Spelling suggestions: "subject:"autoignition"" "subject:"autoignitions""
11 |
Auto-Ignition of Liquid n-Paraffin Fuels Mixtures as Single Droplets Using Continuous ThermodynamicsSabourin, Shaun 09 August 2011 (has links)
This thesis reports a model to predict the auto-ignition time of single droplets of n-paraffin fuel mixtures using the method of continuous thermodynamics. The model uses experimental data for pure fuels to fit rate parameters for a single-step global chemical reaction equation; from this, correlations for rate parameters as a function of species molecular mass are derived, which are integrated to produce a continuous thermodynamics expression for mixture reaction rate. Experiments were carried out using the suspended droplet-moving furnace technique. The model was then tested and compared to experimental data for three continuous mixtures with known compositions: one ranging from ¬n-octane to n-hexadecane, the second ranging from n-dodecane to n-eicosane, and the third being a combination of the first two mixtures to produce a “dumbbell” mixture. Discrete and continuous mixture models of the ASTM standard distillation test were compared to design the experimental mixtures and provide the distribution parameters of the continuous mixtures intended to simulate them. The results of calculations were found to agree very well with measured ignition times for the mixtures.
|
12 |
Numerical investigation on the in-cylinder flow with SI and CAI valve timingsBeauquel, Julien A. January 2016 (has links)
The principle of controlled auto-ignition (CAI) is to mix fuel and air homogeneously before compressing the mixture to the point of auto-ignition. As ignition occurs simultaneously, CAI engines operate with lean mixtures preventing high cylinder pressures. CAI engines produce small amounts of nitrogen oxides (NOx) due to low combustion temperatures while maintaining high compression ratios and engine efficiencies. Due to simultaneous combustion and lean mixtures, CAI engines are restricted between low and mid load operations. Various strategies have been studied to improve the load limit of CAI engines. The scope of the project is to investigate the consequences of varying valve timing, as a method to control the mixture temperature within the combustion chamber and therefore, controlling the mixture auto-ignition point. This study presents computational fluid dynamics (CFD) modelling results of transient flow, inside a 0.45 litre Lotus single cylinder engine. After a validation process, a chemical kinetics model is combined with the CFD code, in order to study in-cylinder temperatures, the mixture distribution during compression and to predict the auto-ignition timing. The first part of the study focuses on validating the calculated in-cylinder velocities. A mesh sensitivity study is performed as well as a comparison of different turbulence models. A method to reduce computational time of the calculations is presented. The effects of engine speed on charge delay and charge amount inside the cylinder, the development of the in-cylinder flow field and the variation of turbulence parameters during the intake and compression stroke, are studied. The second part of the study focuses on the gasoline mixture and the variation of the valve timing, to retain different ratios of residual gases within the cylinder. After validation of the model, a final set of CFD calculations is performed, to investigate the effects of valve timing on flow and the engine parameters. The results are then compared to a fully homogeneous mixture model to study the benefits of varying valve duration. New key findings and contributions to CAI knowledge were found in this investigation. Reducing the intake and exhaust valve durations created a mixture temperature stratification and a fuel concentration distribution, prior to auto-ignition. It resulted in extending the heat release rate duration, improving combustion. However, shorter valve timing durations also showed an increase in heat transfer, pumping work and friction power, with a decrease of cylinder indicated efficiency. Valve timing, as a method to control auto-ignition, should only be used when the load limit of CAI engines, is to be improved.
|
13 |
Tabulation de la cinétique chimique pour la modélisation et la simulation de la combustion turbulente / Tabulated chemistry for turbulent combustion modeling and simulationVicquelin, Ronan 17 June 2010 (has links)
Cette thèse se situe dans le cadre de la simulation numérique de la combustion turbulente à l’aide de méthodes de tabulation de la cinétique chimique. En approximant la structure fine des flammes turbulentes, ces méthodes prennent en compte des effets fins de cinétique chimique pour un faible coup dans les calculs numériques. Ceci permet de prédire les champs de température et d’espèces chimiques incluant les polluants. Le champ d’application de la chimie tabulée a d’abord été réservé à la simulation des écoulements moyens (RANS) dans une hypothèse de faible nombre de Mach pour une combustion dite "conventionnelle". Cependant, le développement actuel de nouvelles technologies de combustion ainsi que celui de modèles numériques plus avancés que les approches RANS nécessite d’étendre ce champ d’application. Les travaux de cette thèse ont mené au développement de nouveaux modèles de chimie tabulée afin de répondre à ces nouvelles exigences. L’émergence de nouvelles technologies comme la combustion sans flamme nécessite le développement de modèles dédiés. Ce mode de combustion présente en effet des structures de flamme mixtes. C’est pourquoi un modèle de tabulation de la cinétique chimique nommé UTaC (Unsteady flamelets Tabulated Chemistry) est proposé pour prédire la combustion diluée à haute température qui caractérise la combustion sans flamme. Le modèle est basé sur la tabulation de solutions instationnaires de flammelettes non-prémelangées qui s’auto-allument. Les pertes thermiques et la dilution variable des gaz brûlés sont négligés dans le cadre de cette thèse par soucis de simplification et de clarté de la validation du modèle. Le modèle est appliqué au cas d’un jet de combustible dilué dans un environnement de gaz vicié qui favorise l’auto-allumage comme moyen de stabilisation d’une flamme liftée. Plusieurs simulations RANS sont réalisées en faisant varier le combustible utilisé. Enfin, une simulation aux grandes échelles (LES) est aussi conduite pour le mélange méthane/air. Plusieurs codes numériques dédiés à la LES sont basés sur une formulation compressible des équations de Navier-Stokes. Cependant les méthodes de tabulation ne permettent pas directement de prendre en compte les effets acoustiques. Un modèle appelé TTC (Tabulated Thermo-chemistry for Compressible flows) a été créé afin d’introduire les méthodes de chimie tabulée dans les codes numériques compressibles. Pour cela, le calcul de la température est reformulé ainsi que le traitement des conditions aux limites à l’aide d’ondes caractéristiques. Enfin, l’application de modèle RANS de tabulation de la cinétique chimique à la LES est souvent faite sans tenir compte des spécificités de la simulation aux grandes échelles. Ainsi, les fonctions de densité de probabilités de type ß qui traduisent l’interaction de la combustion avec la turbulence en RANS sont utilisées telles quelles en LES. Nous montrerons que cette hypothèse est mauvaise car elle ne conserve pas l’intégrale du terme source dans une flamme prémélangée. Un nouveau modèle de chimie tabulée nommé F-TACLES (Filtered Tabulated Chemistry for Large Eddy Simulation) est alors développé spécifiquement pour la simulation aux grandes échelles de la combustion parfaitement prémélangée. Le modèle est basé sur le filtrage de flammes laminaires de prémélange mono-dimensionelles. / The thesis subject is located in the domain of numerical simulation of turbulent combustion through tabulated chemistry methods. These methods allow to include detailed chemistry effects at low cost in numerical simulation by approximating the fine scales structure of turbulent flames. Prediction of temperature and chemical species including pollutants becomes then possible. Tabulated chemistry models were first dedicated to low Mach-number RANS approaches for "conventional" combustion applications. However, the current uprising of new combustion configurations and of more precise numerical modeling than RANS approach requires to widen these range of applications. For that purpose, this thesis led to the development of new tabulated chemistry models. Flameless combustion is one of these new combustion technology that requires dedicated models. Indeed, complex flame structures are encountered in this combustion mode. That is why a tabulated chemistry model called UTaC (Unsteady flamelets Tabulated Chemistry) is derived to simulate high temperature diluted combustion which characterizes flameless combustion. The model lies on the tabulation of laminar unsteady non-premixed flamelets that auto-ignite. Heat losses and variation of dilution with burnt gases are neglected in the topic of this thesis for brevity and simplification of the model validation. The investigated configuration is a fuel jet diluted in a vitiated coflow. The hot coflow promotes auto-ignition in the lifted flame stabilization mechanism. Several RANS computations are performed by changing the fuel composition. Finally, a Large Eddy Simulation (LES) is also realized using a methane/air mixture as the impinging fuel stream. Several numerical codes for LES use a fully compressible formulation of Navier-Stokes equations. However, tabulated chemistry techniques do not take into account acoustic perturbations. A model called TTC (Tabulated Thermo-chemistry for Compressible flows) formalism is therefore developed in order to include tabulated chemistry in compressible CFD codes. TTC formalism consists in reformulating both temperature computation inside the numerical code and the characteristic boundary treatment. Finally, application of tabulated chemistry model to LES is usually done by a straightforward derivation from its RANS version without taking into account LES requirements. Indeed, ß-probability density functions which accounts for turbulence-chemistry interaction in RANS are used in LES although this technique does not conserve the source terms integral in premixed flames. A new model, F-TACLES (Filtered Tabulated Chemistry for Large Eddy Simulation), is then derived specifically for LES of perfectly premixed combustion. This model is based on filtering of 1D laminar premixed flamelets.
