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In the small high speed DI diesel engines, wall quenching plays an important role on the particulate formation process. In order to clarify the particulate formation process, authors have analyzed the deposit on the combustion chamber wall, which are the results of the wall quenching. Deposit is sampled at 22 locations on the combustion chamber wall. On the wall of the piston cavity, dry and SOF deposits generate. The deposit quantity is the highest on the side surface of the cavity, but SOF ratio is the smallest in the cavity.

The mixture formation by fuel spray impingement (OSKA system) was applied to a small direct-injection diesel engine in order to reduce the wall quenching- induced emissions, i.e., the emissions of THC and soluble organic fractions (SOF). Experiments were carried out using a single-cylinder engine, fitted with various piston cavity geometries, ran under a wide range of compression ratios and fuel injection specifications. The piston cavity was designed as a centrally located reentrant type. The combination of the high squish flow and the weak penetration of the OSKA spray was very effective in reducing harmful emissions. A short ignition delay, under the retarded fuel injection timing, was obtained because of the high compression ratio. The OSKA DI diesel engine showed reduced NOx, smoke, and THC emissions without deterioration of the fuel consumption compared to modern DI diesel engines used in automotive applications.

Authors have experimented the effects of cooling water temperature on the particulate emission characteristics from a high speed DI diesel engines. A single cylinder small high speed DI diesel engine is operated under various engine speed and load conditions. Cooling water temperature is varied from 313 K (40 °C) to 363 K (90 °C). Particulate is collected using a single stage full size dilution tunnel. Dry soot and SOF emissions are measured, as well as total particulate. SOF increases when the cooling water temperature decreases, as well as HC increases. SOF also increases as load decreases. This suggests that the SOF emits at the cold starting and warming up periods. This also suggests that the SOF can be reduced by increasing cooling water temperature. IT IS IMPORTANT TO CLARIFY the effects of cooling water temperature on the particulate emission.

A new mixture formation and combustion process for reducing both emissions and fuel consumption has been developed, where the fuel impinges onto the impinging surface and spreads into the free space, named the OSKA process. A single cylinder engine particulate emission test was conducted with full flow dilution tunnel. The OSKA process shows lower TPM (total particulate matter) emission than the conventional DI diesel at the corresponding operating condition. ISF(insoluble fractions) and SOF(soluble organic fraction) are lower than DI diesel's. Correlation between SOF and THC of OSKA engine is, however different from that of conventional DI diesel. OSKA emits lower THC than conventional DI diesel does at the same SOF emission. This is because the wall quenching effect is smaller in OSKA than in conventional DI diesel. A NEW MIXTURE FORMATION and combustion technology, impinging diffusion one named OSKA, has been developed by the authors.

The effects of the spray impinging part on the in-cylinder airflow were numerically analyzed in the combustion chamber of the impinging diffusion direct injection diesel engine using KIVA-3 code. KIVA-3 code was enhanced to cater the impinging part as an internal obstacle by adopting the virtual droplet method, which is relatively easy to implement. Numerical result shows that the turbulence generation is promoted by the impinging part and is transformed by the squish flow into the piston cavity. The secondary flow is generated beneath the impinging part as well. The secondary flow area increases as the distance between top surface of the impinging part and bottom surface of the cylinder cover increases.

Wall quenching plays a vital role on particulate formation. A single cylinder engine test has been carried out to clarify the effects of wall quenching on particulate emission. A completely warmed up engine is fired in variety of operating period under various engine load, and then stopped immediately. Deposits are collected from 25 positions on the combustion chamber wall. Area basis concentration of deposit is obtained at each position. Soluble organic fractions (SOF) extracted from deposit are analyzed with gel permeation chromatograph (GPC). Results show the correlation between SOF in exhaust particulate and in deposit. Deposit concentration is highest on the spray axis impinging region of piston cavity wall. GPC pattern of the SOF in deposit indicates that higher molecular weight composition generates as a result of polymerization of fuel where the main jet region of the spray impinges.