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A full-scale CFD model of scavenge air inlet temperature on two-stroke marine diesel engine combustion and exhaust emission characteristics

Year 2024, , 493 - 517, 18.09.2024
https://doi.org/10.58559/ijes.1467215

Abstract

Most ships in the maritime transport sector are equipped with large two-stroke marine diesel engines in their propulsion systems. Therefore, ensuring stable and long-term operation of these engines is crucial to maintaining freight transportation. The design of the ship's machinery, particularly the diesel engine, is a crucial step in achieving this goal. Computational Fluid Dynamics (CFD) tools can be used to achieve this goal. This article presents a full-scale CFD study on the effect of different scavenge air inlet temperatures (300, 312, 330 and 340 K) on the combustion process and generation of exhaust emissions in a two-stroke marine diesel engine using ANSYS Forte software. Regarding the cylinder pressure, the presented model agrees well with experimental data. The maximum cylinder pressure decreases as the scavenge air inlet temperature increases, whereas the maximum cylinder temperature increases as the scavenge air inlet temperature increases. The maximum NOX, CO and UHC emission values are calculated to be 2256.5, 20375.8 and 3743.9 ppm, respectively, at a scavenge air inlet temperature of 340 K. Due to the higher combustion temperature caused by the increasing scavenge air inlet temperature, it is observed that the exhaust emission levels increase.