|
14 |
Auto-Ignition of Liquid n-Paraffin Fuels Mixtures as Single Droplets Using Continuous ThermodynamicsSabourin, Shaun January 2011 (has links)
This thesis reports a model to predict the auto-ignition time of single droplets of n-paraffin fuel mixtures using the method of continuous thermodynamics. The model uses experimental data for pure fuels to fit rate parameters for a single-step global chemical reaction equation; from this, correlations for rate parameters as a function of species molecular mass are derived, which are integrated to produce a continuous thermodynamics expression for mixture reaction rate. Experiments were carried out using the suspended droplet-moving furnace technique. The model was then tested and compared to experimental data for three continuous mixtures with known compositions: one ranging from ¬n-octane to n-hexadecane, the second ranging from n-dodecane to n-eicosane, and the third being a combination of the first two mixtures to produce a “dumbbell” mixture. Discrete and continuous mixture models of the ASTM standard distillation test were compared to design the experimental mixtures and provide the distribution parameters of the continuous mixtures intended to simulate them. The results of calculations were found to agree very well with measured ignition times for the mixtures.
|
15 |
Experimental Study of the Role of Intermediate-Temperature Heat Release on Octane SensitivityPeterson, Jonathan 07 1900 (has links)
Increasing the efficiency of the spark-ignition engine can help to reduce the environmental impact of the transportation sector. Engine knock obstructs the increased efficiency that could be gained by increasing the compression ratio in a spark-ignition (SI) engine.
A fuel’s propensity to knock is measured by the research octane number (RON) and the motor octane number (MON) in a co-operative fuel research (CFR) engine. A fuel’s octane sensitivity (OS) is the difference between the RON and MON. Modern downsized and turbocharged engines operate at what is considered to be beyond-RON conditions. Studies have shown that having a fuel with higher OS improves knock resistance at beyond-RON conditions.
This study aims to gain a better understanding of the role of intermediate-temperature heat release (ITHR) in defining OS and its subsequent impact on SI operation through the experimental framework. The ITHR of toluene primary reference fuels (TPRFs) fuels with matching RON and varying OS was studied at RON-like and MON-like homogeneous charge compression ignition (HCCI) conditions for two different matching criteria.
The first criterion was to control the combustion phasing by matching half of the heat release (CA50) to 3 crank angle degrees after top dead center. The second criterion was to match the compression ratios.
Results showed that at RON-like HCCI conditions, TPRF fuels display decreasing ITHR with increasing OS. Furthermore, it was shown that TPRF fuels with low sensitivity displayed a greater increase in ITHR from MON-like conditions to RON-like conditions. Thus, the sensitivity of ITHR to changes in operating conditions was found to be a contributing factor to OS.
In the beyond-RON conditions (relevant to current modern engines), there is a potential for improved engine efficiency by using fuels with high OS to allow for higher compression ratios. The experimental results of this work show that OS is negatively correlated with ITHR. Thus, high-sensitivity fuels can be designed by choosing components and additives that reduce the amount of ITHR.
|
16 |
A study of controlled auto ignition (CAI) combustion in internal combustion enginesMilovanović, Nebojša January 2003 (has links)
Controlled Auto Ignition (CAI) combustion is a new combustion principle in internal combustion engines which has in recent years attracted increased attention. In CAI combustion, which combines features of spark ignition (SI) and compression ignition (CI) principles, air/fuel mixture is premixed, as in SI combustion and auto-ignited by piston compression as in CI combustion. Ignition is provided in multiple points, and thus the charge gives a simultaneous energy release. This results in uniform and simultaneous auto-ignition and chemical reaction throughout the whole charge without flame propagation. CAI combustion is controlled by the chemical kinetics of air/fuel mixture with no influence of turbulence. The CAI engine offers benefits in comparison to spark ignited and compression ignited engines in higher efficiency due to elimination of throttling losses at part and idle loads. There is a possibility to use high compression ratios since it is not knock limited, and in significant lower NOx emission (≈90%) and particle matter emission (≈50%), due to much lower combustion temperature and elimination of fuel rich zones. However, there are several disadvantages of the CAI engine that limits its practical application, such as high level of hydrocarbon and carbon monoxide emissions, high peak pressures, high rates of heat release, reduced power per displacement and difficulties in starting and controlling the engine. Controlling the operation over a wide range of loads and speeds is probably the major difficulty facing CAI engines. Controlling is actually two-components as it consists of auto-ignition phasing and controlling the rates of heat release. As CAI combustion is controlled by chemical kinetics of air/fuel mixture, the auto-ignition timing and heat release rate are determined by the charge properties such as temperature, composition and pressure. Therefore, changes in engine operational parameters or in types of fuel, results in changing of the charge properties. Hence, the auto-ignition timing and the rate of heat release. The Thesis investigates a controlled auto-ignition (CAI) combustion in internal combustion engines suitable for transport applications. The CAI engine environment is simulated by using a single-zone, homogeneous reactor model with a time variable volume according to the slider-crank relationship. The model uses detailed chemical kinetics and distributed heat transfer losses according to Woschini's correlation [1]. The fundamentals of chemical kinetics, and their relationship with combustion related problems are presented. The phenomenology and principles of auto-ignition process itself and its characteristics in CAI combustion are explained. The simulation model for representing CAI engine environment is established and calibrated with respect to the experimental data. The influences of fuel composition on the auto-ignition timing and the rate of heat release in a CAI engine are investigated. The effects of engine parameters on CAI combustion in different engine concepts fuelled with various fuels are analysed. The effects of internal gas recirculation (IEGR) in controlling the auto-ignition timing and the heat release rate in a CAI engine fuelled with different fuels are investigated. The effects of variable valve timings strategy on gas exchange process in CAI engine fuelled with commercial gasoline (95RON) are analysed.
|
17 |
Vaporization and Combustion Processes of Alcohols and Acetone-Butanol-Ethanol (ABE) blended in n-Dodecane for High Pressure-High Temperature Conditions : Application to Compression Ignition Engine / Procédés de Vaporisation et Combustion des Alcools et de l'Acétone-Butanol-Ethanol (ABE) Mélangés au n-dodécane dans des Conditions de Haute-Pression et Haute-Température : Application au Moteur à allumage par compressionNilaphai, Ob 18 October 2018 (has links)
La préoccupation de plus en plus importante ces dernières décennies, liée à l’épuisement des ressources pétrolières et au réchauffement climatique par les gaz à effet de serre a accentué l’intérêt du butanol comme carburant alternatif dans le secteur des transports grâce à ses propriétés adaptées pour le moteur à allumage par compression. Cependant, le faible rendement des procédés de production et de séparation empêche encore sa commercialisation en tant que carburant. C’est pourquoi le mélange de fermentation intermédiaire de la production de butanol, Acétone-Butanol-Ethanol(ABE), est de plus en plus considéré comme un carburant alternatif potentiel en raison de ses propriétés similaires au butanol et de ses avantages quant à son cout énergétique pour sa fabrication.Dans ce cadre, ce travail a pour objectif d’étudier l’impact des propriétés de différents mélanges d’ABE et n-dodécane en comparaison avec des mélanges d’alcools (éthanol et butanol) sur le processus de pulvérisation et de combustion et ce,pour différentes proportions en volume allant de 20% à 50%. Pour cela, une nouvelle chambre de combustion appelée"New One Shot Engine ", a été réalisée et utilisée car les conditions haute pression et haute température de "Spray-A" (60bars, 800-900 K et 22,8 kg/m³) définies par le réseau Engine Combustion network (ECN) peuvent être atteintes. Autant les phases liquides et vapeur que de combustion ont été caractérisées grâce à l’utilisation des plusieurs techniques optiques (extinction, Schlieren, chimiluminescence d’OH*) dans des conditions non réactives (Azote pur) et réactives (avec15% d'oxygène). Ces résultats expérimentaux ont non seulement permis d’étudier l’impact en oxygène moléculaire et de fournir une nouvelle base de données fiables, mais aussi d’affirmer la possibilité d’utiliser jusque 20% d’ABE en volume dans des moteurs à allumage par compression, grâce à ses caractéristiques de pulvérisation et de combustion similaires au carburant Diesel conventionnel. / The growing concern in recent decades, linked to the depletion of oil resources and global warming by greenhouse gases has increased the interest of butanol as an alternative fuel in the transport sector. However, the low yield of production and separation processes still prevents its commercialization as a fuel. Therefore, the intermediate fermentation mixture of butanol production, Acetone-Butanol-Ethanol (ABE), is increasingly considered as a potential alternative fuel because of its similar properties to butanol and its advantages in terms of the energy and cost in the separation process.The context of this work aims to study the impact of fuel properties on the spray and combustion processes of ABE mixture and alcohol fuels, blended with the diesel surrogate fuel, n-dodecane, in different volume ratio from 20% to 50%. A new combustion chamber called "New One Shot Engine," was designed and developed to reach the high-pressure and high temperatureconditions of "Spray-A" (60 bar, 800-900 K and 22.8 kg/m³) defined by the Engine Combustion Network (ECN).The macroscopic spray and combustion parameters were characterized by using the several optical techniques (extinction,Schlieren, chemiluminescence of OH*) under non-reactive (pure Nitrogen) and reactive (15% of oxygen) conditions. These experimental results not only made it possible to study the molecular oxygen impact and provide a new accurate database,but also to affirm the possibility of using ABE up to 20% by volume in compression-ignition engines, as its spray and combustion characteristics similar to conventional diesel fuel.
|
18 |
Etude de l’effet du taux d’oxygène sur la combustion en moteur à allumage commandé suralimenté / The study of the oxygen controlled combustion in downsized SI engineZhou, Jianxi 17 June 2013 (has links)
Aujourd’hui, les constructeurs automobiles continuent de chercher les technologies renouvelables face à la pénurie d’énergie et les problèmes d’émission de polluants. Un moyen important pour optimiser l’économie de carburant et réduire les émissions polluantes des moteurs à allumage commandés est le concept ‘downsizing’. Cependant, ce concept est limité par le phénomène de cliquetis dû aux conditions de haute température et haut pression. Dans cette étude, le contrôle de la concentration d’oxygène dans l’air est proposé. Car d’une part, la combustion enrichie en oxygène permet d’améliorer la densité de puissance de moteur avec le même niveau de pression d’admission. Cela permet soit de ‘booster’ la combustion pour augmenter la puissance du moteur ou de l’activer lorsque le moteur fonctionne à faible charge ou dans des conditions de démarrage à froid. D’autre part, une faible concentration en oxygène dans l’air (ou dilution de N2) par un système membranaire peut être considérée comme une alternative à la recirculation des gaz d’échappement. Les expériences ont été effectuées dans un moteur monocylindre ‘downsizing’ avec différents taux d’oxygène et richesse. L’étude de l’impact du contrôle de la concentration d’oxygène sur les caractéristiques de combustion et d’émissions a été effectuée pour plusieurs charges en fonctionnement optimum pour limiter la consommation spécifique de carburant. L’effet de la concentration en oxygène sur les caractéristiques de combustion du moteur a été simulé en utilisant le logiciel commercial AMESim avec le modèle de combustion développé par IFP-EN. En mettant en oeuvre des corrélations de la vitesse de combustion laminaire, déterminées au préalable durant ce travail, et délai d’auto-inflammation, les pressions dans les cylindres sont parfaitement calibrés avec une erreur maximale inférieure à 2% et l’intensité du cliquetis a pu être prédite. / Nowadays, car manufacturers continue to lead researches on new technologies facing to the energy shortage and pollutant emission problems. A major way to optimise fuel economy and reduce pollutant emissions for Spark-Ignition (SI) engines is the downsizing concept. However, this concept is unfortunately limited by ‘knock’ phenomena (abnormal combustion) due to high temperature and high pressure in-cylinder conditions. In the present study, control the oxygen concentration in air is proposed. Indeed, on the one hand, oxygen-enriched combustion can improve engine power density with the same intake pressure level. Thus, oxygen-enriched combustion can be used either as a booster to increase engine output or as a combustion enhancer when the engine operates at low loads or in cold start conditions. On the other hand, low oxygen concentration in air (or N2 dilution) can be considered as an alternative to exhaust gas recirculation (EGR). The experiments were carried out in a downsized single-cylinder SI engine with different rates of oxygen and equivalence ratios. The study of the impact of controlling oxygen concentration on the combustion characteristics and emissions was performed at several loads by optimizing the spark advance and the intake pressure to maintain the load and obtain a minimum value of indicated Specific Fuel Consumption (SFC). The effect of oxygen concentration on the engine combustion characteristics was simulated by using the commercial software AMESim, with the combustion model developed by IFP-EN. By implementing correlations for the laminar burning velocity, determined previously during this study, and auto-ignition delay data base, the in-cylinder pressures were perfectly calibrated with a maximum pressure relative error less than 2%, and the knock intensity was predicted.
