An experimental study of the effects of fuel properties on diesel spray processes using blends of single-component fuels

Resumen

This last few years, the trend in diesel engines has been to use different kinds of fuels to identify their influence and behaviour on the emissions and performance. Among the wide variety of fuels employed are the so called Primary Reference Fuels (PRFs), which represent the behaviour of diesel and gasoline in terms of ignition properties, as they are located at both ends of the octane rating scale and also have very different cetane numbers. One of the disadvantages of using pure gasoline or diesel-gasoline blends in diesel engines is the time needed for the mixture to ignite and to completely burn the fuel. This generally requires working with partial loads or with premixed charges. In order to isolate the fuel effects on the spray processes and to be able to study the characteristic parameters of ignition delay time, lift-off length, vapour and liquid penetration, among others; different experiments under parametric variations of diesel like conditions have been performed. The tests were performed under inert and reactive conditions in a 2-stroke optical engine and a constant-pressure flow (CPF) high-pressure high-temperature vessel using single-hole nozzles, while diverse optical techniques were being employed. To study the influence of the fuel properties, different single-component fuels were employed as well as binary blends and a six-component diesel surrogate, which was also compared to conventional diesel. Additionally, the results have been contrasted with a one-dimensional model in order to further explain the values and trends found. The results presented a strong dependency on the fuel properties for the tests performed under inert and reactive conditions. The difference in physical properties of n-decane and n-hexadecane showed an almost linear reduction of the stabilized liquid penetration down to approximately 60% under some conditions. Additionally, due to the composition of the surrogate fuel, pure n-hexadecane was demonstrated to have almost identical evaporation characteristics, hence proving itself as a good candidate for a single-component surrogate of diesel fuel. In a similar way, the chemical properties of the PRFs n-heptane and iso-octane also proved to be influential on the spray development and radiation emitted. Ignition delay values up to one order of magnitude larger where obtained for both extremes of the blend range, as well as lift-off lengths up to three times longer. The radiation emitted by the soot incandescence presented the highest variations, as some conditions showed a reduction of almost four orders of magnitude among the blend range. Moreover, some cases did not present any radiation corresponding to the soot, and increasing the sensitivity of the camera only caused the chemiluminescence of the OH* radical to be captured. On a different way, the stabilized flame length determined also by the soot radiation did not present much variation as the fuel properties or the air temperature were changed; in fact, the only noticeable differences were caused by the changes in the oxygen composition of the ambient air. In conclusion, the fuel properties proved to have a significant effect on the spray processes. Lighter fuels favoured the evaporation of the spray under a range of conditions, while fuels with lower octane numbers ignited sooner and closer to the spray tip but with more soot luminosity measured.