Spray-turbulence-chemistry interactions under engine-like conditions

Turbulent multiphase combustion plays an important role in both nature (e.g., volcanos and pool fires) and industry (e.g., industrial furnaces, aeroengines, and internal combustion engines). It is a highly complex multiscale and multi-physicochemical process in which interactions between the dispersed and continuous phases, phase change, droplet collisions, evaporation, mixing, heat transfer, and chemical reactions occur simultaneously. In recent years, significant progress has been made in understanding the mechanisms of spray flames and their behaviors in combustion engines. This paper covers key and representative developments in the area of turbulent spray combustion with a focus on spray-chemistry-turbulence interactions. The effects of turbulence-chemistry, spray-turbulence, and spray-chemistry interactions on the spray process, ignition, flame stabilization and emission are comprehensively discussed at elevated pressures and temperatures. Furthermore, spray-radiation and spray flame-wall interactions, which are important to engine performance and emission characteristics, are scrutinized. Supercritical spray flames and turbulent spray flames in dual-fuel engines are also discussed. Finally, outlooks and further challenges for the research field are outlined.

Automated summary

Turbulent multiphase combustion is a highly complex process involving interactions between dispersed and continuous phases, phase change, droplet collisions, evaporation, mixing, heat transfer, and chemical reactions, and plays a key role in spray combustion.