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In this study, an attempt has been made to estimate trapping efficiency of a two-stroke engine by CFD analysis under cold flow conditions. A single-cylinder, loop-scavenged, spark-ignition, two-stroke engine extensively used for two-wheeler application in India is being considered for the analysis. Engine geometry is modeled using commercial PRO-E software. Simulation is carried out using commercial CFD code STAR-CD. The CFD predictions are validated by available experimental data. In the present study, the trapping efficiency is estimated at various engine speeds with change in configurations of ports. From the analysis of results, it is found that, increasing exhaust port area relative to total transfer port area and engine speeds increase the trapping efficiency significantly. In general, it is possible to increase the trapping efficiency by about 4% at the engine speeds considered.

This paper deals with in-cylinder flow field analysis in a motored two-stroke engine by CFD technique using STAR-CD. The main aim of this study is to find out the best turbulence model which predicts the fluid flow field inside the cylinder of a two-stroke engine. In this study, a single-cylinder, two-stroke engine which is very commonly used for two-wheeler application in India is considered. Entire analysis is done at an engine speed of 1500 rev/min. under motoring conditions. Here, three commonly used turbulence models viz. standard k-ε, Chen k-ε and RNG k-ε are considered. In addition, experiments were also conducted on the above engine at the motoring conditions to measure velocity vectors of in-cylinder flow fields using particle image velocimetry (PIV). The results of PIV were also used for validating the CFD predictions.

Short-circuiting of the fuel air mixture during scavenging is the main reason for high fuel consumption and hydrocarbon (HC) emissions in two-stroke SI engines. Though direct injection of the fuel after the closure of ports has advantages, it is costly and complex. In this work, in a 2S-SI, single cylinder, automotive engine, LPG (liquefied Petroleum Gas) was injected through the boost port to reduce short-circuiting losses. A fuel injector was located on one of the boost ports and the air alone was fed through the other transfer and boost ports for scavenging. Experiments were done at 25% and 70% throttle openings with different injection timings and optimal spark timing at 3000 rpm. Boost port injection (BPI) of LPG reduced HC emissions at all conditions as compared to LPG-MI (Manifold Injection). Particularly significant reductions were seen at high throttle conditions and rich mixtures. HC reductions with BPI were 19% and 25% as compared to LPG-MI and gasoline-MI respectively.

This experimental study was aimed at improving a two-stroke S.I engine by injecting gasoline with air assistance through the cylinder barrel. Experimentally obtained performance and emission parameters of the engine at 25% and 100% throttle positions were analyzed at 3000 rpm. The timing of air assisted injection was optimized at 25% throttle and 3000 rpm. The performance and emissions of the engine were compared with those obtained with an optimized manifold injection system. In all cases the best spark timing was used. At 25% throttle although the thermal efficiency was increased only slightly, there was a significant reduction in HC emissions to 6.63 g/kW-h with cylinder barrel injection from 10.69 g/kW-h with manifold injection due to reduced short circuiting of the fuel. There was a reduction in NO emissions as well with cylinder barrel injection. Comparisons were made at the point of highest thermal efficiency at 100% throttle also.

Direct injection of fuel has been seen as a potential method to reduce fuel short circuiting in two stroke engines. However, most work has been on low pressure injection. In this work, which employed high pressure direct injection in a small two stroke engine (2S-GDI), a detailed study of injection parameters affecting performance and combustion has been presented based on experiments for evaluating its potential. Influences of injection pressure (IP), injection timing (end of injection - EOI) and location of the spark plug at different operating conditions in a 199.3 cm3 automotive two stroke engine using a real time open engine controller were studied. Experiments were conducted at different throttle positions and equivalence ratios at a speed of 3000 rpm with various sets of injection parameters and spark plug locations. The same engine was also run in the manifold injection (2S-MI) mode under similar conditions for comparison.