References

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  • [2] Liang X, Liu Z, Wang K, Wang X, Zhu Z, Xu C, Liu B. Impact of pilot injection on combustion and emission characteristics of a low-speed two-stroke marine diesel engine. Energies 2021; 14(2): 417.
  • [3] Cong YJ, Gan HB, Wang HY. Parameter investigation of the pilot fuel post-injection strategy on performance and emissions characteristics of a large marine two-stroke natural gas-diesel dual-fuel engine. Fuel 2022; 323: 124404.
  • [4] Wei H, Chen X, Wang G, Zhou L, An S, Shu G. Effect of swirl flow on spray and combustion characteristics with heavy fuel oil under two-stroke marine engine relevant conditions. Applied Thermal Engineering 2017; 124: 302–14.
  • [5] He F, Wei J. Numerical simulation of scavenging process of large 2-stroke marine diesel engine. 2nd International Conference on Automatic Control and Information Engineering, Atlantis Press, 2017.
  • [6] Yılmaz H. Assessment of Combustion and Emission Characteristics of Various Gas Mixtures under Different Combustion Techniques. International Journal of Energy Studies 2020; 5 (1): 13-41.
  • [7] Zhang B, Zhang P, Zhang Z, Yang SS, Wang C, Zeng F. Numerical simulation of flow field characteristics of the cooling water jacket of a marine diesel engine. 7th International Conference on Energy Materials and Environment Engineering (ICEMEE 2021), 261, 02040, 2021.
  • [8] Menon P, Mittal M. Modeling and simulation of diesel engines using CFD and its applications in optimizing various in-cylinder techniques. In: Agarwal, A.K., Kumar, D., Sharma, N., Sonawane, U. (eds) Engine Modeling and Simulation. Energy, Environment, and Sustainability. Springer, Singapore, 2021; 89-143.
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  • [13] Mavrelos C, Theotokatos G. Numerical investigation of a premixed combustion large marine two-stroke dual fuel engine for optimising engine settings via parametric runs. Energy Conversion and Management 2018; 160: 48-59.
  • [14] Sigurdsson E. Scavenging flow in a two-stroke diesel engine. MSc Thesis, Technical University of Denmark, 2011.
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  • [16] Hafiz MNM, Hairuddin AA, Md Rezali KA, Masuri SU, Mossa MAA. Numerical study of piston bowl geometries on PFI-HCCI engine performance. Journal of Mechanical Engineering and Sciences 2023; 17 (4): 9689-9699.
  • [17] Ghazal OH. Reducing Diesel Engine Emission using Reactivity Controlled Approach. Journal of Ecological Engineering 2018; 19 (1): 94-103.
  • [18] Altun Ş, Fırat M, Okcu M. Numerical Analysis on the Effect of Hydrogen as Low-Reactivity Fuel in a 3D Scanned Engine Model Operated on RCCI Mode. Arabian Journal for Science and Engineering 2023; 48: 11545–11557.
  • [19] Rahman KM, Ahmed Z. Combustion and Emission Characteristics of a Diesel Engine Operating with Varying Equivalence Ratio and Compression Ratio - A CFD Simulation. Journal of Engineering Advancements 2020; 1 (3): 100-110.
  • [20] Ortiz-Imedio R, Ortiz A, Ortiz I. Comprehensive analysis of the combustion of low carbon fuels (hydrogen, methane and coke oven gas) in a spark ignition engine through CFD modeling. Energy Conversion and Management 2022; 251: 114918.
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  • [22] Sigurdsson E, Ingvorsen KM, Jensen MV, Mayer S, Matlok S, Walther JH. Numerical analysis of the scavenge flow and convective heat transfer in large two-stroke marine diesel engines. Applied Energy 2014; 123: 37-46.
  • [23] Abani N, Kokjohn S, Park SW, Bergin M, Munnannur A, Ning W, Sun Y, Reitz RD. An improved spray model for reducing numerical bibliomiscmeter dependencies in diesel engine CFD simulations. SAE Technical Paper Series 2008; Paper no: 2008-01-0970.
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  • [25] Yang C, Takamoto Y, Okajima A, Obokata T, Long W. Comparison of computed and measured high-pressure conical diesel sprays. SAE Technical Paper Series 2000; Paper no: 2000-01-0951.
  • [26] Hou S, Schmidt DP. Adaptive collision meshing and satellite droplet formation in spray simulations. International Journal of Multiphase Flow 2006; 32: 935-956.
  • [27] Ra Y, Reitz RD. A vaporization model for discrete multi-component fuel sprays. International Journal of Multiphase Flow 2009; 35: 101-117.
  • [28] ANSYS Inc., ANSYS Forte 2020 R1 Theory Manual.
  • [29] Han Z, Xu Z, Trigui N. Spray/wall interaction models for multidimensional engine simulation. International Journal of Engine Research 2000; 1(1): 127-146.
  • [30] Patel A., King SC., Reitz RD. Development and validation of a reduced reaction mechanism for HCCI engine simulations. SAE Technical Paper Series 2004; Paper no: 2004-01-0558.
  • [31] Liang L, Shelburn A, Wang C, Hodgson D, Meeks E. A New automatic and dynamic mesh generation technique based on immersed boundary method. International Multidimensional Engine Modeling User's Group Meeting, Detroit, Michigan, 2011.
  • [32] Pehlivan EF, Altın, İ. Exergy analysis under consideration of operational parameters by numerical approach in a two-stroke marine diesel engine. Fuel 2024; 368: 131650.
  • [33] Han Z, Reitz RD. Turbulence modeling of internal combustion engines using RNG k-ε models. Combustion Science and Technology 1995; 106: 267-295.
  • [34] Tan Z. Multi-dimensional modeling of ignition and combustion in premixed and DIS/CI (direct injection spark/compression ignition) engines. PhD Thesis, University of Wisconsin-Madison, 2003.
  • [35] ANSYS Inc., ANSYS Chemkin-Pro Theory Manual. 2022, USA.
  • [36] He X, Tan Q, Wu Y, Wei C. Optimization of marine two-stroke diesel engine based on air intake composition and temperature control. Atmosphere 2022; 13(2): 355.
  • [37] Lu D, Theotokatos G, Zhang J, Zeng H, Cui K. Comparative Assessment and Parametric Optimisation of Large Marine Two-Stroke Engines with Exhaust Gas Recirculation and Alternative Turbocharging Systems. Journal of Marine Science and Engineering 2022; 10 (3): 351.
  • [38] He X, Tan Q, Wu Y, Wei C. Optimization of Marine Two-Stroke Diesel Engine Based on Air Intake Composition and Temperature Control. Atmosphere 2022; 13 (2): 355.
  • [39] Ceylan BO. Investigation of seasonal effects on two-stroke marine diesel engine performance parameters and emissions. Journal of Marine Science Applications 2023; 22: 795-808.
  • [40] Nemati A, Ong JC, Jensen MV, Pang KM, Mayer S, Walther JH. Numerical Study of the Scavenging Process in a Large Two-Stroke Marine Engine Using URANS and LES Turbulence Models. SAE Technical Paper Series 2020; Paper no: 2020-01-2012.
Year 2024, , 493 - 517, 18.09.2024
https://doi.org/10.58559/ijes.1467215

