Abstract
Despite extensive research into alternative methods, the internal combustion engine is expected to remain as the primary source of vehicular propulsion for the foreseeable future. There are still significant opportunities for improving fuel efficiency, thus directly reducing the harmful emissions. Consequently, mitigation of thermal and frictional losses has gradually become a priority. The piston-cylinder system accounts for the major share of all the losses as well as emissions. Therefore, the need for an integrated approach, particularly of a predictive nature is essential. This paper addresses this issue, particularly the role of cylinder liner temperature, which affects both thermal and frictional performance of the piston-cylinder system. The study focuses on the top compression ring whose critical sealing function makes it a major source of frictional power loss and a critical component in guarding against further blow-by of harmful gasses. Such an integrated approach has not hitherto been reported in literature. The study shows that the cylinder liner temperature is critical in mitigating power loss as well as reducing Hydrocarbon (HC) and Nitrogen Oxide (NOx) emissions from the compression ring – cylinder liner conjunction. The results imply the existence of an optimum range for liner working temperature, independent of engine speed (at least in the studied cases) to minimise frictional losses. Combined with the study of NOx and HC emissions, the control of liner temperature can help to mitigate frictional power loss and reduce emissions.
Highlights
There are three main elements when optimising the performance of Internal Combustion (IC) engines in terms of improved energy efficiency
Higher minimum film thickness values are predicted for lower liner temperatures for most of the engine cycle, which is attributed to higher viscosity
It is concluded that working at higher temperature is beneficial for reducing oil transport to the combustion chamber, which can help in reducing lubricant evaporation within the chamber, reducing unburnt HC emissions
Summary
There are three main elements when optimising the performance of Internal Combustion (IC) engines in terms of improved energy efficiency. The parasitic losses of the cylinder system account for 4–7% of the total fuel energy [1,2,3]. Mitigating the sources of energy losses would improve fuel efficiency, which is a key driver in modern engine development. Reducing emissions such as HC, NOx and particulates is essential because of the environmental health issues, subject to a growing list of mandatory regulations and directives. These three aspects are increasingly and extensively studied
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