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The cavitation flow characteristics inside the micro-variable circular orifice (MVCO) fuel injector have been investigated through numerical simulations. The results show that cavitation inside the conical nozzle significantly influences the conical spray characteristics. The spray velocity loss is increased through the choked cavitation flow, and liquid spray angle and drop size is reduced by cavitation. A cavitation map has been generated by dividing the operating conditions into four regimes featuring full cavitation, partial cavitation at outlet, partial cavitation at inlet, and no cavitation respectively according to the area of cavitation inside the nozzle. We found that, in order to be in full cavitation regime, an inlet pressure at 500 bar is sufficient when the outlet pressure is less than 30 bar, where the liquid fuel can be easily atomized; however, when the outlet pressure exceeds 30 bar, the required inlet pressure jumps to 2200 bar.

This paper focuses on the spray and atomization characteristics of a Micro-Variable Circular-Orifice (MVCO) fuel injector coupled with a unique swirl adapter. Spray characteristics produced from this configuration, such as spray penetration length, spray velocity and the droplet size distribution were evaluated under different injection pressure and air inlet pressure. Diesel injection pressure ranges from 300 bar to 700 bar at a back pressure of 1bar while compressed air at pressures of 2 bar and 4 bar was supplied to the swirl adapter. High speed Mie scattering images were recorded to capture the spray evolution, as seen from both the front view and the bottom view. Phase Doppler Anemometry (PDA) measurements were conducted at different locations in the spray for the acquisition of droplet sizes and velocity distributions.

Dual loop EGR systems (having both a high pressure loop EGR and a low pressure loop EGR) have been successfully applied to multiple light-duty diesel engines to meet Tier 2 Bin 5 and Euro 5/6 emissions regulations [1, 2], including the 2009 model year VW Jetta 2.0TDI. Hyundai and Toyota also published their studies with dual loop EGR systems [3, 4]. More interest exists on the low pressure loop EGR effects on medium to heavy duty applications [5]. Since the duty cycles of light duty diesel and heavy duty diesel applications are very different, how to apply the dual loop EGR systems to heavy duty applications and understanding their limitations are less documented and published. As a specific type of heavy duty application, this paper studied the dual loop EGR effects on the retrofit applications of heavy duty diesel for delivery and drayage applications. The reduction of NOx emissions and the impact on fuel economy and controls are discussed.