Abstract

References

  • [1] Zhu Z, Liang X, Cui L, Wang K, Wang X, Zhu S. Simulation research on the injection strategy of a diesel-ammonia dual-fuel marine engine. Energy Fuels 2023; 37(13): 9736–45.
  • [2] Liang X, Liu Z, Wang K, Wang X, Zhu Z, Xu C, Liu B. Impact of pilot injection on combustion and emission characteristics of a low-speed two-stroke marine diesel engine. Energies 2021; 14(2): 417.
  • [3] Cong YJ, Gan HB, Wang HY. Parameter investigation of the pilot fuel post-injection strategy on performance and emissions characteristics of a large marine two-stroke natural gas-diesel dual-fuel engine. Fuel 2022; 323: 124404.
  • [4] Wei H, Chen X, Wang G, Zhou L, An S, Shu G. Effect of swirl flow on spray and combustion characteristics with heavy fuel oil under two-stroke marine engine relevant conditions. Applied Thermal Engineering 2017; 124: 302–14.
  • [5] He F, Wei J. Numerical simulation of scavenging process of large 2-stroke marine diesel engine. 2nd International Conference on Automatic Control and Information Engineering, Atlantis Press, 2017.
  • [6] Yılmaz H. Assessment of Combustion and Emission Characteristics of Various Gas Mixtures under Different Combustion Techniques. International Journal of Energy Studies 2020; 5 (1): 13-41.
  • [7] Zhang B, Zhang P, Zhang Z, Yang SS, Wang C, Zeng F. Numerical simulation of flow field characteristics of the cooling water jacket of a marine diesel engine. 7th International Conference on Energy Materials and Environment Engineering (ICEMEE 2021), 261, 02040, 2021.
  • [8] Menon P, Mittal M. Modeling and simulation of diesel engines using CFD and its applications in optimizing various in-cylinder techniques. In: Agarwal, A.K., Kumar, D., Sharma, N., Sonawane, U. (eds) Engine Modeling and Simulation. Energy, Environment, and Sustainability. Springer, Singapore, 2021; 89-143.
  • [9] Chryssakis C, Kaiktsis L, Frangopoulos A. Computational investigation of in-cylinder NOx emissions reduction in a large marine diesel engine using water addition strategies. SAE Technical Paper Series 2010; Paper no: 2010-01-1257.
  • [10] Liu H, Zhang H, Wang H, Zou X, Yao M. A numerical study on combustion and emission characteristics of marine engine through miller cycle coupled with EGR and water emulsified fuel. SAE Technical Paper Series 2016; Paper no: 2016-01-2187.
  • [11] Yang R, Theotokatos G, Vassalos D. CFD modelling and numerical investigation of a large marine two-stroke dual fuel direct injection engine. Ships and Offshore Structures 2022; 17 (5): 1062–1074.
  • [12] Senčić T, Mrzljak V, Medica-Viola V, Wolf I. CFD analysis of a large marine engine scavenging process. Processes 2022; 10 (1): 141.
  • [13] Mavrelos C, Theotokatos G. Numerical investigation of a premixed combustion large marine two-stroke dual fuel engine for optimising engine settings via parametric runs. Energy Conversion and Management 2018; 160: 48-59.
  • [14] Sigurdsson E. Scavenging flow in a two-stroke diesel engine. MSc Thesis, Technical University of Denmark, 2011.
  • [15] Woodyard D. Pounders Marine Diesel Engines and Gas Turbines. Elsevier Butterworth-Heinemann, 8th edition, 2004.
  • [16] Hafiz MNM, Hairuddin AA, Md Rezali KA, Masuri SU, Mossa MAA. Numerical study of piston bowl geometries on PFI-HCCI engine performance. Journal of Mechanical Engineering and Sciences 2023; 17 (4): 9689-9699.
  • [17] Ghazal OH. Reducing Diesel Engine Emission using Reactivity Controlled Approach. Journal of Ecological Engineering 2018; 19 (1): 94-103.
  • [18] Altun Ş, Fırat M, Okcu M. Numerical Analysis on the Effect of Hydrogen as Low-Reactivity Fuel in a 3D Scanned Engine Model Operated on RCCI Mode. Arabian Journal for Science and Engineering 2023; 48: 11545–11557.
  • [19] Rahman KM, Ahmed Z. Combustion and Emission Characteristics of a Diesel Engine Operating with Varying Equivalence Ratio and Compression Ratio - A CFD Simulation. Journal of Engineering Advancements 2020; 1 (3): 100-110.
