- -

Thermal effects on the diesel injector performance through adiabatic 1D modelling. Part I: Model description and assessment of the adiabatic flow hypothesis

RiuNet: Repositorio Institucional de la Universidad Politécnica de Valencia

Compartir/Enviar a

Citas

Estadísticas

  • Estadisticas de Uso

Thermal effects on the diesel injector performance through adiabatic 1D modelling. Part I: Model description and assessment of the adiabatic flow hypothesis

Mostrar el registro sencillo del ítem

Ficheros en el ítem

Thumbnail
Nombre: Salvador;Gmeno;Martín ...
Tamaño: 1.677Mb
Formato: PDF
Descripción: Versión del Autor.
Abrir
[Cerrado]
Nombre: Salvador2020_Ther ...
Tamaño: 1.301Mb
Formato: PDF
Descripción: Versión editorial
Solicitar una copia al autor
dc.contributor.author Salvador, Francisco Javier es_ES
dc.contributor.author Gimeno, Jaime es_ES
dc.contributor.author Martín, Jaime es_ES
dc.contributor.author Carreres, Marcos es_ES
dc.date.accessioned 2021-06-23T03:30:39Z
dc.date.available 2021-06-23T03:30:39Z
dc.date.issued 2020-01-15 es_ES
dc.identifier.issn 0016-2361 es_ES
dc.identifier.uri http://hdl.handle.net/10251/168336
dc.description.abstract [EN] The fuel flow along common-rail injectors is usually treated as isothermal, although the expansions across the injector orifices lead to variations in the fuel temperature that in turn modify the fuel properties influencing injector dynamics. This investigation introduces the hypothesis of adiabatic flow to account for local temperature variations in the computational model of a solenoid injector previously introduced by the authors in its isothermal variant. The main contribution of the study consists on the assessment of the validity of this hypothesis by qualitatively estimating the relative importance of the heat transfer processes during the injection event and in the time lapse among injections. Results of this tentative assessment for engine-like conditions imply that heat transfer is usually still occurring by the time of a new injection, meaning any initial temperature difference among the fuel and the injector wall is not expected to be completely mitigated before each injection event. The magnitude of reduction of this temperature difference depends on the injection frequency through engine speed and load. Anyway, the assumption of adiabatic flow seems to hold once the steady conditions of the injection are reached, meaning that any temperature change predictions considered with the adiabatic hypothesis may be valid as long as a certain temperature change is accounted for at the injector inlet. In a second part of the paper, the capabilities of this new model are validated against experimental data, allowing the use of the model to explore the influence of the thermal effects on the injection event. es_ES
dc.description.sponsorship This work was partly sponsored by FEDER and the Spanish "Ministerio de Economia y Competitividad" in the frame of the project "Desarrollo de modelos de combustion y emisiones HPC para el analisis de plantas propulsivas de transporte sostenible (CHEST)", reference TRA2017-89139-C2-1-R-AR. The support of General Motors Global Research and Development (US) concerning the experimental measurements in the engine is gratefully acknowledged by the authors. The authors would also like to thank Jose Enrique del Rey, Leo Thiercelin and Mariano Sanchez for their technical help. es_ES
dc.language Inglés es_ES
dc.publisher Elsevier es_ES
dc.relation.ispartof Fuel es_ES
dc.rights Reconocimiento - No comercial - Sin obra derivada (by-nc-nd) es_ES
dc.subject Diesel es_ES
dc.subject Injection es_ES
dc.subject Computational es_ES
dc.subject 1D modelling es_ES
dc.subject Fuel temperature es_ES
dc.subject Adiabatic flow es_ES
dc.subject.classification INGENIERIA AEROESPACIAL es_ES
dc.subject.classification MAQUINAS Y MOTORES TERMICOS es_ES
dc.title Thermal effects on the diesel injector performance through adiabatic 1D modelling. Part I: Model description and assessment of the adiabatic flow hypothesis es_ES
dc.type Artículo es_ES
dc.identifier.doi 10.1016/j.fuel.2019.116348 es_ES
dc.relation.projectID info:eu-repo/grantAgreement/AEI/Plan Estatal de Investigación Científica y Técnica y de Innovación 2013-2016/TRA2017-89139-C2-1-R/ES/DESARROLLO DE MODELOS DE COMBUSTION Y EMISIONES HPC PARA EL ANALISIS DE PLANTAS PROPULSIVAS DE TRANSPORTE SOSTENIBLES/ es_ES
dc.rights.accessRights Abierto es_ES
dc.contributor.affiliation Universitat Politècnica de València. Departamento de Máquinas y Motores Térmicos - Departament de Màquines i Motors Tèrmics es_ES
dc.description.bibliographicCitation Salvador, FJ.; Gimeno, J.; Martín, J.; Carreres, M. (2020). Thermal effects on the diesel injector performance through adiabatic 1D modelling. Part I: Model description and assessment of the adiabatic flow hypothesis. Fuel. 260:1-13. https://doi.org/10.1016/j.fuel.2019.116348 es_ES
dc.description.accrualMethod S es_ES
dc.relation.publisherversion https://doi.org/10.1016/j.fuel.2019.116348 es_ES
dc.description.upvformatpinicio 1 es_ES
dc.description.upvformatpfin 13 es_ES
dc.type.version info:eu-repo/semantics/publishedVersion es_ES
dc.description.volume 260 es_ES
dc.relation.pasarela S\395863 es_ES
dc.contributor.funder Agencia Estatal de Investigación es_ES
dc.contributor.funder European Regional Development Fund es_ES
dc.description.references Heywood JB. Internal Combustion Engine Fundamentals. vol. 21. 1988. es_ES
dc.description.references Payri, R., Salvador, F. J., Gimeno, J., & De la Morena, J. (2011). Influence of injector technology on injection and combustion development – Part 1: Hydraulic characterization. Applied Energy, 88(4), 1068-1074. doi:10.1016/j.apenergy.2010.10.012 es_ES
dc.description.references Payri, R., Salvador, F. J., Gimeno, J., & De la Morena, J. (2011). Influence of injector technology on injection and combustion development – Part 2: Combustion analysis. Applied Energy, 88(4), 1130-1139. doi:10.1016/j.apenergy.2010.10.004 es_ES
dc.description.references Gavaises, M. (2008). Flow in valve covered orifice nozzles with cylindrical and tapered holes and link to cavitation erosion and engine exhaust emissions. International Journal of Engine Research, 9(6), 435-447. doi:10.1243/14680874jer01708 es_ES
dc.description.references Som, S., Ramirez, A. I., Longman, D. E., & Aggarwal, S. K. (2011). Effect of nozzle orifice geometry on spray, combustion, and emission characteristics under diesel engine conditions. Fuel, 90(3), 1267-1276. doi:10.1016/j.fuel.2010.10.048 es_ES
dc.description.references Salvador, F. J., Carreres, M., Jaramillo, D., & Martínez-López, J. (2015). Analysis of the combined effect of hydrogrinding process and inclination angle on hydraulic performance of diesel injection nozzles. Energy Conversion and Management, 105, 1352-1365. doi:10.1016/j.enconman.2015.08.035 es_ES
dc.description.references Nguyen, D., Duke, D., Kastengren, A., Matusik, K., Swantek, A., Powell, C. F., & Honnery, D. (2017). Spray flow structure from twin-hole diesel injector nozzles. Experimental Thermal and Fluid Science, 86, 235-247. doi:10.1016/j.expthermflusci.2017.04.020 es_ES
dc.description.references Salvador, F. J., de la Morena, J., Carreres, M., & Jaramillo, D. (2017). Numerical analysis of flow characteristics in diesel injector nozzles with convergent-divergent orifices. Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, 231(14), 1935-1944. doi:10.1177/0954407017692220 es_ES
dc.description.references Lee, C. S., Lee, K. H., Reitz, R. D., & Park, S. W. (2006). EFFECT OF SPLIT INJECTION ON THE MACROSCOPIC DEVELOPMENT AND ATOMIZATION CHARACTERISTICS OF A DIESEL SPRAY INJECTED THROUGH A COMMON-RAIL SYSTEM. Atomization and Sprays, 16(5), 543-562. doi:10.1615/atomizspr.v16.i5.50 es_ES
dc.description.references Wang, X., Huang, Z., Zhang, W., Kuti, O. A., & Nishida, K. (2011). Effects of ultra-high injection pressure and micro-hole nozzle on flame structure and soot formation of impinging diesel spray. Applied Energy, 88(5), 1620-1628. doi:10.1016/j.apenergy.2010.11.035 es_ES
dc.description.references Gumus, M., Sayin, C., & Canakci, M. (2012). The impact of fuel injection pressure on the exhaust emissions of a direct injection diesel engine fueled with biodiesel–diesel fuel blends. Fuel, 95, 486-494. doi:10.1016/j.fuel.2011.11.020 es_ES
dc.description.references Bianchi GM, Falfari S, Pelloni P, Kong S-C, Reitz RD. Numerical Analysis of High-Pressure Fast-Response Common Rail Injector Dynamics. SAE Tech Pap 2002-01-0213 2002. doi:10.4271/2002-01-0213. es_ES
dc.description.references Marcer R, Audiffren C, Viel A, Bouvier B, Walbott A, Argueyrolles B. Coupling 1D System AMESim and 3D CFD EOLE models for Diesel Injection Simulation Renault. ILASS - Eur. 2010, 23rd Annu. Conf. Liq. At. Spray Syst., 2010, p. 1–10. es_ES
dc.description.references Plamondon, E., & Seers, P. (2014). Development of a simplified dynamic model for a piezoelectric injector using multiple injection strategies with biodiesel/diesel-fuel blends. Applied Energy, 131, 411-424. doi:10.1016/j.apenergy.2014.06.039 es_ES
dc.description.references Salvador, F. J., Gimeno, J., De la Morena, J., & Carreres, M. (2012). Using one-dimensional modeling to analyze the influence of the use of biodiesels on the dynamic behavior of solenoid-operated injectors in common rail systems: Results of the simulations and discussion. Energy Conversion and Management, 54(1), 122-132. doi:10.1016/j.enconman.2011.10.007 es_ES
dc.description.references Salvador, F. J., Plazas, A. H., Gimeno, J., & Carreres, M. (2012). Complete modelling of a piezo actuator last-generation injector for diesel injection systems. International Journal of Engine Research, 15(1), 3-19. doi:10.1177/1468087412455373 es_ES
dc.description.references Payri, R., Salvador, F. J., Carreres, M., & De la Morena, J. (2016). Fuel temperature influence on the performance of a last generation common-rail diesel ballistic injector. Part II: 1D model development, validation and analysis. Energy Conversion and Management, 114, 376-391. doi:10.1016/j.enconman.2016.02.043 es_ES
dc.description.references Wang, X., Huang, Z., Kuti, O. A., Zhang, W., & Nishida, K. (2010). Experimental and analytical study on biodiesel and diesel spray characteristics under ultra-high injection pressure. International Journal of Heat and Fluid Flow, 31(4), 659-666. doi:10.1016/j.ijheatfluidflow.2010.03.006 es_ES
dc.description.references Theodorakakos, A., Strotos, G., Mitroglou, N., Atkin, C., & Gavaises, M. (2014). Friction-induced heating in nozzle hole micro-channels under extreme fuel pressurisation. Fuel, 123, 143-150. doi:10.1016/j.fuel.2014.01.050 es_ES
dc.description.references Strotos, G., Koukouvinis, P., Theodorakakos, A., Gavaises, M., & Bergeles, G. (2015). Transient heating effects in high pressure Diesel injector nozzles. International Journal of Heat and Fluid Flow, 51, 257-267. doi:10.1016/j.ijheatfluidflow.2014.10.010 es_ES
dc.description.references Salvador, F. J., Carreres, M., De la Morena, J., & Martínez-Miracle, E. (2018). Computational assessment of temperature variations through calibrated orifices subjected to high pressure drops: Application to diesel injection nozzles. Energy Conversion and Management, 171, 438-451. doi:10.1016/j.enconman.2018.05.102 es_ES
dc.description.references Desantes, J., Salvador, F., Carreres, M., & Jaramillo, D. (2015). Experimental Characterization of the Thermodynamic Properties of Diesel Fuels Over a Wide Range of Pressures and Temperatures. SAE International Journal of Fuels and Lubricants, 8(1), 190-199. doi:10.4271/2015-01-0951 es_ES
dc.description.references Dernotte, J., Hespel, C., Foucher, F., Houillé, S., & Mounaïm-Rousselle, C. (2012). Influence of physical fuel properties on the injection rate in a Diesel injector. Fuel, 96, 153-160. doi:10.1016/j.fuel.2011.11.073 es_ES
dc.description.references Park, Y., Hwang, J., Bae, C., Kim, K., Lee, J., & Pyo, S. (2015). Effects of diesel fuel temperature on fuel flow and spray characteristics. Fuel, 162, 1-7. doi:10.1016/j.fuel.2015.09.008 es_ES
dc.description.references Seykens X, Somers LMT, Baert RSG. Modelling of common rail fuel injection system and influence of fluid properties on process. Proc. VAFSEP, Dublin, Ireland; July 6-9, 2004, p. 6–9. es_ES
dc.description.references Catania, A. E., Ferrari, A., & Spessa, E. (2008). Temperature variations in the simulation of high-pressure injection-system transient flows under cavitation. International Journal of Heat and Mass Transfer, 51(7-8), 2090-2107. doi:10.1016/j.ijheatmasstransfer.2007.11.032 es_ES
dc.description.references Yu, H., Goldsworthy, L., Brandner, P. A., Li, J., & Garaniya, V. (2018). Modelling thermal effects in cavitating high-pressure diesel sprays using an improved compressible multiphase approach. Fuel, 222, 125-145. doi:10.1016/j.fuel.2018.02.104 es_ES
dc.description.references Salvador, F. J., Gimeno, J., Carreres, M., & Crialesi-Esposito, M. (2017). Experimental assessment of the fuel heating and the validity of the assumption of adiabatic flow through the internal orifices of a diesel injector. Fuel, 188, 442-451. doi:10.1016/j.fuel.2016.10.061 es_ES
dc.description.references Salvador, F. J., Gimeno, J., De la Morena, J., & Carreres, M. (2018). Comparison of Different Techniques for Characterizing the Diesel Injector Internal Dimensions. Experimental Techniques, 42(5), 467-472. doi:10.1007/s40799-018-0246-1 es_ES
dc.description.references Desantes, J. M., López, J. J., Carreres, M., & López-Pintor, D. (2016). Characterization and prediction of the discharge coefficient of non-cavitating diesel injection nozzles. Fuel, 184, 371-381. doi:10.1016/j.fuel.2016.07.026 es_ES
dc.description.references Leonhard, R., Warga, J., Pauer, T., Rückle, M., & Schnell, M. (2010). Solenoid common-rail injector for 1800 bar. MTZ worldwide, 71(2), 10-15. doi:10.1007/bf03227003 es_ES
dc.description.references PAYRI, R., GARCIA, J., SALVADOR, F., & GIMENO, J. (2005). Using spray momentum flux measurements to understand the influence of diesel nozzle geometry on spray characteristics. Fuel, 84(5), 551-561. doi:10.1016/j.fuel.2004.10.009 es_ES
dc.description.references Siebers DL. Scaling liquid-phase fuel penetration in diesel sprays based on mixing-limited vaporization. SAE Tech Pap 1999-01-0528 1999. doi:10.4271/1999-01-0528. es_ES
dc.description.references Desantes, J. M., Salvador, F. J., Carreres, M., & Martínez-López, J. (2014). Large-eddy simulation analysis of the influence of the needle lift on the cavitation in diesel injector nozzles. Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, 229(4), 407-423. doi:10.1177/0954407014542627 es_ES
dc.description.references Salvador, F. J., Gimeno, J., Carreres, M., & Crialesi-Esposito, M. (2016). Fuel temperature influence on the performance of a last generation common-rail diesel ballistic injector. Part I: Experimental mass flow rate measurements and discussion. Energy Conversion and Management, 114, 364-375. doi:10.1016/j.enconman.2016.02.042 es_ES
dc.description.references Chorążewski, M., Dergal, F., Sawaya, T., Mokbel, I., Grolier, J.-P. E., & Jose, J. (2013). Thermophysical properties of Normafluid (ISO 4113) over wide pressure and temperature ranges. Fuel, 105, 440-450. doi:10.1016/j.fuel.2012.05.059 es_ES
dc.description.references Huang, D., Simon, S. L., & McKenna, G. B. (2005). Chain length dependence of the thermodynamic properties of linear and cyclic alkanes and polymers. The Journal of Chemical Physics, 122(8), 084907. doi:10.1063/1.1852453 es_ES
dc.description.references Bell, I. H., Wronski, J., Quoilin, S., & Lemort, V. (2014). Pure and Pseudo-pure Fluid Thermophysical Property Evaluation and the Open-Source Thermophysical Property Library CoolProp. Industrial & Engineering Chemistry Research, 53(6), 2498-2508. doi:10.1021/ie4033999 es_ES
dc.description.references Růžička, V., & Domalski, E. S. (1993). Estimation of the Heat Capacities of Organic Liquids as a Function of Temperature using Group Additivity. I. Hydrocarbon Compounds. Journal of Physical and Chemical Reference Data, 22(3), 597-618. doi:10.1063/1.555923 es_ES
dc.description.references Zábranský, M., Kolská, Z., Růžička, V., & Domalski, E. S. (2010). Heat Capacity of Liquids: Critical Review and Recommended Values. Supplement II. Journal of Physical and Chemical Reference Data, 39(1), 013103. doi:10.1063/1.3182831 es_ES
dc.description.references Winklhofer, E., Ahmadi-Befrui, B., Wiesler, B., & Cresnoverh, G. (1992). The Influence of Injection Rate Shaping on Diesel Fuel Sprays—An Experimental Study. Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, 206(3), 173-183. doi:10.1243/pime_proc_1992_206_176_02 es_ES
dc.description.references Nishimura T, Satoh K, Takahashi S, Yokota K. Effects of Fuel Injection Rate on Combustion and Emission in a DI Diesel Engine. SAE Tech. Pap. 981929, 1998. doi:10.4271/981929. es_ES
dc.description.references Benajes, J., Molina, S., De Rudder, K., & Rente, T. (2006). Influence of injection rate shaping on combustion and emissions for a medium duty diesel engine. Journal of Mechanical Science and Technology, 20(9), 1436-1448. doi:10.1007/bf02915967 es_ES
dc.description.references He, Z., Xuan, T., Xue, Y., Wang, Q., & Zhang, L. (2014). A numerical study of the effects of injection rate shape on combustion and emission of diesel engines. Thermal Science, 18(1), 67-78. doi:10.2298/tsci130810013h es_ES
dc.description.references Payri, F., Payri, R., Bardi, M., & Carreres, M. (2014). Engine combustion network: Influence of the gas properties on the spray penetration and spreading angle. Experimental Thermal and Fluid Science, 53, 236-243. doi:10.1016/j.expthermflusci.2013.12.014 es_ES
dc.description.references Sieder, E. N., & Tate, G. E. (1936). Heat Transfer and Pressure Drop of Liquids in Tubes. Industrial & Engineering Chemistry, 28(12), 1429-1435. doi:10.1021/ie50324a027 es_ES
dc.description.references Salvador, F. J., Carreres, M., Crialesi-Esposito, M., & Plazas, A. H. (2017). Determination of critical operating and geometrical parameters in diesel injectors through one dimensional modelling, design of experiments and an analysis of variance. Proceedings of the Institution of Mechanical Engineers, Part D: Journal of Automobile Engineering, 232(13), 1762-1781. doi:10.1177/0954407017735262 es_ES
dc.description.references Matsumoto S, Yamada K, Date K. Concepts and Evolution of Injector for Common Rail System. SAE Tech Pap 2012-01-1753 2012. doi:10.4271/2012-01-1753. es_ES
dc.description.references Schöppe, D., Zülch, S., Hardy, M., Geurts, D., Jorach, R. W., & Baker, N. (2008). Delphi Common Rail system with direct acting injector. MTZ worldwide, 69(10), 32-38. doi:10.1007/bf03226918 es_ES
dc.description.references Benajes, J., Olmeda, P., Martín, J., Blanco-Cavero, D., & Warey, A. (2017). Evaluation of swirl effect on the Global Energy Balance of a HSDI Diesel engine. Energy, 122, 168-181. doi:10.1016/j.energy.2017.01.082 es_ES
dc.description.references Broatch, A., Olmeda, P., García, A., Salvador-Iborra, J., & Warey, A. (2017). Impact of swirl on in-cylinder heat transfer in a light-duty diesel engine. Energy, 119, 1010-1023. doi:10.1016/j.energy.2016.11.040 es_ES
dc.description.references Bardi, M., Payri, R., Malbec, L. M., Bruneaux, G., Pickett, L. M., Manin, J., … Genzale, C. (2012). ENGINE COMBUSTION NETWORK: COMPARISON OF SPRAY DEVELOPMENT, VAPORIZATION, AND COMBUSTION IN DIFFERENT COMBUSTION VESSELS. Atomization and Sprays, 22(10), 807-842. doi:10.1615/atomizspr.2013005837 es_ES
dc.description.references Gimeno, J., Martí-Aldaraví, P., Carreres, M., & Peraza, J. E. (2018). Effect of the nozzle holder on injected fuel temperature for experimental test rigs and its influence on diesel sprays. International Journal of Engine Research, 19(3), 374-389. doi:10.1177/1468087417751531 es_ES
dc.description.references ECN. Engine Combustion Network. Https://EcnSandiaGov/Diesel-Spray-Combustion/ 2010. www.sandia.gov/ecn/. es_ES


Este ítem aparece en la(s) siguiente(s) colección(ones)

Mostrar el registro sencillo del ítem