Abstract
The injection process of diesel engines influences the pollutant emissions. The spray formation is significantly influenced by the internal flow of the injector. One of the key parameters here is the generation of cavitation caused by the geometry and the needle lift.In modern diesel engines the injection pressure is established up to 3000 bar. The details of the flow and phase change processes inside the injector are of increasing importance for such injectors. With these experimental measurements the validation of multiphase and cavitation models is possible for the high pressure range. Here, for instance, cavitation effects can occur. Cavitation effects in the injection port area destabilize the emergent fuel jet and improve the jet break-up.The design of the injection system in direct-injection diesel engines is an important challenge, as the jet breakup, the atomization and the mixture formation in the combustion chamber are closely linked. These factors have a direct impact on emissions, fuel consumption and performance of an engine. The shape of the spray at the outlet is determined by the internal flow of the nozzle. Here, geometrical parameters, the injection pressure, the injection duration and the cavitation phenomena play a major role.In this work, the flow dependency in the nozzles are analysed with the Neutron-Imaging. The great advantage of this method is the penetrability of the steel structure while a high contrast to the fuel is given due to the interaction of the neutrons with the hydrogen amount. Compared to other methods (optical with glass structures) we can apply real components under highest pressure conditions. During the steady state phase of the injection various cavitation phenomena are visible in the injector, being influenced by the nozzle geometry and the fuel pressure. Different characteristics of cavitation in the sac and spray hole can be detected, and the spray formation in the primary breakup zone is influenced.
Highlights
The relationship of the internal nozzle flow and the primary break up is important for combustion process
There have to many physical processes, such as the momentum exchange between liquid phase and gas phase turbulence in the liquid phase and in the gas phase, transient heat transfer, boiling behaviour, surface tension effects, cavitation etc. are included (Figure 1) [1]
The liquid fuel is through the injection ports with speeds exceeding 500 m / s is injected into the combustion chamber
Summary
- LES of cavitating flow inside a Diesel injector including dynamic needle movement F Örley, S Hickel, S J Schmidt et al. - Visualisation of high temperature magnetisation states in magnetite grains using off-axis electron holography T P Almeida, A R Muxworthy, A Kovács et al
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