  • [20] Ortiz-Imedio R, Ortiz A, Ortiz I. Comprehensive analysis of the combustion of low carbon fuels (hydrogen, methane and coke oven gas) in a spark ignition engine through CFD modeling. Energy Conversion and Management 2022; 251: 114918.
  • [21] Pehlivan EF. Exergy analysis based on computational fluid dynamics of a two-stroke marine diesel engine. PhD Thesis, Karadeniz Technical University, 2022.
  • [22] Sigurdsson E, Ingvorsen KM, Jensen MV, Mayer S, Matlok S, Walther JH. Numerical analysis of the scavenge flow and convective heat transfer in large two-stroke marine diesel engines. Applied Energy 2014; 123: 37-46.
  • [23] Abani N, Kokjohn S, Park SW, Bergin M, Munnannur A, Ning W, Sun Y, Reitz RD. An improved spray model for reducing numerical bibliomiscmeter dependencies in diesel engine CFD simulations. SAE Technical Paper Series 2008; Paper no: 2008-01-0970.
  • [24] Reitz RD. Modeling atomization processes in high-pressure vaporizing sprays. Atomization and Sprays 1987; 3: 309-337.
  • [25] Yang C, Takamoto Y, Okajima A, Obokata T, Long W. Comparison of computed and measured high-pressure conical diesel sprays. SAE Technical Paper Series 2000; Paper no: 2000-01-0951.
  • [26] Hou S, Schmidt DP. Adaptive collision meshing and satellite droplet formation in spray simulations. International Journal of Multiphase Flow 2006; 32: 935-956.
  • [27] Ra Y, Reitz RD. A vaporization model for discrete multi-component fuel sprays. International Journal of Multiphase Flow 2009; 35: 101-117.
  • [28] ANSYS Inc., ANSYS Forte 2020 R1 Theory Manual.
  • [29] Han Z, Xu Z, Trigui N. Spray/wall interaction models for multidimensional engine simulation. International Journal of Engine Research 2000; 1(1): 127-146.
  • [30] Patel A., King SC., Reitz RD. Development and validation of a reduced reaction mechanism for HCCI engine simulations. SAE Technical Paper Series 2004; Paper no: 2004-01-0558.
  • [31] Liang L, Shelburn A, Wang C, Hodgson D, Meeks E. A New automatic and dynamic mesh generation technique based on immersed boundary method. International Multidimensional Engine Modeling User's Group Meeting, Detroit, Michigan, 2011.
  • [32] Pehlivan EF, Altın, İ. Exergy analysis under consideration of operational parameters by numerical approach in a two-stroke marine diesel engine. Fuel 2024; 368: 131650.
  • [33] Han Z, Reitz RD. Turbulence modeling of internal combustion engines using RNG k-ε models. Combustion Science and Technology 1995; 106: 267-295.
  • [34] Tan Z. Multi-dimensional modeling of ignition and combustion in premixed and DIS/CI (direct injection spark/compression ignition) engines. PhD Thesis, University of Wisconsin-Madison, 2003.
  • [35] ANSYS Inc., ANSYS Chemkin-Pro Theory Manual. 2022, USA.
  • [36] He X, Tan Q, Wu Y, Wei C. Optimization of marine two-stroke diesel engine based on air intake composition and temperature control. Atmosphere 2022; 13(2): 355.
  • [37] Lu D, Theotokatos G, Zhang J, Zeng H, Cui K. Comparative Assessment and Parametric Optimisation of Large Marine Two-Stroke Engines with Exhaust Gas Recirculation and Alternative Turbocharging Systems. Journal of Marine Science and Engineering 2022; 10 (3): 351.
  • [38] He X, Tan Q, Wu Y, Wei C. Optimization of Marine Two-Stroke Diesel Engine Based on Air Intake Composition and Temperature Control. Atmosphere 2022; 13 (2): 355.
  • [39] Ceylan BO. Investigation of seasonal effects on two-stroke marine diesel engine performance parameters and emissions. Journal of Marine Science Applications 2023; 22: 795-808.
  • [40] Nemati A, Ong JC, Jensen MV, Pang KM, Mayer S, Walther JH. Numerical Study of the Scavenging Process in a Large Two-Stroke Marine Engine Using URANS and LES Turbulence Models. SAE Technical Paper Series 2020; Paper no: 2020-01-2012.
There are 40 citations in total.