|
19 |
Contribution à la compréhension des combustions anormales dans les moteurs à allumage commandé : caractérisation et analyse phénoménologique du pré allumage à forte charge / Contribution the understanding of abnormal combustions in spark ignition engines : characterization and phenomenological analysis of pre-ignition at high loadZaccardi, Jean-Marc 09 March 2012 (has links)
L'augmentation continue des charges de fonctionnement des moteurs à allumage commandé a conduit à l'apparition d'une nouvelle forme de combustion anormale à bas régime sous la forme d'un pré allumage. Dans des conditions de pression et de température extrêmes, une auto-inflammation incontrôlée du mélange carburé peut en effet se produire avant l'allumage normal à la bougie et conduire à une seconde auto-inflammation de type cliquetis donnant naissance à des oscillations de pression inacceptables même pour les moteurs les plus robustes. Cette anomalie constitue donc une véritable limite au downsizing des moteurs et à l'augmentation de leurs performances spécifiques. Cette dernière forme de combustion anormale est bien plus critique que le cliquetis car son apparition est aléatoire, le plus souvent sporadique et généralement très violente. Ces caractéristiques fondamentales expliquent que de nouveaux outils et de nouvelles méthodologies d'analyse aient dû être développés pour mieux caractériser le processus d'auto-inflammation dans ces conditions extrêmes. Des méthodes statistiques avancées ont notamment été mises au point pour quantifier de manière fiable la fréquence d'apparition du pré allumage malgré son caractère aléatoire. En parallèle, un travail expérimental important a été réalisé pour mettre au point une méthodologie de réalisation de visualisations endoscopiques permettant de mieux analyser le processus de combustion, et d'identifier de manière plus précise les zones préférentielles d'apparition du pré allumage dans la chambre de combustion. Les impacts des paramètres fondamentaux régissant l'auto-inflammation (aérodynamique interne, thermique et chimie du mélange) ont d'abord été analysés sur un monocylindre de recherche. Le processus de combustion a ainsi été détaillé et l'hypothèse d'une auto-inflammation spontanée en phase gazeuse a également pu être abordée en parallèle de l'analyse expérimentale par une approche numérique RANS. Une étude plus approfondie a ensuite montré qu'il était possible qu'un pré allumage conduise à une auto-inflammation de type détonation, ce qui explique qu'un nombre réduit d'occurrences suffise à détériorer irrémédiablement le moteur. La versatilité du monocylindre a également permis de mettre en évidence la diversité des phénomènes qui pouvaient conduire au pré allumage et d'autres hypothèses que celle d'une auto-inflammation spontanée en phase gazeuse ont ainsi pu être formulées. Celles-ci ont finalement été testées sur un multicylindre en appliquant des méthodologies d'essais et d'analyse éprouvées sur monocylindre. Les investigations tournées vers l'impact des réglages moteur ont alors notamment confirmé que les impacts du carburant sur les parois de la chambre de combustion conduisaient à la formation de films liquides dont les caractéristiques locales pouvaient être favorables à une auto-inflammation. / The continuous increase of engine loads on SI engines has provoked the apparition of a new form of abnormal combustion at low engine speed in the guise of a pre-ignition. Under extreme conditions of pressure and temperature, an uncontrolled auto-ignition of the fresh mixture can happen well before the normal ignition at the spark and lead to a knocking-like second auto-ignition and to unacceptable pressure oscillations even for modern and robust engines. This anomaly constitutes thus a strong limit to the downsizing of gasoline engines and to the increase of their specific performance. This latter abnormal combustion is far more critical than knocking combustion since its apparition is random, most often sporadic and usually very violent. These fundamental characteristics explain that new tools and methodologies had to be developed to achieve a better characterization of the auto-ignition process under such extreme conditions. Advanced statistical methods have notably been defined to obtain a reliable quantification of the pre-ignition frequency despite its randomness. A significant work has simultaneously been realized to develop an experimental methodology dedicated to endoscopic visualizations allowing a better analysis of the combustion process and a more precise identification of the preferential areas of auto-ignition inside the combustion chamber. The impacts of fundamental parameters governing auto-ignition (the mixture's charge motion, thermal and chemical evolutions) have first been analyzed thanks to a research single cylinder engine. That way, the combustion process has been detailed and the hypothesis of a spontaneous auto-ignition of the gaseous mixture has also been tackled at the same time with the help of a numerical RANS approach. Then, a deeper analysis has showed that pre-ignition could lead to a developing detonation mode during the second auto-ignition, explaining so that a reduced number of events could cause irremediable damages. Thanks to the flexibility of the single cylinder engine, it has also been shown that a wide variety of phenomena could lead to pre-ignition and it has made possible the formulation of other hypotheses than a spontaneous auto-ignition of the gaseous mixture. These ones have finally been tested on a serial multi-cylinder engine with test and analysis methodologies validated on the single cylinder engine. The investigations focused on the impacts of settings have then confirmed that the fuel impacts on the liner and on the piston lead to the formation of liquid films whose local characteristics could be favorable to auto-ignition.
|
20 |
Analysis of the potential of SI lean combustion and CAI combustion in a two-stroke spark-assisted gasoline engineValero Marco, Jorge 09 March 2020 (has links)
[EN] Internal combustion engines are in a situation in which they must be cleaner and more efficient than they have ever been. This change is motivated by the global and continuous evolution of the emissions regulations linked to their commercialization, which try to establish the path to protect the human health, and move towards more sustainable energetic models.
