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THERMAL SCIENCE
International Scientific Journal
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VOLUME OF FLUID ANALYSIS USING LARGE EDDY SIMULATION ON STANDARD ENGINE COMBUSTION NETWORK INJECTORS
ABSTRACT
Accurate prediction of fuel injection and jet formation under diesel-like conditions requires understanding the coupled thermo-fluid processes inside injector nozzles, including pressure-driven acceleration, viscous losses, cavitation, interfacial dynamics, and convective heat transfer. This study numerically investigates these processes for an oxygenated fuel (OME₃) and a conventional diesel surrogate (n-dodecane) using large-eddy simulations with a Volume-of-Fluid approach and real nozzle geometries from standard ECN Spray A, C, and D injectors. OME₃ exhibits higher liquid density than n-dodecane, resulting in lower exit velocity but greater mass flow and denser near-nozzle jets. The divergent Spray C nozzle promotes inlet separation and cavitation, reducing discharge coefficient and jet core density, whereas convergent nozzles (Spray A and D) yield fuller, attached flows and higher discharge efficiency. Despite geometric differences, both fuels show similar internal pressure distributions, indicating that nozzle design dominates over fuel properties in determining internal hydraulics. From a thermal perspective, OME₃ reaches slightly higher liquid temperatures due to weaker turbulent heat transfer and enhanced viscous heating. Overall, the simulations reveal the combined influence of fuel density, viscosity, and nozzle geometry on discharge characteristics, jet structure, and thermal state, offering physics-based insights for optimizing injector and fuel design in clean, high-efficiency diesel combustion systems.
KEYWORDS
Combustion Network, CFD, Spray A, Spray C, Spray D, projected density, rate of flow, n-dodecane OME₃
PAPER SUBMITTED: 2025-05-16
PAPER REVISED: 2025-10-24
PAPER ACCEPTED: 2025-11-25
PUBLISHED ONLINE: 2026-05-17
DOI REFERENCE: https://doi.org/10.2298/TSCI250516046A
REFERENCES
[1] Dec, J., A Conceptual Model of DI Diesel Combustion Based on Laser-Sheet Imaging, SAE transactions, 106 (1997), pp. 1319-1348
[2] Walther, S., Li, T., Geyer, D., Dreizler, A., Böhm, B., Soot and Flame Structures in Turbulent Partially Premixed Jet Flames of Pre-Evaporated Diesel Surrogates with Admixture of OMEn, Fluids, 9 (2024), 210
[3] Lautenschütz, L., Oestreich, D., Seidenspinner, P., Arnold, U., Dinjus, E., Sauer, J., Physico-chemical properties and fuel characteristics of oxymethylene dialkyl ethers, Fuel, 209 (2017), pp. 812-812
[4] Virt, M., Zöldy, M., Enhancing the Viability of a Promising E-Fuel: Oxymethylene Ether-Decanol Mixtures, Energies, 17 (2024), 1348
[5] Wiesmann, F., Strauß, L., Rieß, S., Manin, J., Wan, K., Lauer, T., Numerical and Experimental Investigations on the Ignition Behavior of OME, Energies, 15 (2022), 6855
[6] Dworschak, P., Berger, V., Härtl, M., Wachtmeister, G., Neat Oxymethylene Ethers: Combustion Performance and Emissions of OME 2 , OME 3 , OME 4 and OME 5 in a Single-Cylinder Diesel Engine, SAE Technical Paper 2020-01-0805, 2020
[7] Ouda, M., Yarce, G., White, R. J., Hadrich, M., Himmel, D., Schaadt, A., Klein, H., Jacob, E., Krossingc, I., Poly(oxymethylene) dimethyl ether synthesis - a combined chemical equilibrium investigation towards an increasingly efficient and potentially sustainable synthetic route, Reaction Chemistry & Engineering, 2 (2017), 1, pp. 50-59
[8] Rodríguez-Vallejo, D. F., Valente, A., Guillén-Gosálbez, G., Chachuat, B., Economic and life-cycle assessment of OME3-5 as transport fuel: a comparison of production pathways, Sustainable Energy & Fuels, 5 (2021), 9, pp. 2504-2516
[9] Pastor, J., Garcia-Oliver, J., Micó, C., Tejada, F., Comparison of the Diffusive Flame Structure for Dodecane and OME X Fuels for Conditions of Spray A of the ECN, SAE International Journal of Advances and Current Practices in Mobility, 3 (2021), 1, pp. 402-411
[10] Haspel, P., Gierth, S., Popp, S., Scholtissek, A., Rieß, S., Wensing, M., Hasse, C., Large eddy simulation of OME3 and OME4 spray combustion under heavy-duty conditions, Fuel, 353 (2023), 129097
