Fuel spray modelling in direct-injection diesel and gasoline engines

Tonini, Simona

January 2006

Computational fluid dynamics methodologies have been achieving in the last decades remarkable progresses in predicting the complex physical process in internal combustion engines, which need to be continuously optimised to get the best compromise between fuel economy, emissions and power output/drivability. Among the variety of computational tools developed by researchers to investigate the multi-Phase flow development from high-pressure fuel injection systems for modem diesel and gasoline direct injection engines, the Eulerian-Lagrangian stochastic methodology, which models the air/vapour mixture as continuous phase and the liquid droplets as the dispersed one, has become standard among the developers of commercial or in-house university CFD codes due to its intuitive assumptions and simple implementation. It is generally recognised that this method is specifically suitable for dilute sprays, but it has shortcomings with respect to modelling of the dense sprays present in the crucial region close to the nozzle exit of fuel injection systems. Moreover, the mathematical formulation of the Eulerian-Lagrangian models is intrinsically related to critical numerical issues, like the difficulty of correctly estimating the initial conditions at the nozzle hole exit required by spray modelling calculations and, furthermore, the dependency of the results on the spatial and temporal discretisation schemes used to solve the governing flow equations. To overcome some of these difficulties, a modified Lagrangian methodology has been developed in this study. The interaction between the Eulerian and the Lagrangian phases is not treated on the cell-to-parcel basis, but using spatial distribution functions, which allow for distribution of the spray source terms on a number of cells located within a distance from the droplet centre. The end result is a numerical methodology which can handle numerical grids irrespective of the volume of the Lagrangian phase introduced. These improvements have been found to offer significant advances on Lagrangian spray calculations without the need to switch to Eulerian models in the near nozzle region. Besides these fundamental numerical issues, the present study offers some new insights on the physical processes involved in evaporating sprays under a wide range of operating conditions typical of advanced diesel and gasoline direct injection engines. Attention hag been directed on the topic of liquid droplet vaporisation modelling, which has been addressed by implementing and discussing different models published in the literature. Topics of particular emphasis include phase equilibrium, quasi-steadiness assumption, fuel composition, physical properties correlation, droplet shape and energy and mass transfer in the liquid and gas phases. The models have been implemented and validated against an extensive data base of experimental results for single and multi-component droplets vaporising under suband super-critical surrounding conditions and then implemented in the in-house GFS code, the multi-phase CFD solver developed within the research group over the last decade. A variety of physical sub-models have been assessed against comprehensive experimental data, which include the effect of thermodynamic, operating and physical parameters on the liquid and vapour penetration of diesel sprays. In particular, the effect of liquid atomisation, evaporation, aerodynamic drag, droplet secondary break-up and fuel physical properties has been thoroughly tested. The sensitivity of the predictions on the numerical treatment of the multi-phase interaction has been investigated by identifying and properly modelling the numerical parameters playing the most crucial role in the simulations. Finally the validated code has been used to investigate the flow processes from three high-pressure injection systems for direct injection spark-ignition engines. These have included the pressure swirl atomiser, the multi-hole injector and the outward-opening pintle nozzle. These investigations have enlightened the crucial role of the accurate modelling of the link between the internal nozzle flow prediction and the characteristics of the forming sprays in term of the successive multi-phase flow interaction, as function of the design of the fuel injection system used.

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Multihole injectors for direct-injection gasoline engines

