The effects of fuel volatility, structure, speed and load on HC emissions from piston wetting in direct injection spark ignition engines

Huang, Yiquan

16 March 2011

Not available / text

Spark ignition engines

Automobiles--Motors--Exhaust gas

A genetic algorithms based optimisation tool for the preliminary design of gas turbine combustors

Rogero, J. M.

January 2002

The aim of this research is to develop an optimisation tool to support the preliminary design of gas turbine combustors by providing a partial automation of the design process. This tool is to enable better design to be obtained faster, providing a reduction in the development costs and time to market of new engines. The first phase of this work involved the analysis of the combustor design process with the aim of identifying the critical tasks that are suitable for being automated and most importantly identifying the key parameters describing the performance of a combustor. During the second phase of this work an adequate design methodology for this problem was defined. This led to the development of a design optimisation Toolbox based on genetic algorithms, containing the tools required for it's proper integration into the combustor preliminary design environment. For the development of this Toolbox, extensive work was performed on genetic algorithms and derived techniques in order to provide the most efficient and robust optimisation method possible. The optimisation capability of the Toolbox was first validated and metered on analytical problems of known solution, where it demonstrated excellent optimisation performance especially for higher-dimensional problems. In a second step of the testing and validation process the combustor design capability of the Toolbox was demonstrated by applying it to diverse combustor design test cases. There the Toolbox demonstrated its capacity to achieve the required performance targets and to successfully optimise some key combustor parameters such as liner wall cooling flow and NOx emissions. In addition, the Toolbox demonstrated its ability to be applied to different types of engineering problems such as wing profile optimisation.

629

Sistema de desenvolvimento para controle eletrônico dos motores de combustão interna ciclo Otto / Electronic control development system of Otto cycle internal combustion engines

Carlos Eduardo Milhor

29 November 2002

O sistema de gerenciamento dos motores automotivos tem se tornado um avançado sistema de controle. Seu objetivo é fazer com que o nível de emissões de gases poluentes gerados esteja dentro dos padrões exigidos pela legislação de cada país e ao mesmo tempo manter os níveis de desempenho e dirigibilidade. Apresenta as principais características de um típico sistema de gerenciamento de motores a combustão interna, descreve os modos de controle e aponta tendências futuras. Descreve o sistema de controle desenvolvido, o qual servirá de ferramenta de pesquisa para trabalhos que envolvam o estudo de técnicas de controle aplicadas neste contexto e pesquisas envolvendo otimização do rendimento dos motores automotivos / The automotive engine management system has become an advanced control system. Its objective is to maintain the pollutants gas emissions according to legislations and to maintain the performance and driveability, at the same time. It presents the main features of a tipical internal combustion engine management system, it describes the control modes and it point out the future tendencies. It describes the control system developed, which one will be usefull as a tool for research involving control applied in this context and engine automotive efficiency optimization researchs

injeção eletrônica de combustível

sistema de gerenciamento de motores

sistemas microprocessados

electronic fuel injection

engine management system

microprocessed systems

Produção e fornecimento de vapor de etanol para motor de combustão interna operando com combustível pré-vaporizado / Ethanol vapor production and feeding for an internal combustion engine operating with pre-vaporized fuel

Francisco José Alves

23 November 2007

O motor a álcool pré-vaporizado tem potencial para ser uma alternativa mais eficiente e menos poluente aos motores a álcool convencionais. Nele, o combustível é vaporizado com calor rejeitado pelo próprio motor e admitido na fase gasosa, aproveitando-se das vantagens dos motores com combustíveis nessa fase sem alguns dos seus inconvenientes. O projeto foi aperfeiçoado buscando viabilidade técnica e econômica para sua instalação em veículos automotores. Água do sistema de arrefecimento cede calor para a ebulição do combustível. As novas tecnologias para injeção de combustíveis gasosos contribuem para esse objetivo, bem como o desenvolvimento de um sistema sustentável e auto-ajustável de geração de vapor de etanol que usa a água do sistema de arrefecimento. Conseguiu-se maior eficiência em quase todos os regimes de funcionamento estudados, bem como meios de reduzir as principais emissões automotivas indesejáveis. / Pre-vaporized ethanol engine (PVEE) has potential to be more efficient and less pollutant than conventional ethanol-powered engines. In it, fuel is vaporized with heat rejected by engine itself and intook in gaseous form, taking advantage of this kind of fuel but without some of its inconveniences. The PVEE project was polished looking for economical and technical liability to future use in automotive vehicles. New gaseous fuel injection technologies contribute to this goal, together the development of a sustainable and self-adjustable ethanol vapor generating system who uses water from engine\'s cooling systems. Better efficiency was achieved in almost all investigated regimes, as well as were found ways to reduce the main undesirable automotive emissions.