[11] Wiesmann, F., Nguyen, T. M., Manin, J., Pickett, L. M., Wan, K., Tagliante, F., Lauer, T., LES and RANS Spray Combustion Analysis of OME3-5 and n-Dodecane, Energies, 17 (2024), 2265
[12] ***, ECN Diesel Spray Combustion: Target Condition Spray A/B, https://ecn.sandia.gov/diesel-spray-combustion/target-condition/spray-ab/
[13] Du, C., Andersson, M., Andersson, S., Effects of Nozzle Geometry on the Characteristics of an Evaporating Diesel Spray, SAE International Journal of Fuels and Lubricants, 9 (2016), 3, pp. 493-513
[14] Pastor, J. V., García-Oliver, J. M., Micó, C., García-Carrero, A. A., An experimental study with renewable fuels using ECN Spray A and D nozzles, International Journal of Engine Research, 23 (2022), 10, pp. 1748-1759
[15] Yang, S., Yi, P., Habchi, C., Real-fluid injection modeling and LES simulation of the ECN Spray A injector using a fully compressible two-phase flow approach, International Journal of Multiphase Flow, 122 (2020), 103145
[16] Chung, W. T., Ma, P. C., Ihme, M., Examination of diesel spray combustion in supercritical ambient fluid using large-eddy simulations, International Journal of Engine Research, 21 (2020), 1, pp. 122-133
[17] Holzer, A., Günthner, M., Jung, P., Performance of pure OME and various HVO-OME fuel blends as alternative fuels for a diesel engine, Automot. Engine Technol., 7 (2022), pp. 369-383
[18] Singh, S., Ailaboina, A., Battistoni, M., Danish, M., Saha, K., Numerical Investigation of Cavitation Behavior for Dodecane and OME3 Fuel in ECN Spray C Injector Nozzle, Proceedings of the 1st International Conference on Fluid, Thermal and Energy Systems (ICFTES 2022), Lecture Notes in Mechanical Engineering, Springer, Singapore, 2024
[19] ***, Engine Combustion Network, https://ecn.sandia.gov/
[20] Powell, C., Ciatti, S., Cheong, S., Liu, J., X-Ray absorption measurements of diesel sprays and the effects of nozzle geometry, SAE Technical Paper 2004-01-2011, 2004
[21] Kastengren, A., Powell, C., Liu, Z., Wang, J., Time Resolved, Three Dimensional Mass Distribution of Diesel Sprays Measured with X-Ray Radiography, SAE Technical Paper 2009-01-0840, 2009
[22] Malbec, L., Egúsquiza, J., Bruneaux, G., Meijer, M., Characterization of a Set of ECN Spray A Injectors: Nozzle to Nozzle Variations and Effect on Spray Characteristics, SAE International Journal of Engines, 6 (2013), 3, pp. 1642-1660
[23] Payri, R., Gimeno, J., Cuisano, J., Arco, J., Hydraulic characterization of diesel engine single-hole injectors, Fuel, 180 (2016), pp. 357-366
[24] Allehaibi, M., Liu, X., Aljabri, H., Ben Houidi, M., Investigation of the Engine Combustion Network Spray C Characteristics at High Temperature and High-Pressure Conditions Using Eulerian Model, SAE Technical Paper 2021-24-0056, 2021
[25] Yue, Z., Battistoni, M., Som, S., Spray characterization for engine combustion network Spray G injector using high-fidelity simulation with detailed injector geometry, International Journal of Engine Research, 21 (2020), 1, pp. 226-238
[26] Richards, K., Senecal, P., Pomraning, E., CONVERGE (v3.0), Convergent Science, Madison, WI, USA, 2021
[27] Waclawczyk, T., Koronowicz, T., Modeling of the Wave Breaking with CICSAM and HRIC High-Resolution Scheme, Proceedings of ECCOMAS CFD, Egmond an Zee, The Netherlands, 2006
[28] Yasutomi, K., Hwang, J., Manin, J., Pickett, L., Diesel injector elasticity effects on internal nozzle flow, SAE Technical Paper 2019-01-2284, 2019
[29] Abers, P., Cenker, E., Yasutomi, K., Hwang, J., Effect of pressure cycling on gas exchange in a transparent fuel injector, SAE Technical Paper 2019-01-2280, 2019
[30] Allehaibi, M., Liu, X., Aljabri, H., Ben Houidi, M., Mohan, H., Im, H., Investigation of the Engine Combustion Network Spray C Characteristics at High Temperature and High-Pressure Conditions Using Eulerian Model, SAE Technical Paper 2021-24-0056, 2021
[31] Sforzo, B. A., Fuel nozzle geometry effects on cavitation and spray behavior at diesel engine conditions, Report No. (SNL-NM), Sandia National Lab., Albuquerque, NM, USA, 2018
© 2026 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, National Institute of the Republic of Serbia, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence