Detailed modelling of the internal processes of an injector for common rail systems

• Autorzy: Zöldy M. , Vass S.

Identyfikatory

DOI

10.5604/01.3001.0012.2867

• Języki publikacji: EN

Abstrakty

EN

In the last few decades exhaust emissions of road vehicles have decreased dramatically, owing to the more and more stringent emission standards issued by the legislative bodies of different countries, combined with the necessity of cleaner, better performing vehicles from society side. The introduction of Common Rail (CR) injection systems has been a great step towards achieving this target, thanks to its flexibility in fuel injection pressure, timing, and length, along variable engine load conditions. However, it is highly time and resource consuming to set up the injection system for all operating points of different engines, moreover, as the injection is a small scale, high speed process, the behaviour of the internal processes is challenging to measure. The best solution for these problems is to create a detailed model of the injector, where all the hydraulic, mechanic, and electromagnetic subsystems are represented, this way the internal working conditions can be analysed and resources can be saved. In this work, a detailed model of a first generation CR injector for commercial vehicles is presented and validated against needle lift data. The fluid dynamic and mechanic sub-systems are presented in details to thoroughly investigate the working principles of the injector internal parts. The fluid dynamic subsystem contains the chambers, holes, and throttles of the injector, while the mechanic subsystem models the motion and behaviour of the internal parts. The main features of the injector internal working conditions are described and analysed. Apart from the needle lift, these included solenoid anchor, pin and control piston lifts, the control chamber pressure and the mechanical force acting on the anchor. Five test cases were chosen on a medium duty test engine to represent a wide range of operation points from full load to idle and the simulated results were compared to the measured data. The simulated control piston movement accurately matched the measured curves in every test case.

Słowa kluczowe

EN

common rail; injector; simulation; modelling; internal combustion engines

• Wydawca: Łukasiewicz Research Network - Institute of Aviation ; European Science Society of Powertrain and Transport KONES Poland ; Wydawnictwo Instytutu Technicznego Wojsk Lotniczych
• Czasopismo: Journal of KONES
• Rocznik: 2018
• Tom: Vol. 25, No. 2
• Strony: 416--426
• Opis fizyczny: Bibliogr. 31 poz., rys.

Twórcy

autor

Zöldy M.

• Budapest University of Technology and Economics Department of Automotive Technologies Stoczek Street 6, 1111 Budapest, Hungary tel.:+36 1 4632607, +36 1 4632380

autor

Vass S.

• Budapest University of Technology and Economics Department of Automotive Technologies Stoczek Street 6, 1111 Budapest, Hungary tel.:+36 1 4632607, +36 1 4632380