Framed in this context, the research work developed in this PhD thesis has focused on the way to continue improving the spark ignition engines. To this end, a prototype two-stroke engine has been used, with the idea of studying the Spark Ignited combustion in lean conditions ('lean SI') and the Controlled Auto-Ignition combustion 'CAI'). In this way, the traditional 'SI' operation in stoichiometric conditions of this type of engines is replaced, looking for an improvement in fuel efficiency, and a reduction, at the same time, of the pollutant emissions.
This work has been approached mainly from an experimental point of view. Firstly, different works have been performed on the engine: operation of the different combustion modes, definition of the operating strategies, and compilation of experimental data coming from the engine operation in the different regions of the engine map. And, secondly, all this data has been analyzed and studied in detail to define the strengths and weaknesses of each combustion mode applied to the different engine operating conditions.
The combination of these two works has led to obtain a large amount of data about the achievable efficiencies and the emissions values obtained in each combustion mode. And, in addition, the influence on the combustion of the burned gases recirculation in the engine ('EGR'), has also been studied as a strategy to reduce emissions, and control the combustion at high loads in both combustion modes.
Regarding the analytical part of the work, several problems have been detected. Firstly, the high combustion variability in this engine, and secondly, the coupling of two completely different combustion modes. These issues have generated the need to analyze the data obtained in a more detailed way, in order to get more information about the combustion process. To solve these two aspects, first, a different point of view has been raised when dealing with the combustion diagnosis, the cycle to cycle analysis, and secondly, a combustion analysis methodology has been proposed in order to allow the combustion analysis from a more detailed point of view. In this way the combustion development is studied, and thus, the differentiation between the different combustion events that take place in the engine can be studied.
All this work has been useful to define the strategies to operate the whole engine map by combining the 'lean SI' and 'CAI' combustion modes. This solution, compared to the current Euro VI engines, has presented higher efficiency values complying with the established emissions limits, showing in this way, the high potential of these combustion modes applied to 'SI' engines, as well as a real possibility of its implementation in future vehicles. / [ES] Los motores de combustión interna viven un momento en el que deben ser más limpios y eficientes de lo que han sido hasta la fecha. Este cambio viene dado por el endurecimiento global y continuado de las normativas anticontaminación vinculadas a su comercialización, que tratan de establecer el camino para proteger la salud de las personas que conviven con éstos, y avanzar hacia unos modelos más sostenibles de uso de las energías disponibles.
Enmarcado en este contexto, el trabajo de investigación desarrollado en esta tesis se ha centrado en continuar avanzando en el camino para la mejora de los motores de encendido provocado. Para este fin se ha empleado un motor prototipo de dos tiempos con la idea de estudiar la combustión por encendido provocado en mezclas pobres 'lean SI') y la combustión mediante el autoencendido controlado de la mezcla ('CAI'). De esta forma la operación tradicional en condiciones estequiométricas de este tipo de motores es reemplazada, en busca de una mejora en la eficiencia energética, y una reducción, al mismo tiempo, de las emisiones contaminantes.
Este trabajo se ha abordado desde un punto de vista principalmente experimental. En primer lugar se ha trabajado sobre el motor, operando los diferentes modos de combustión, fijando las estrategias de operación, y obteniendo gran cantidad de datos sobre el funcionamiento del motor en las diferentes regiones del mapa motor. Y, en segundo lugar, estos datos han sido analizados y estudiados en detalle para detectar los potenciales y las debilidades de cada modo de combustión aplicado a las diferentes condiciones de funcionamiento del motor.
La combinación de estos dos trabajos ha servido para obtener gran cantidad de datos sobre las eficiencias alcanzables y los valores de emisiones obtenidos en cada modo de operación. Y, adicionalmente, se ha estudiado también la influencia de la recirculación de gases quemados en el motor ('EGR') sobre la combustión, como estrategia para reducir las emisiones y controlar la combustión a altas cargas en ambos modos de operación.
