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Rheological measurements were performed on a series of lubricants for flexible fuel vehicles, and blends of water or methanol in these oils. A series of measurements, including kinematic viscosity, viscosity at low and high shear rates, low shear viscosity under borderline pumping conditions, and density were performed on all oils and blends. The effects of mixing conditions, such as mixing speed and temperature on these properties were also studied. Viscosity increases when water emulsifies in oils. Methanol exhibits limited solubility in all oils, but more so in synthetic base oils. Viscosity tests at 248 K (-25°C) do not indicate the onset of critical pumping conditions, even at high concentrations of water or methanol. Tests at high shear rates at 323 K (50°C) suggest that water-oil emulsions are quite stable, while methanol-oil blends lose their methanol content either due to evaporation or shear-induced separation.

A single cylinder indirect injection diesel engine was used to evaluate the emissions, fuel consumption, and ignition delay of non-petroleum liquid fuels derived from coal, shale, and tar sands. Correlations were made relating fuel properties with exhaust emissions, fuel consumption, and ignition delay. The results of the correlation study showed that the indicated fuel consumption, ignition delay, and CO emissions significantly correlated with the H/C ratio, specific gravity, heat of combustion, aromatics and saturates content, and cetane number, Multiple fuel properties were necessary to correlate the hydrocarbon emissions. The NOx emissions did not correlate well with any fuel property. Because these fuels from various resources were able to correlate succesfully with many of the fuel properties suggests that the degree of refinement or the chemical composition of the fuel is a better predictor of its performance than its resource.

A 98-hour sequence test has been developed to study the wear of Ford OHC 2.3L methanol fueled engines. This test requires only half the test time of an ASTM Sequence V-D test used by many researchers, and yet provides sufficient severity to generate measurable bore wear to discriminate engine hardware changes. A portable fixture was designed to provide rapid, convenient, and accurate measurement of radial bore wear at a prescribed depth in the cylinder. The fixture can measure radial bore wear with accuracies to 0.004 mm. Its portability allows on-site measurement of engines on dynamometer test stands, or in vehicles with minimal engine disassembly. The test procedure and measurement fixture were used to quantitatively document the ring and bore wear effects of numerous variables, such as fuels, fully formulated lubricants, top ring configurations, coolant temperatures and flow patterns, intake heat addition, and fuel contamination.