Details

Primary Language English
Subjects Internal Combustion Engines
Journal Section Research Article
Authors

Enes Fatih Pehlivan 0000-0003-4956-1098

İsmail Altın 0000-0002-7587-9537

Publication Date September 18, 2024
Submission Date April 9, 2024
Acceptance Date August 12, 2024
Published in Issue Year 2024

Cite

APA Pehlivan, E. F., & Altın, İ. (2024). A full-scale CFD model of scavenge air inlet temperature on two-stroke marine diesel engine combustion and exhaust emission characteristics. International Journal of Energy Studies, 9(3), 493-517. https://doi.org/10.58559/ijes.1467215
AMA Pehlivan EF, Altın İ. A full-scale CFD model of scavenge air inlet temperature on two-stroke marine diesel engine combustion and exhaust emission characteristics. Int J Energy Studies. September 2024;9(3):493-517. doi:10.58559/ijes.1467215
Chicago Pehlivan, Enes Fatih, and İsmail Altın. “A Full-Scale CFD Model of Scavenge Air Inlet Temperature on Two-Stroke Marine Diesel Engine Combustion and Exhaust Emission Characteristics”. International Journal of Energy Studies 9, no. 3 (September 2024): 493-517. https://doi.org/10.58559/ijes.1467215.
EndNote Pehlivan EF, Altın İ (September 1, 2024) A full-scale CFD model of scavenge air inlet temperature on two-stroke marine diesel engine combustion and exhaust emission characteristics. International Journal of Energy Studies 9 3 493–517.
IEEE E. F. Pehlivan and İ. Altın, “A full-scale CFD model of scavenge air inlet temperature on two-stroke marine diesel engine combustion and exhaust emission characteristics”, Int J Energy Studies, vol. 9, no. 3, pp. 493–517, 2024, doi: 10.58559/ijes.1467215.
ISNAD Pehlivan, Enes Fatih - Altın, İsmail. “A Full-Scale CFD Model of Scavenge Air Inlet Temperature on Two-Stroke Marine Diesel Engine Combustion and Exhaust Emission Characteristics”. International Journal of Energy Studies 9/3 (September 2024), 493-517. https://doi.org/10.58559/ijes.1467215.
JAMA Pehlivan EF, Altın İ. A full-scale CFD model of scavenge air inlet temperature on two-stroke marine diesel engine combustion and exhaust emission characteristics. Int J Energy Studies. 2024;9:493–517.
MLA Pehlivan, Enes Fatih and İsmail Altın. “A Full-Scale CFD Model of Scavenge Air Inlet Temperature on Two-Stroke Marine Diesel Engine Combustion and Exhaust Emission Characteristics”. International Journal of Energy Studies, vol. 9, no. 3, 2024, pp. 493-17, doi:10.58559/ijes.1467215.
Vancouver Pehlivan EF, Altın İ. A full-scale CFD model of scavenge air inlet temperature on two-stroke marine diesel engine combustion and exhaust emission characteristics. Int J Energy Studies. 2024;9(3):493-517.