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In a future ‘hybrid’ mode internal combustion engine capable of running in spark ignition (SI) and controlled auto ignition-CAI (also known as Homogeneous Charge Compression Ignition-HCCI) modes, transition between these modes, during changes in engine load and speed, will play a crucial role. The valve train and engine management system (EMS) must provide a fast and smooth transition between these two very different combustion modes keeping all relevant engine and combustion parameters in an acceptable range. In order to obtain such transition between SI and HCCI and SI, a valve event (duration, timing and lift) has to be variable, which consequently leads to high demands on the valve train and therefore a need for its higher degree of flexibility. Two valve train concepts, one with a Cam Profile Switching (CPS) and phaser system and the other camless using Fully variable Valve Train (FVVT) are presented.

The Homogeneous Charge Compression Ignition (HCCI) engine combustion uses heat energy from trapped exhaust gases enhanced by the piston compression heating to auto ignite a premixed air/gasoline mixture. As the HCCI combustion is controlled by the charge temperature, composition and pressure, it therefore, prevents the use of a direct control mechanism such as in the spark and diesel combustion. Using a large amount of trapped residual gas (TRG), is seen as one of the ways to achieve and control HCCI in a certain operating range. By varying the amount of TRG in the fresh air/fuel mixture (inside the cylinder), the charge mixture temperature, composition and pressure can be controlled and hence, the auto ignition timing and heat release rate. The controlled auto ignition (HCCI) engine concept has the potential to be highly efficient and to produce low NOx, carbon dioxide and particulate matter emissions.