The Flow of Lubricant as a Mist in the Piston Assembly and Crankcase of a Fired Gasoline Engine

The tribological performance of the piston assembly of an automotive engine is highly influenced by the complex flow mechanisms that supply lubricant to the upper piston rings. As well as affecting friction and wear, the oil consumption and emissions of the engine are strongly influenced by these mechanisms. There is a significant body of work that seeks to model these flows effectively. However, these models are not able to fully describe the flow of lubricant through the piston assembly. Some experimental studies indicate that droplets of lubricant carried in the gas flows through the piston assembly may account for some of this. This work describes an investigation into the nature of lubricant misting in a fired gasoline engine. Previous work in a laboratory simulator showed that the tendency of a lubricant to form mist is dependent on the viscosity of the lubricant and the type and concentration of viscosity modifier. The higher surface area-to-volume ratio of the lubricant if more droplets are formed or if the droplets are smaller is hypothesised to increase the degradation rate of the lubricant. The key work in the investigation was to measure the size distribution of the droplets in the crankcase of a fired gasoline engine. Droplets were extracted from the crankcase and passed through a laser diffraction particle sizer. Three characteristic droplet size ranges were observed: Spray sized (250-1000 mu m); Major mist (30-250 mu m); and Minor mist (0.1-30 mu m). Higher base oil viscosity tended to reduce the proportion of mist-sized droplets. The viscoelasticity contributed by a polymeric viscosity modifier reduced the proportion of mist droplets, especially at high load.

Automated summary

The tribological performance of the piston assembly of an automotive engine is influenced by the flow mechanisms that supply lubricant to the upper piston rings. The oil consumption, emissions, and wear in engines are affected by these mechanisms. Experimental studies suggest that droplets of lubricant carried in the gas flows through the piston assembly may contribute to this. This investigation measures the droplet size distribution in the crankcase of a fired gasoline engine and finds that higher base oil viscosity and the use of a polymeric viscosity modifier can reduce the proportion of mist-sized droplets, especially at high load.