Combustíveis gasosos

Energia renovável

Injeção de combustível

Fuel injection

Gaseous fuels

Renewable energy

Design, control and experimental testing of intelligent variable dual-fuel automotive engines

Zhao, Gui Quan

January 2017

University of Macau / Faculty of Science and Technology / Department of Electromechanical Engineering

Automobiles -- Motors

Experimental and numerical study of a two-stroke poppet valve engine fuelled with gasoline and ethanol

Dalla Nora, Macklini

January 2016

The restrictions imposed by CO2 emission standards in Europe and many countries have promoted the development of more efficient spark ignition engines. The reduced swept volume and number of cylinders of four-stroke engines has significantly improved fuel economy by means of lower pumping and friction losses. This approach, known as engine downsizing, has demonstrated its potential of reducing fuel consumption on its own as well as applied to hybrid vehicles where a low weight engine is desired. However, aggressive engine downsizing is currently constrained by thermal and mechanical stresses and knocking combustion. In order to overcome these limitations, the present work evaluates the application of a conventional poppet valve direct injection engine into the two-stroke cycle. Two-stroke engines have the ability to produce higher power with reduced swept volume and less weight than four-stroke engines thanks to the doubled firing frequency. These advantages, although, are sometimes offset by poorer emissions resulted from fuel short-circuiting; lower thermal efficiency resulted from short expansion process; and reduced engine durability due to lubrication issues. Therefore, in this research the four-stroke engine architecture was employed so these shortcomings could be addressed by the use of direct fuel injection, variable valve actuation and a wet crankcase, respectively. The burnt gases were scavenged during a long valve overlap by means of boosted air supplied by an external compressor. An electrohydraulic fully-variable valve train enabled the optimisation of the gas exchange process in a variety of engine operating conditions. The air-fuel mixture formation was evaluated through computational fluid dynamic simulations and correlated to experimental tests. In addition, the engine operation with ethanol was assessed in a wide range of engine loads and speeds. Finally, the engine performance, combustion process, air-fuel mixing and gas exchange results were presented, discussed and contextualised with current four-stroke engines. Keywords: Two-stroke poppet valve engine; gasoline and ethanol direct injection; engine downsizing; supercharged two-stroke cycle.

621.43

Atomization and mixing performance of swirl-venturi lean direct injection

Burkhalter, Matthew W.

01 December 2014

This paper investigated the effects of swirl number and momentum ratio on the atomization and mixing performance of Swirl-Venturi Lean Direct Injection technology. Mie scattering of liquid water, was used to identify the location of water droplets in a cross section of the injector spray. Experiments were performed with three air swirlers with vane angles of 45, 52 and 60 degrees. The swirl number varied from 0.58 to 1.0 and air-to-liquid ratios from 15.8 to 35.6. A transition was observed in the liquid spray distribution for the 52 degree case, which unexpectedly produced twice as much signal than the 45 and 60 degree cases. The main cause of this increased signal may be due to instabilities in the flow when transitioning from low to high swirl states. The results from investigation of swirl number it was found that the spray pattern for is sensitive to swirl intensity. Two flow states were observed for a lower and higher swirl flow as well as a transition state that occurred with the lower swirl state. This work may aid in the specific inquiry of physical mechanisms relating to the effect of flow states on spray distribution. It is found that improved atomization and mixing performance are a result of increase in swirl number.

publicabstract

Atomization

Fuel injection

Lean Direct Injection

Mie scattering

Mixing

Sprays

Mechanical Engineering

Numerical Analysis of Pulsed Jets in Supersonic Crossflow using a High Frequency Actuator

Castelino, Neil

January 2021

No description available.

Aerospace Materials

jets in crossflow

supersonic mixing

high frequency actuator

scramjets

large eddy simulations

fuel injection

Development of Predictive Gasoline Direct Fuel Injector Model for Improved In-cylinder Combustion Characterization

Mandokhot, Mohit Atul

January 2018

No description available.

Mechanical Engineering

Design and Development of a High Swirl Burner with Gaseous Fuel Injection through Porous Tubes

Ramalingam Ammaiyappan, Arul Kumaran

January 2017

No description available.

Aerospace Engineering

axial swirler

porous tube fuel injection

high swirl burner

swirl combustion

PIV

emissions