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Increasing the efficiency of engine auxiliary systems have become a challenge. Oil pump, identified for this study, is one such engine system which is used for lubrication of engine parts. To achieve higher efficiencies, there is a need for math-based analysis and design. This can be achieved by means of Computational Fluid Dynamics (CFD). The main aim of this paper is to simulate the flow through Gerotor Oil pump using Computational Fluid Dynamics. A 3D model of the entire flow domain is created and meshed in preprocessor GAMBIT. The mesh for various pressure outlet conditions is exported to FLUENT solver for analysis. The predicted results are validated with the experimental results. The comparison shows that the CFD predictions are in good agreement with experimental results. In particular, such a simulation offers a scope for visualizing the flow through the Gerotor oil pump.

This paper deals with the experimental investigation carried out to study the effect of expansion ratio (ER) on the brake thermal efficiency of a spark ignition ( S.I. ) engine. Intake valve closure timing (IVCT) and clearance volume have been suitably altered to achieve different ERs and compression ratios (CRs). For the modified engines the ratio of ER to CR ranges from 1:1 to 2.27:1, for CRs of 6,7, and 8:1. The results have been compared with the standard version of the engine with compression ratio of 7 and 8:1. Brake thermal efficiency improvement up to 35% has been achieved with a combination of variable IVCT (VIVCT) and variable CR (VCR) at part - load operation. Results show that in this system CR can be lowered without penalizing the thermal efficiency of the engine. Results indicate that the thermal efficiency of an Extended Expansion Engine with a CR of 6:1 and ER/CR equal to 1.5 is equal to the thermal efficiency of a standard engine with a CR of 8:1.