel/natural gas dual-fuel engine. Energy Procedia 158:1418–24. doi:10.1016/j.egypro.2019.01.344.
   Google Scholar
• Liu, J., B. Ma, and H.B. Zhao. 2020. Combustion parameters optimization of a diesel/natural gas dual fuel engine using genetic algorithm. Fuel 260:116365.
   Google Scholar
• Ma, J., X. Wang, and H. Zhao. 2018. Analysis of the effect of bore/stroke ratio and scavenge port angles on the scavenging process in a two-stroke boosted uniflow scavenged direct injection gasoline engine. Proceedings of the Institution of Mechanical Engineers 232 (13):105–17.
   Google Scholar
• Metcalfe, W.K., S.M. Burke, S.S. Ahmed, and H.J. Curran. 2013. A hierarchical and comparative kinetic modeling study of C1–C2 hydrocarbon and oxygenated fuels. International Journal of Chemical Kinetics 45 (10):638–75.
   Web of Science ®Google Scholar
• Nakagawa, H., K. Satoshi, and M. Tateishi. 1990. Airflow in the cylinder of a 2-stroke cycle uniflow scavenging diesel engine during compression stroke. JSME International Journal 33 (3):591–98.
   Google Scholar
• Nemati, A., J.C. Ong, M.V. Jensen, et al. 2020. Numerical study of the scavenging process in a large two-stroke marine engine using URANS and LES turbulence models. SAE Technical Paper.
   Google Scholar
• Rao, V., and D. Honnery. 2014. Application of a multi-step soot model in a thermodynamic diesel engine model. Fuel 135:269–78.
   Google Scholar
• Richards, K., P. Senecal, and E. Pomraning. 2016. CONVERGE manual (Version 2.3). Convergent Science Inc 12:45–56.
   Google Scholar
• Rizvi, I. H., and R. Gupta. 2021. Numerical investigation of injection parameters and piston bowl geometries on emission and thermal performance of DI diesel engine. SN Applied Sciences 3 (6):1–15.
   Google Scholar
• Scarcelli, R., T. Wallner, H. Obermair, V.M. Salazar, and S.A. Kaiser. 2010. CFD and optical investigations of fluid dynamics and mixture formation in a DI-H2ICE. ASME 2010 Internal Combustion Engine Division Fall Technical Conference. New York, NY: American Society of Mechanical Engineers, 175–88.
   Google Scholar
• Scarcelli, R., T. Wallner, N. Matthias, V. Salazar, and S. Kaiser. 2011a. Mixture formation in direct injection hydrogen engines: CFD and optical analysis of single-and multi-hole nozzles. SAE International Journal of Engines 4 (2):2361–75.
   Google Scholar
• Scarcelli, R., T. Wallner, N. Matthias, et al. 2011b. Numerical and optical evolution of gaseous jets in direct injection hydrogen engines. SAE Technical Paper.
   Google Scholar
• Senecal, P.K., K.J. Richards, E. Pomraning, et al. 2007. A new parallel cut-cell Cartesian CFD code for rapid grid generation applied to in-cylinder diesel engine simulations (No. 2007-01-0159). SAE Technical Paper.
   Google Scholar
• Takasaki, K. 2012. Observations on the development and practical application of marine gas engines. ClassNk Technical Bulletin 30:1‐9.
   Google Scholar
• Taskiran, O., and M. Ergeneman. 2014. Trajectory based droplet collision model for spray modeling. Fuel 115:896–900.
   Google Scholar
• Temizer, İ., and Ö. Cihan. 2021. Heat and flow analysis of different piston bowl geometries in a diesel engine. International Journal of Automotive Science and Technology 5 (3):206–13.
   Google Scholar
• Wang, J.H., E.J. Hu, Z.H. Huang, Z. Ma, Z. Tian, J. Wang, and Y. Li. 2008. An experimental study of premixed laminar methane/oxygen/argon flames doped with hydrogen at low pressure with synchrotron photoionization. Chinese Science Bulletin 53 (8):1262–69.
   Google Scholar
• Wang, H., B. Yan, and Z. Zheng. 2018. The effect of combustion chamber geometry on in-cylinder flow and combustion process in a stoichiometric operation natural gas engine with EGR. Applied Thermal Engineering 129 199–211 https://doi.org/10.1016/j.applthermaleng.2017.09.067.
   Google Scholar
• White, R. 2006. Simultaneous diesel and natural gas injection for dual-fueling compression-ignition engines. Sydney, Australia: University of New South Wales.
   Google Scholar
• Xu, Z., F. Ji, S. Ding, Y. Zhao, Y. Wang, Q. Zhang, F. Du, and Y. Zhou. 2021. Simulation and experimental investigation of swirl-loop scavenging in two-stroke diesel engine with two poppet valves. International Journal of Engine Research 22 (6):2021–34.
   Google Scholar
• Yakhot, V., and S.A. Orszag. 1986. Renormalization group analysis of turbulence. I. Basic theory. Journal of Computational Physics 1 (1):3–51.
   Google Scholar
• Zhang, Z., P. Jia, S. Feng, J. Liang, Y. Long, and G. Li. 2018. Numerical simulation of exhaust reforming characteristics in catalytic fixed-bed reactors for a natural gas engine. Chemical Engineering Science 191: 200–07.doi: 10.1016/j.ces.2018.06.061
   Google Scholar
• Zheng, X.U., J.I. Fenzhu, D. Shuiting, Z.H. Yunhai, Z.H. Yu, Q. Zhang, and D.U. Farong. 2021. Effect of scavenge port angles on flow distribution and performance of swirl-loop scavenging in 2-stroke aircraft diesel engine. Chinese Journal of Aeronautics 34 (3):105–17.
   Google Scholar