Mitroglou, Nicholas

January 2006

High-pressure multi-hole nozzles, carrying a Diesel-derived technology, are believed to be promising Fuel Injection Equipment (FIE) for Direct-Injection (DI) Spark Ignition (SI) gasoline engines. Having explored thoroughly swirl pressure atomisers and their spray behaviour, multi-hole nozzles represent the second-generation injectors. Thus, complete investigation of multi-hole nozzle flow, spray characteristics and their engine performance is a vital part of development of future DI gasoline engines. The internal nozzle flow of an enlarged transparent multi-hole injector was investigated for different flow rates and needle lifts under steady state flow conditions. High-resolution CCD camera and high speed digital video systems were employed to visualize the nozzle flow patterns and cavitation development. The images identified the onset of cavitation in multi-hole gasoline nozzles and revealed the transition from pre-film to film stage cavitation. Cavitation strings were also visualized inside the injection hole that could extend to the needle face. However, these structures are highly unstable and directly affected by needle lift and cavitation number, although it appeared to be independent of the Re, in a behaviour similar to that of multi-hole diesel injectors. The sprays from various high-pressure multi-hole nozzle designs injected into a high-pressure/temperature constant-volume chamber have been visualised and quantified in terms of droplet velocity and diameter with a two-component phase-Doppler Anemometry (PDA) system at injection pressures up to 200bar and chamber pressures varying from atmospheric to 12bar. The overall spray angles relative to the axis of the injector were found to be almost independent of injection and chamber pressure, a significant advantage relative to swirl pressure atomisers. Within the measured range, the effect of injection pressure on droplet size was rather small while the increase in chamber pressure from atmospheric to 12bar resulted in much smaller droplet velocities, by up to fourfold, and larger droplet sizes by up to 40%. The effect of chamber temperature on multi-hole sprays confirmed the expected trends that dictate smaller droplet size distributions as temperature rise from 50 to 90 and 120°C. Additionally, multiple-injection proved to have similar dependencies to the single injection with certain operating limits. Laser-induced fluorescence has been mainly used to characterise the two-dimensional fuel vapour concentration inside the cylinder of a multi-valve twin-spark ignition engine equipped with high-pressure multi-hole injectors. The effects of injection timing, in-cylinder charge motion and injector tip layout have been quantified. The flexibility in nozzle design of the multi-hole injectors has proven to be a powerful tool in terms of matching overall spray cone angle and number of holes to specific engine configurations. Injection timing was found to control spray impingement on the piston and cylinder wall, thus contributing to quick and efficient fuel evaporation. Multipleinjection performed well under certain operating conditions and proved to be a powerful tool in the hands of engine manufacturers. It was confirmed that in-cylinder charge motion plays a major role in engine's stable operation by assisting in the transportation of the air-fuel mixture towards the ignition locations (i.e. spark-plugs) in the way of a uniformly distributed charge or by preserving stratification of the charge depending on operating mode of the engine.

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Μελέτη και κατασκευή συστήματος διάγνωσης λειτουργίας τετράχρονης μηχανής

Αποστόλου, Γεώργιος, Δαλαμάγκας, Κωνσταντίνος

06 September 2010

Έγινε λήψη σήματος μέσω πιεζοκρυστάλλων και έπειτα το σήμα επεξεργάστηκε κατάλληλα μέσω του αναπτυξιακού περιβάλλοντος και έγινε διάγνωση για την κατάσταση λειτουργίας της μηχανής. / We took a signal with piezoelectrics and we processed the signal through a program and we mwde a diagnosis about the functionality of the four cycle machine.

Διάγνωση

Τετράχρονες μηχανές

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Diagnosis

Four cycle machines

Potentiel de la combustion partiellement prémélangée pour les moteurs essence / Investigation on the potential of partially premixed combustion for gasoline engine

Labreche, Amine

16 December 2015

La limitation des rejets en CO₂ associés aux normes européennes antipollution de plus en plus sévères ont conduit les constructeurs automobiles à innover dans de nouveaux concepts de combustion, dans l’objectif d’augmenter le rendement des moteurs essence conventionnels. La combustion de type Partiellement Prémélangée, communément appelée Gasoline Partially Premixed Combustion (soit GPPC) semble être l’un des possibilités pour répondre à ces problématiques, en particulier s’il était possible d’atteindre un rendement proche des rendements Diesel avec des émissions polluantes plutôt de type moteur à allumage commandé et qui pourraient donc être traitées par systèmes de post-traitement classiques. Cette étude vise, par une approche expérimentale, à comprendre les processus physiques qui permettent d’optimiser ce nouveau mode de combustion, en particulier en termes de préparation du mélange et de déroulement de la combustion proprement dite. La première partie de ce travail a consisté en la détermination de l’impact des différentes conditions thermodynamiques, de la stratégie d’injections et du taux de dilution sur le déroulement de la combustion à partir de données obtenues sur un moteur opaque. Trois modes de dégagements de chaleur très distincts ont été sélectionnés, l’un représentant la configuration optimale en termes de rendement et d’émissions polluantes à partir d’expériences réalisées sur moteur monocylindre à fort taux de compression et avec une chambre typée Diesel. Des techniques de diagnostics optiques ont été mises en place sur un moteur identique mais à accès optiques dans l’objectif d’isoler tout particulièrement l’impact du phasage de la seconde injection sur le déroulement de la combustion. L’étude de la propagation liquide du spray lors de l’injection, de l’interaction entre l’air et le carburant lors du processus de formation du mélange et de la phase d’oxydation du carburant a ainsi pu être réalisée et a permis de valider les hypothèses émises lors des essais sur moteur opaque pour expliquer les processus de combustion et donner des pistes de contrôle de ce type de combustion. / Carbon dioxide (CO₂) and other pollutant emission limitations are more and more rigorous. These limits conduct cars manufacturers to study new combustion concept, in order to increase conventional gasoline engine efficiencies. Gasoline Partially premixed combustion concept (GPPC) seems to have the potential to reach these objectives, in other terms an efficiencies comparable to diesel engine by with emissions of gasoline engine, which mean a low cost after-treatment system. This study investigates, by an experimental approach, the physical process responsible on controlling this combustion concept and by the way improves it. This will be done by studying the mixture preparation and the combustion behaviour. The first part of this work concerns on determining the impact of in-cylinder thermodynamic conditions, injection strategy and the dilution rate on combustion behaviour using a single cylinder all metal engine. Three distinctive heat release rates were selected; where one represent the optimized injection phasing in term of efficiencies and pollutant emissions. The second part was dedicated to studying the process involved in GPPC combustion mode by optical diagnostic techniques on single cylinder optical access diesel engine. The impact of second injection phasing, fuel and air interaction and also the fuel combustion process allowed the validation of hypothesis emitted in the first part to explain the combustion behaviour and give ways to control this combustion mode.

