Fuel Stratification Research Articles

D132 化学発光像を用いた燃料濃度の不均質性がHCCI燃焼に及ぼす影響の調査(環境エンジン先進テクノロジー1)

D132 化学発光像を用いた燃料濃度の不均質性がHCCI燃焼に及ぼす影響の調査(環境エンジン先進テクノロジー1)

Flow optimization and fuel stratification for the stratified fuel spark ignition engine

In order to take advantage of the different properties of fuel components or fractions, a new concept of fuel stratification has been proposed by the authors. This concept requires that two fractions of standard gasoline (e.g. light and heavy fractions) or two different fuels in a specially formulated composite be introduced into the cylinder separately through two separate intake ports. The fuel stratification is realized by means of strong tumble flows in the cylinder. The detailed in-cylinder flow measurement and flow optimization in a three-valve twin-spark spark ignition (SI) engine were carried out using a digital particle image velocimetry (PIV) system. A two-tracer laser-induced fluorescence (LIF) system was developed and applied to visualize the in-cylinder fuel stratification. During the LIF measurements, two dopants, 3-pentanone and N, N-dimethylaniline (DMA), were used as fluorescence tracers when mixed into hexane and isooctane respectively. The two tracer fluorescence images were recorded simultaneously on to an intensified charge coupled device (ICCD) camera using a specially designed image doubling and filtering system. The results show that the presence of strong tumble was necessary to obtain good fuel stratification. Because of symmetrically distributed mean velocity and a small cycle-to-cycle variation of strong tumble flows, clear fuels stratification was obtained along the direction of the tumble rotational axis. It was also found that better fuel stratification was obtained when the closed valve fuel injection (injection during the exhaust stroke) was used.

Ignition and flame propagation within stratified methane-air mixtures formed by convective diffusion

The concentration changes with time and space of methane following its release into air, under the combined effects of molecular diffusion and natural convection were examined. A smooth, cylindrical, vertical flame tube of 116.0 inches (2.946 m) long and 2.5 inches (63.5 mm) inside diameter was used. The tube was separated into two sections by a plane shutter: a lower small fuel section and an upper large air section. Fuel stratification, caused mostly by convective diffusion, was initiated following the opening of the shutter. The concentration profile as a function of diffusion time at specified regions of the tube was determined by measuring the velocity of sound in the medium using a specially developed “ultra-sonic gas analyzer”. To predict the experimental concentration profile in such a system an eddy diffusivity that is a function of both the diffusion time and the local concentration gradient is needed. The range of diffusion time within which a flammable zone was developed within the stratified mixtures was determined at various locations employing a periodic spark source, for downward flame propagation. It was observed that the flammability limits of downward flame propagation within stratified methane-air mixtures were wider than those obtained for the corresponding homogeneous quiescent mixtures. Flame speeds of both accelerating and decelerating flames within stratified methane-air mixtures caused by the natural convection process were found to be higher than those encountered under homogeneous conditions at the corresponding methane concentration. Some possible reasons for the enhanced flame speeds are discussed.