Bibliografia

• [1] Boehner, W., Hummel, K., Common Rail Injection System for Commercial Diesel Vehicles, SAE Technical Paper Series 970345, 1997.
• [2] Flaig, U., Polach, W., Ziegler, G., Common Rail System (CR-System) for Passenger Car DI Diesel Engines; Experiences with Applications for Series Production Projects, SAE Technical Paper Series 1999-01-0191, 1999.
• [3] Strumpp, G., Ricco, M. Common Rail – An Attractive Fuel Injection System for Passenger Car DI Diesel Engines, SAE Technical Paper Series 960870, 1996.
• [4] Zellbeck, H., Schmidt G., Einspritzsysteme für zukünftige Anforderungen an schnellaufenden Dieselmotor, MTZ 56(11): 648-655, 1995.
• [5] Heywood, J. B. Internal combustion engine fundamentals. McGraw-Hill Publishing, New York 1988.
• [6] Sabau, A., Barhalescu, M., Oanta, E., Modelling of high pressure fuel injection systems, Annals of DAAAM for 2012 & Proceedings of the 23rd International DAAAM Symposium Vol. 23, No. 1, 2011.
• [7] Chiavola, O., Giulanelli, P., Modelling and Simulation of Common rail Systems, SAE Technical Paper Series 2001-01-3183, 2001.
• [8] Lino, P., Maione, B., Rizzo, A., Nonlinear modelling and control of a common rail injection system for diesel engines, Applied Mathematical Modelling 31: 1770-1784., 2007.
• [9] Palamondon, E., Seers, P., Development of a simplified dynamic model for a piezoelectric injector using multiple injection strategies with biodiesel / diesel-fuel blends, Applied Energy 131: 411-424, 2014.
• [10] Brusca, S., Giuffrida, A., Lanzafame, R., Corcione, G. E., Theoretical and experimental analysis of diesel sprays behaviour from multiple injections common rail systems, SAE Technical Paper Series 2002-01-2777, 2002.
• [11] Catalano, L. A., Tondolo, V. A., Dadone, A., Dynamic rise of pressure in the common rail fuel injection system, SAE Technical Paper Series 2002-01-0210, 2002.
• [12] Digesu, P., Ficarella, A., Laforgia, D., Bruni, G., Ricco, M., Diesel Electro-Injector: A Numerical Simulation Code, SAE Technical Paper Series 940193, 1994.
• [13] Huhtala, K., Vilenius, M., Study of a common rail fuel injection system, SAE Technical Paper Series 2001-01-3184, 2001.
• [14] Mulemane, A., Han, J-S., Lu P-H., Yoon, S-J., Lai, M-Ch., Modelling Dynamic Behavior of Diesel Fuel Injection Systems, SAE Technical Paper Series 2004-01-0536, 2004.
• [15] Payri, R., Climent, H., Salvador, F. J., Favennec, A. G., Diesel injection system modelling. methodology and application for a first-generation common rail system, Proceedings of the Institution of Mechanical Engineering Vol. 218, Part D, 2004.
• [16] Bereczky A, Lukács K., Development of Dual fuel engine and modelling of it with AVL Boost software system In: Stanislaw Szwaja (szerk.) Technologia uprawy mikroglonów w bioreaktorach zamkniętych z recyklingiem CO2 i innych odpadów z biogazowni. Konferencia helye, ideje: Kroczyce, Lengyelország, Instytut Maszyn Cieplnych Polit. Czestochowska, pp. 11-16, Czestochowa 2015.
• [17] Bianchi, G. M., Falfari, S., Pelloni P., Filicori, F., Milani, M. A Numerical and Experimental Study on the Possible Improvements of C.R. Injectors, SAE Technical Paper Series 2002-01-0500, 2002.
• [18] Bianchi, G. M., Falfari, S., Pelloni P., Song-Charng Kong, Reitz, R.D., Numerical Analysis of High Pressure Fast-Response C.R. Injector Dynamics, SAE Technical Paper Series 2002-01-0213, 2002.
• [19] Bianchi, G. M., Falfari, S., Parotto, M., Osbat, G., Advanced Modelling of Common Rail Injector Dinamics and Comparison with Experiments, SAE Technical Paper Series 2003-01-0006, 2003.
• [20] Amiola, V., Ficarella, A., Laforgia, D., De Matthaeis, S., Genco, C., A theoretical code to simulate the behaviour of an electro-injector for diesel engines and parametric analysis, SAE Technical Paper Series 970349, 1997.
• [21] Ficarella, A., Laforgia, D., Landriscina, V., Evaluation of instability phenomena in a common rail injection system for high speed diesel engines, SAE Technical Paper Series 1999-01-0192, 1999.
• [22] Dongiovanni, C., Coppo, M., Accurate Modelling of an Injector for Common Rail Systems, Fuel Injection, InTech, ISBN: 978-953-307-116-9, 2010.
• [23] Von Kunsberg Sarre, C., Kong, S-C., Reitz, R. D., Modelling the Effects of Injector Nozzle Geometry on Diesel Sprays, SAE Technical Paper Series 1999-01-0912, 1999.
• [24] Kolade, B., Boghosian, M. E., Reddy, P. S., Gallagher, S., Development of a General Purpose Thermal- Hydraulic Software and its Application to Fuel Injection Systems, SAE Technical Paper Series 2003-01-0702, 2003.
• [25] Kolade, B., Morel, T., Kong, S-C. Coupled 1-D/3-D Analysis of Fuel Injection and Diesel Engine Combustion, SAE Technical Paper Series 2004-01-0928, 2004.
• [26] Vass, S., Németh, H. Sensitivity analysis of instantaneous fuel injection rate determination for detailed Diesel combustion models, Periodica Polytechnica, Transportation Engineering 41(1): 77-85, 2013.
• [27] GT-Suite 7.3.0 User’s Manual, Gamma Technologies Inc., 2012.
• [28] Vass, S., Németh, H., Detailed electromagnetic model of a Common Rail injector, 34th International Colloquium on Advenced Manufacturing and Repairing Technologies in Vehicle Industry, Visegrád, Hungary, pp. 165-168, 2017.
• [29] Kolade, B., Boghosian, M. E., Reddy, P.S., Gallagher, S., Development of a General Purpose Thermal – Hydraulic Software and its Application to Fuel Injection Systems, SAE Technical Paper Series 2003-01-0702, 2003.
• [30] Miller, D. S., Internal Flow Systems, BHRA Fluid Engineering, Bedford 1990.
• [31] Bárdos, Á., Vass, S., Németh, H., Validation of a detailed commercial vehicle turbocharged diesel engine model, A Jövő Járműve 1-2/2014: 25-31, 2014.

Uwagi

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018).