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Having low aromatic compounds, high cetane rating, higher heat of combustion and almost zero sulphur content, a new paraffinic fuel (NPF), developed by Oroboros AB Sweden, was believed to receive attention as a new alternative fuel. Therefore, further investigation and combustion analyses were conducted in a research single-cylinder diesel engine, where detailed thermodynamic analyses were performed by Burst to File high frequency signal sampling code and by the Dragon software, revealing the real thermochemistry history. The aim of this investigation was an effort to reduce the pollution levels in Santiago de Chile by introducing this new paraffinic fuel (NPF). Experimental results have shown that the NPF fuel has a significant impact not only on the emission levels, but also on other energetic parameters of the engine such as ignition delay, cylinder peak pressure, heat release gradient, indicated efficiency etc.

Believed to have a potential in reducing the NOx emission level, hydrogen peroxide was fumigated into the inlet duct of the AVL single cylinder research engine via a standard gasoline injector, normally used in the Volvo 850-car engine. A small metallic sphere installed 3 cm downstream the injector tip, improved the spray formation and the uniform distribution of the fumigated peroxide fluid upstream the intake valve. The hydrogen peroxide flow was varied according to the desired value via an electronic pulse frequency generator. The engine, equipped with an electronic unit injector, was initially run without any fumigation fluid until the specifications of the engine test point were reached and remained very stable. Further, the hydrogen peroxide injection was activated with three different injection flows, and the engine performance, including emission levels, was compared to reference performance.

This paper depicts the main topics of the experimental investigation on alcohol engine development field, aiming at the engineering targets for the emission levels. The first part of this study was focused on engine design optimization for running on ethanol mixed with poly-ethylene glycol (PEG) as ignition improver. It was shown that some design changes in compression ratio, turbine casing, injector nozzle configuration and exhaust pressure governor (EPG) activation, lead to a better engine thermodynamics and its thermochemistry. The second objective of this study was the investigation of engine performance and emission levels, when the ignition improver diethyl ether (DEE) would be generated on board via catalytically dehydration of ethanol, and used directly as soluble mixture or separately fumigated.