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The traditional diesel engine suffers from high emission levels of nitrogen oxide and particulate matter. A new injection concept has therefore been developed and investigated. To enhance the air-fuel mixing process and avoid local concentration of fuel, the injection direction of each spray is varied during the injection event. This was achieved by rotating the injector. In this test, the rotational speed was 1700 rpm. On a six-cylinder engine, one cylinder was equipped with the new injector and exhaust gases were sampled with a new type of valve, integrated in the exhaust-valve stem of the affected cylinder. Tests show that the combustion is significantly affected by the rotating injection. The impact of the rotating injection on smoke, emissions and heat release was repeatable but dependent on loadpoint. No universal trend over all loadpoints was found. NO levels were mostly lowered but for smoke and CO, both lower and higher levels than without rotation were encountered.

The ignition dynamics of an ethanol-diesel direct injection compression ignition engine is investigated based on 3D RANS simulations. Experimental results of a previous test campaign on a single-cylinder research engine equipped with two direct injectors are used to validate the CFD model. Four reference engine conditions are considered, including split and overlapped injections of ethanol and diesel at low and high load. Combustion driven by the separate direct injection of pure ethanol and diesel as pilot fuel is simulated with AVL Fire and AVL Tabkin adopting the flamelet generated manifold combustion model. The in-cylinder pressure and apparent rate of heat release traces computed in the simulations are found to be consistent with the corresponding experimental results.