Abstract
The top compression ring design of an internal combustion engine has an impact on ring in-plane motion and its lubrication conditions at the ring-cylinder liner contact. In this paper, the geometrical dimensions of the top compression piston ring-cylinder system were obtained from an actual four-stroke motorbike engine. The top ring tribological behaviour was characterized by a Computational Fluid Dynamics (CFD) simulation including the effects of asperity contact. Based on the numerical solution of the Navier–Stokes equations and taking into account realistic engine running conditions, the effect of the in-plane top ring motion in quasi-static equilibrium was determined. The simulation model was validated by the numerical and experimental results of similar investigations of other researchers. Good predictions were achieved by solving the Navier-Stokes equations because the pressure gradient into the lubricant film was accounted for. The effects of ring curvature at the ends of the stroke were studied. The results show that a flatter ring profile has a sufficient minimum lubricant thickness at reversal points, showing reasonably lower boundary friction than that of the higher curvature. Higher heights of the curvature profile promote significantly mixed lubrication, in which the power losses and the burning of excess lubricating oil are increased. The proposed simulation model can be expanded to any set of compression rings where a minimum simulation time is required.
Highlights
A desirable top compression ring profile could lead to good sealing performance with low frictional power loss and better oil consumption
The top compression ring contribution to ring pack performance has increased from 13% in the 1980s to 27% recently [1]
The total friction force along the top compression ring significantly contributes to the frictional losses of the engine
Summary
A desirable top compression ring profile could lead to good sealing performance with low frictional power loss and better oil consumption. In reference [12], they provided a solution for the isothermal mixed hydrodynamic conjunction of the compression ring to cylinder liner, and they investigated the effects of the compression ring axial profile along its face-width and topography of contiguous solids Another important feature of their analysis was the development of a control volume thermal mixing model [13], showing that the temperature of the liner is the determining factor for lubricant temperature in the contact. Styles et al [15] studied a boundary and mixed lubrication model by considering the coating surface effects in detail Their analysis took into account the friction of the top compression ring of a high-performance V12 Aston Martin engine. A 2D axisymmetric CFD model is developed to study the performance of top compression piston rings in mixed lubrication conditions. The variation in frictional power loss with compression ring profile is investigated
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