En cuanto a la parte analítica del trabajo, se han detectado diversos problemas. En primer lugar, lidiar con la alta variabilidad de la combustión en este motor, y en segundo lugar, el acople de dos modos de combustión totalmente diferentes. Esto ha generado la necesidad de analizar los datos obtenidos de forma que nos den algo más de información sobre la forma en que se ha desarrollado la combustión. Para dar solución a estos dos aspectos, se ha planteado un punto de vista diferente a la hora de afrontar el diagnóstico de la combustión (análisis ciclo a ciclo) y se ha propuesto una metodología de análisis de la combustión que nos permita estudiar, desde un punto de vista más detallado, la forma en que se ha desarrollado la combustión, y tratar de diferenciar así los diferentes eventos de combustión que se desarrollan en el motor.
Todo este trabajo ha dado sus frutos en forma de la definición de las estrategias para operar el motor en su totalidad mediante la combinación de los modos 'lean SI' y 'CAI'. Esta solución, en comparación con los motores actuales Euro VI, ha presentado unos valores de eficiencia superiores cumpliendo con los límites establecidos de emisiones, mostrando de esta forma un elevado potencial de estos modos de combustión aplicados a los motores de encendido provocado, así como una posibilidad real de implementación en los vehículos venideros. / [CA] Els motors de combustió interna alternatius es troben a un moment en el que deuen ser mes nets i eficients que mai. Aquest canvi ve motivat per l'augment de l'exigència de les normatives reguladores d'emissions contaminants vinculades a la seua comercialització, que tracten d'establir el camí per a protegir la salut de les persones que conviuen amb aquests, i avançar cap a uns models mes sostenibles d'aprofitament de les energies disponibles.
Dins d'aquest context, el treball d'investigació realitzat en aquesta tesi, ha girat al voltant de la millora dels motors d'encesa provocada. Per a aquesta finalitat, s'ha emprat un prototip de motor de dos temps amb l'idea d'estudiar la combustió per encesa provocada amb dosatges pobres 'lean SI') i la combustió mitjançant una auto-encesa provocada per les condicions termodinàmiques de la cambra de combustió ('CAI'). D'aquesta manera l'operació tradicional en condicions estequiomètriques d'aquest tipus de motors és substituïda, buscant una millora en l'eficiència energètica i una reducció al mateix temps de les emissions contaminants.
Aquest treball s'ha abordat des d'un punt de vista fonamentalment experimental. En primer lloc s'ha treballat sobre el motor, operant els diferents modes de combustió, fixant les estratègies d'operació, i obtenint gran quantitat de dades sobre el funcionament del motor en les diferents regions del seu mapa d'operació. I en segon lloc, aquestes dades han sigut analitzades i estudiades en detall per a detectar els potencials i les debilitats de cada mode de combustió aplicat a les diferents condicions de funcionament del motor.
La combinació d'aquests dos treballs ha servit per a obtindre gran quantitat de dades sobre les eficiències assolibles i els valors d'emissions obtinguts en cada mode d'operació. I, a més, s'ha estudiat la influència de la recirculació de gasos d'escapament al motor ('EGR') sobre la combustió, com a estratègia per a reduir les emissions contaminants i controlar la combustió a altes càrregues en els dos modes de combustió.
Quant a la part analítica del treball, s'han detectat diversos problemes. En primer lloc, tractar amb l'alta variabilitat de la combustió en aquest motor, i en segon lloc, l'acoblament de dos modes de combustió totalment diferents. Açò ha generat la necessitat d'analitzar les dades obtingudes de forma que ens donen més informació sobre la forma en que s'ha desenvolupat la combustió. Per a donar solució a aquests dos aspectes, s'ha plantejat un punt de vista diferent a l'hora de realitzar el diagnòstic de la combustió (un anàlisis cicle a cicle) i s'ha proposat una metodologia d'anàlisi de la combustió que permeta estudiar, des d'un punt de vista més detallat, la forma en que s'ha desenvolupat la combustió, i tractar de diferenciar així, les diferents combustions al motor.
Tot aquest treball ha donat uns resultats en forma de la definició de les estratègies per a operar el motor en la seva totalitat mitjançant la combinació dels modes de combustió 'lean SI' i 'CAI'. Aquesta solució, en comparació amb els actuals motors Euro VI, ha ofert uns valors d'eficiència superiors, acomplint amb les limitacions establertes d'emissions, mostrant d'aquesta manera un elevat potencial d'aquests modes aplicats als motors d'encesa provocada, així com una possibilitat real d'implantació en els vehicles que estan per vindre. / Valero Marco, J. (2020). Analysis of the potential of SI lean combustion and CAI combustion in a two-stroke spark-assisted gasoline engine [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/138556
|
Page generated in 0.0919 seconds