GPPC

Fluorescence induite par laser

Double injection

Contrôle de la combustion

GPPC

LIF

Double injection

Control of combustion

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Improving the performances of the combustion engines by improving the ignition system / Amélioration des performances des moteurs à combustion par amélioration du système d'allumage

Astanei, Dragoş-George

05 November 2014

Face aux normes actuelles et futures, de plus en plus drastiques, concernant les émissions de polluants, les constructeurs automobiles cherchent en permanence à améliorer l'efficacité des moteurs à allumage commandé. Une des solutions les plus efficaces et applicables pour diminuer la quantité de polluants émis dans les gaz d’échappement (HC, CO, NOx) et réduire la consommation de carburant, est d’utiliser un mélange très pauvre (richesse du mélange inférieure à 0,6). Toutefois, ce concept de fonctionnement est limité par les systèmes d'allumage classiques qui ne peuvent pas garantir un allumage du mélange air / combustible dans de bonnes conditions, de manière à assurer une combustion complète, rapide et reproductible.Le sujet de cette thèse consiste en l'élaboration d'un nouveau système d'allumage basé sur une bougie d’allumage double, qui peut produire deux d'étincelles quasi-simultanées, dont la longueur cumulée est plusieurs fois plus élevée que celle d’étincelles produites par une bougie d'allumage classique. Pour valider ce système d'allumage, trois différents types d'analyses ont été réalisés: une analyse des paramètres électriques des décharges, un diagnostic du plasma par spectroscopie optique d'émission, et des essais in situ du système d'allumage sur deux moteurs à combustion interne avec analyse des gaz d'échappement et détermination des performances des moteurs.Ces tests ont révélé que l'utilisation du système d’allumage à double étincelle peut assurer une meilleure stabilité dans le fonctionnement du moteur (en particulier dans les conditions d'allumage difficiles, en utilisant des mélanges très pauvres) ; des performances accrues du moteur pour une même quantité de carburant consommé ; et une diminution de la quantité d’hydrocarbures imbrûlés et de monoxyde de carbone dans les gaz d'échappement, mais avec une plus grande émission d'oxydes d'azote par rapport à un système d'allumage classique. / Faced with the current and future more and more drastic standards for pollutant emissions, the car manufacturers are permanently trying to improve the efficiency of spark ignition engines. One of the most effective applicable solutions for reducing the quantity of pollutant emissions (HC, CO, NOx) from the exhaust gases and also to reduce the fuel consumption is to operate with very lean mixture (equivalent ratio lower than 0.6). However, this operation concept is limited by the actual ignition systems that cannot assure an air/fuel mixture ignition in good conditions, in order to assure a complete, fast and repeatable combustion. The subject of this thesis consists into developing of a new ignition system based on a double spark plug, which can produce two quasi-simultaneous spark discharges with cumulated length few times higher than the sparks produced by a conventional spark plug. For ignition system validation, three different types of analysis have been considered: the analysis of the discharges electrical parameters, the plasma diagnosis using optical emission spectroscopy methods and the tests of the ignition system on two internal combustion engines with the exhaust gases analysis and engine performances determination. The tests revealed that the utilization of the double spark ignition system can assure a better stability in engine operation (especially in difficult ignition conditions such using very lean mixtures), increased engine performances for the same amount of consumed fuel and it can provide a diminution of the unburned hydrocarbons and carbon monoxide quantities from the exhaust gases, but with an increased quantity of nitrogen oxides, compared with a conventional ignition system.

Moteur à allumage commandé

Emissions polluantes

Allumage par plasma

Bougie d'allumage double

GPG-SM

Mélange pauvre

Spectroscopie

Internal combustion engines

Exhaust gases pollutant

Plasma ignition systems

Double spark plug

GC-MS

Lean mixture operation

Spectroscopy

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