An investigation on near-field and far-field characteristics of superheated ammonia spray

Ammonia is an attractive alternative fuel for internal combustion engines because it has an octane number above 110 and produces zero carbon oxide emissions compared to traditional fossil fuels. Due to its low boiling point, liquid ammonia is highly susceptible to flash boiling even at high ambient pressures under engine-like condi-tions. However, the characteristics of superheated ammonia spray are not fully understood due to the combined effects of bubble explosion in the near-field and strong aerodynamic interactions during its penetration process. In this study, the spray characteristics of ammonia under different fuel temperatures and ambient densities were investigated in a constant volume chamber to cover a wide range of superheat degrees. High speed diffused back-illumination method was adopted to measure both micro-and macroscopic features of ammonia spray. A non-dimensional analysis was established for the near-field characteristics to correlate critical factors to quantified bubble explosion intensity of ammonia as well as methanol and n-hexane for a comparison. It is found that both superheat degree and fuel viscosity play a significant role in the entire flashing region. For the far-field char-acteristics, the evolution of penetration is divided into three stages, and the dominant factor in each stage is investigated systematically. These experimental data would provide insightful information for understanding the breakup mechanism and developing simulation models of ammonia sprays.

Automated summary

This study investigates the spray characteristics of ammonia under different temperatures and densities, and establishes a non-dimensional analysis to quantitatively compare the key factors with bubble explosion intensity of different fuels. The results show that the superheat degree and fuel viscosity play significant roles in the spray evaporation process.