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The paper illustrates both numerical and experimental methodologies aiming to characterize performances and overall noise radiated from a light duty diesel engine. The main objective was the development of accurate models to be included within an optimization procedure, able to define an optimal injection strategy for a common rail engine. The injection strategy was selected to contemporary reduce the fuel consumption and the combustion noise. To this aim, an experimental investigation was firstly carried out measuring engine performances and noise emissions at different operating conditions. Contemporary, a one-dimensional (1D) simulation of the engine under investigation was performed, finalized to predict the in-cylinder pressure cycles and the overall engine performances. The 1D model was validated with reference to the measured data. In order to assess the combustion noise, an innovative study, mainly based on the decomposition of the in-cylinder pressure signal, was utilized.

The paper illustrates the interdisciplinary matching of different numerical and experimental techniques, aimed to characterize the performances, emissions and combustion noise radiated from a small-size DI diesel engine. The main objective is the development of proper models to be included within an optimization procedure, able to define an optimal injection strategy for a common-rail engine. The injection strategy is selected to simultaneously reduce the fuel consumption, the pollutant emissions and the combustion noise. The engine considered is a naturally aspirated, four strokes, two valves, single-cylinder engine (505 cm3 displacement), to be equipped with a prototype common-rail fuel injection system. A preliminary experimental investigation is carried out on the above engine, equipped, however, with a standard mechanical injection system (base engine).

Despite the recent efforts devoted to develop alternative technologies, it is likely that the internal combustion engine will remain the dominant propulsion system for the next 30 years and beyond. Also as a consequence of more and more stringent emissions regulations established in the main industrialized countries, strongly demanded are methods and technologies able to enhance the internal combustion engines performance in terms of both efficiency and environmental impact. Present work focuses on the development of a numerical method for the optimization of the control strategy of a diesel engine equipped with a high pressure injection system, a variable geometry turbocharger and an EGR circuit. A preliminary experimental analysis is presented to characterize the considered six-cylinder engine under various speeds, loads and EGR ratios.