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Particle Image Velocimetry (PIV) here has been used to measure the instantaneous velocity field within a realistic geometry motored single cylinder engine. Through-the-piston-crown illumination of a vertical plane bisecting the inlet and exhaust valves in a four valve pent roof combustion chamber and the use of a corrective optical system has for the first time allowed the velocity field in a vertical plane within a cylindrical bore to be quantified with PIV. Techniques are described which permit accurate and repeatable camera focusing, laser to engine synchronisation and seeding density control. Large scale motion observed at 180° ATDC has been interpreted as barrel swirl. Limitations of the current technique are discussed with respect to general in-cylinder applications.

The Computational Fluid Dynamics (CFD) code KIVA II has been applied to simulate the in-cylinder mean air motion (tumble) and turbulence levels in a motored 4-stroke single cylinder engine with pentroof combustion chamber geometry, having two inlet and two exhaust valves. In-cylinder flow during intake and compression strokes were simulated and a comparison between computational and experimental results were made. The mean turbulent kinetic energy and tumble ratio variation during the compression stroke obtained with CFD, have been compared with computational and experimental data from published literature. The simulation shows general similarity of flow structure and magnitude with published data on engines with similar geometry and initial flow conditions in the cylinder.