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Your search keyword '"Fabio Bozza"' showing total 7 results
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7 results on '"Fabio Bozza"'

2. Exploring the potentials of water injection to improve fuel consumption and torque in a small displacement PFI spark-ignition engine

Author

Marco Piras, Luigi Teodosio, Cinzia Tornatore, Luca Marchitto, Fabio Bozza, Piras, M., Teodosio, L., Tornatore, C., Marchitto, L., and Bozza, F.

Subjects
History, Fuel Technology, Polymers and Plastics, General Chemical Engineering, Organic Chemistry, Energy Engineering and Power Technology, Business and International Management, Industrial and Manufacturing Engineering
Published
2022

3. Impact of the laminar flame speed correlation on the results of a quasi-dimensional combustion model for Spark-Ignition engine

Author

R. Amirante, Pietro Giannattasio, Fabio Bozza, Daniela Tufano, E. Distaso, Luigi Teodosio, Teodosio, L., Bozza, F., Tufano, D., Giannattasio, P., Distaso, E., and Amirante, R.

Subjects
Work (thermodynamics), Materials science, EGR, Laminar flame speed, 1D model, 020209 energy, Naturally aspirated engine, Laminar flow, 02 engineering and technology, Mechanics, Flame speed, Combustion, laminar flame speed, quasi-dimensional combustion modelling, SI engine, Energy (all), 020303 mechanical engineering & transports, 0203 mechanical engineering, Spark-ignition engine, 0202 electrical engineering, electronic engineering, information engineering, Petrol engine
Abstract

In the present study, the impact of the laminar flame speed correlation on the prediction of the combustion process and performance of a gasoline engine is investigated using a 1D numerical approach. The model predictions are compared with experimental data available for full- and part-load operations of a small-size naturally aspirated Spark-Ignition (SI) engine, equipped with an external EGR circuit. A 1D model of the whole engine is developed in the GT-Power™ environment and is integrated with refined sub-models of the in-cylinder processes. In particular, the combustion is modelled using the fractal approach, where the burning rate is directly related to the laminar flame speed. In this work, three laminar flame speed correlations are assessed, including both experimentally- and numerically-derived formulations, the latter resulting from the fitting of laminar flame speeds computed by a chemical kinetic solver. Each correlation is implemented within the combustion sub-model, which is properly tuned to reproduce the experimental performance of the engine at full load. Then, the reliability of the considered flame speed formulations is proved at part-loads, even under external EGR operations.

Published
2018

4. Potentials of cooled EGR and water injection for knock resistance and fuel consumption improvements of gasoline engines

Author

Fabio Bozza, Luigi Teodosio, Vincenzo De Bellis, Bozza, Fabio, DE BELLIS, Vincenzo, and Teodosio, Luigi

Subjects
Thermal efficiency, Engineering, 1D model, 020209 energy, Knock, 02 engineering and technology, Management, Monitoring, Policy and Law, Combustion, Automotive engineering, law.invention, Brake specific fuel consumption, 020401 chemical engineering, law, 0202 electrical engineering, electronic engineering, information engineering, Water injection (engine), 0204 chemical engineering, Engine downsizing, business.industry, Mechanical Engineering, Exhaust gas, Water injection, Building and Construction, Cooled EGR, Ignition system, General Energy, Fuel efficiency, business, Turbocharger
Abstract

It is well known that the downsizing philosophy allows the improvement of the brake specific fuel consumption (BSFC) at part load operation for spark ignition (SI) engines. On the other hand, the BSFC is penalized at high load because of the knock occurrence and of further limitations on the turbine inlet temperature (TIT). Knock control forces the adoption of a late combustion phasing, causing a deterioration of the thermodynamic efficiency, while the TIT control requires the enrichment of the air-to-fuel ratio (A/F), with additional BSFC drawbacks. In this work, two promising techniques are investigated by a 1D approach with the aim of improving the fuel economy of a turbocharged SI engine at full load knock-limited operation. The first technique is the recirculation of low-pressure cooled exhaust gas (EGR), while the second is the injection of liquid water at the intake ports. Proper “in-house developed” sub-models are used to describe the turbulence, combustion and knock phenomena. The effects of the above techniques are studied in six operating points at full load and different speeds for various A/F levels and inert content, by varying the EGR rate and water-to-fuel ratio. The presented results highlight that both the solutions involve significant BSFC improvements, especially in the operating conditions at medium engine speeds. In fact, the introduction of inert gas in the cylinder contributes to reduce the knock tendency, resulting in the possibility to advance the combustion phasing and reduce, or even avoid, the mixture over-fuelling. The heat subtracted by the water evaporation enhances the above effects, resulting in an improved fuel economy. However, the BSFC advantages are limited by the maximum allowable in-cylinder pressure, TIT, turbocharger speed, and boost level. The developed numerical procedure is able to take into account the complex interactions among different driving parameters affecting the engine behaviour. It can be hence very useful to define a numerical engine pre-calibration and to realistically predict the EGR- and water injection-related BSFC advantages.

Published
2016

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