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Pressure Trace Analysis (PTA) is the basis for any combustion concept development and analysis of its combustion features. Cyclic variability analysis is also addressed using PTA, for example by means of heat release calculation. To fulfill that requirement with a low computational effort, methods for reliable fast heat release calculation of single cycles are presented. A new approach to determine the temperature in the burnt zone of a 2-zone-model is introduced as well. These PTA methods were applied to chosen combustion concepts at a representative operation point: 2000/3 bar imep (work integral over 720 cad). The gasoline combustion concepts used in this study are: homogeneous charge stoichiometric spark ignition (SI) using standard valve-train and additionally using a variable valve-train regarding lift and timing (VVA); stratified charge spray guided direct injection (SGDI) and homogeneous charge compression ignition (HCCI).

The controlled auto-ignition1 (CAI) improves dramatically the efficiency of a gasoline engine and brings it in close competition to the diesel engine without penalties in emissions. With CAI run in part-load, the gasoline engine reaches a standard driving cycle advantage of 12% in fuel economy compared to current commercial engines operating solely in homogeneous gasoline direct injection (GDI) with a stoichiometric charge. CAI is run lean in fuel and thus limited in load similar to the second generation spray guided stratified GDI strategy that promises at least the same fuel efficiency but is plagued with high NOx emissions requiring complex after-treatment systems. Although CAI produces negligible NOx, and a simple three-way catalyst suffices, it depends strongly on judiciously operating the engine within the dynamic operating cycle. Direct injection, valve actuation flexibility and advanced controls based on combustion state sensing are indispensable for this.

Novel combustion technologies, which de-throttle the gasoline spark ignition (SI) engine, show high potential in reducing the fuel consumption. Technologies like variable valve actuation and/or gasoline direct injection, allow new strategies to run the SI engine unthrottled with early inlet valve closing (SI-VVA), charge stratification (SI-STRAT) and controlled auto ignition (CAI), also known as gasoline homogeneous charge compression ignition (HCCI). These diverse combustion concepts show thermodynamic gains that stem from several, often different, sources. A multitude of definitions of thermodynamic gas exchange potentials arise when looking at the various publications concerning de-throttled combustion concepts. This paper shows a summary and comparison of these definitions and points out which one can be applied in general to evaluate various combustion concepts under the same basis of evaluation.

It is a well known fact that indicated efficiency of a SI engine at WOT is predominantly limited by knock occurrence. Therefore many investigations have been carried out to avoid knocking. Considering the further development of downsized engines knocking will also pose a greater challenge. Not only knocking but also irregular combustion in general will require further investigation in supercharged SI eingines. Premature ignition, for instance, hasn’t yet been completely understood and therefore limits the low end torque of supercharged SI engines. The purpose of this paper is to introduce different analysis methods which allow to identify the knock onset and the knocking zones in the combustion chamber. In addition to established methods new techniques have been developed to account for the complex nature of pressure oscillation during knocking combustion. Experimental data was acquired on a single cylinder research engine to validate the methodology using six pressure transducers.