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Among industrial engines, vortex chamber diesel engines are mainly used in small engines with output of less than 19 kW, and they employ an indirect injection system in which fuel is injected into a sub-chamber called a vortex chamber. The throttle-type nozzle used in swirl-chamber diesel engines is expected to change its spraying behavior depending on ambient conditions because the pressure fluctuations in the nozzle cause the needle valve to lift, and the injection amount is controlled by the amount of lift of the needle valve. In addition, the dimensions of the vortex chamber of a vortex chamber diesel engine are smaller than the spray development distance, and wall impingement of the spray is expected. In this study, spraying and combustion experiments were conducted using a constant volume chamber to understand the behavior of the spray from a throttle-type nozzle.

A swirl-chamber diesel engine has an indirect injection system in which fuel is injected into a pre-chamber called the swirl-chamber that is separated from the main chamber. Indirect fuel injection systems can be directly mechanically controlled by the camshaft, which is cheaper than electronic control. For these reasons, they are used in diverse industrial applications and automobiles. However, optimization of the swirl-chamber shape and performance tests have been mainly experimental, and there has been insufficient verification of the accuracy of simulations. Thus, we have attempted to verify simulations using a rapid compression and expansion machine that can reproduce the combustion in one engine cycle, with a chamber like a swirl chamber in the cylinder head to visualize the behavior of evaporative sprays and the combustion process. In this study, the authors focused on the wall impingement of the fuel spray and took photos of its liquid phase and ignition.

Pre-chamber type gas engines have some merits; one is high efficiency thanks to lean combustion and the other is lower emissions such as CO2 compared to diesel engines. On the other hand, in pre-chamber type gas engines, one factor which frustrates higher efficiency is cycle-to-cycle variation of combustion. One reason why combustion variation occurs is assumed to be variation of fluid in pre-chamber. Such variation of fluid causes variation of equivalence ratio around the spark plug. It leads to unstable ignitability, and as a result, the peaks of in-cylinder pressure vary in different cycles. In order to overcome such technical problem, designing the pre-chamber shape with less cycle-to-cycle variation of combustion is needed. When designing the pre-chamber, CFD (Computational Fluid Dynamics) is a strong tool because detailed fluid history can be captured easily with CFD compared to experiments.