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The nature of autoignition and knocking is investigated experimentally and theoretically in an optical engine by high speed direct light photography and laser schlieren filming. Special emphasis is devoted experimentally and theoretically to the role of exothermic centres in the end-gas in initiating knocking combustion and subsequent knock damage to the combustion chamber walls. The optical engine is a modified single cylinder ported two stroke engine equipped with a large head window for unlimited access to both the entire combustion chamber and the ring crevice region. In some experiments the formation of exothermic centres was stimulated by microscopic aluminium particles that deposited on the mirrored piston surface. The data are analysed by numerically modelling the transition from normal combustion to autoignition with a simplified 2D-code.

For studying the effects of injection system properties and combustion chamber conditions on the penetration lengths of both the liquid and the vapor phase of fuel injectors in Diesel engines, a holistic injection model was developed, combining hydraulic and spray modeling into one integrated simulation tool. The hydraulic system is modeled by using ISIS (Interactive Simulation of Interdisciplinary Systems), a one dimensional in–house code simulating the fuel flow through hydraulic systems. The computed outflow conditions at the nozzle exit, e.g. the dynamic flow rate and the corresponding fuel pressure, are used to link the hydraulic model to a quasi–dimensional spray model. The quasi–dimensional spray model uses semi–empirical 1D correlation functions to calculate spray angle, droplet history and droplet motion as well as penetration lengths of the liquid and the vapor phases. For incorporating droplet vaporization, a single droplet approach has been used.

1 A recent breakthrough in understanding the origin of ion signals from operating combustion engines [12] led to a new approach in integrating advanced ion current sensing into a compact ignition system. Thus it is now possible to continuously monitor mixture, ignition and combustion properties through online ion current recordings via a novel AC technique. In this paper this AC technique is compared to the standard DC technique and its known drawbacks: expensive high voltage components, sensitivity to plug fouling and expensive electronics. The AC technique is based on the specific properties of the electrical field of spark plugs being characterized by a point source with an extreme inhomogeneity of the electrical field due to the small center electrode. This causes a distinct diode characteristic of the ion signal: very low signals for negative voltages and high signals for positive ion sensing voltages, respectively.