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Transient liquid and vapor penetration of diesel sprays is numerically investigated for conditions corresponding to early-injection timings; this injection approach can be followed since it allows sufficient fuel-ambient mixing avoiding NO and soot-forming combustion. Model validation takes place against experimental data available for injection into an optically accessible constant volume chamber using a single-hole injector nozzle. A parametric analysis on the effect of ambient temperature and density, injection duration, multiple injection strategy and nozzle hole diameter is performed to enlighten the development of the injected sprays for various early-injection strategies. The model is found to predict reasonably well the experimental trends both for steady-state and transient injection events.

The development of diesel sprays at late-cycle post-injection conditions is numerically investigated using a dense-particle Eulerian-Lagrangian stochastic methodology. Model validation takes place against experimental data available for injection into an optically accessible constant volume chamber using a single-hole injector nozzle. A parametric analysis on the effect of ambient temperature and density, injection duration and multiple injection strategy is performed to enlighten the development of the injected sprays for various post-injection strategies, with densities in the range of 1.2 - 3 kg/m₃ and temperature in the range of 800 - 1400 K.

Computational models widely employed for predicting the dispersion of fuel sprays in combustion engines suffer from well-known drawbacks associated with the utilization of case-dependent empirical phase-change models, describing the conversion of liquid into vapour during fuel injection. The present work couples the compressible Navier-Stokes and energy conservation equations with a thermodynamic closure approximation covering pressures from 25 to 2000bar and temperatures that expand from compressed liquid, vapor-liquid equilibrium to trans/supercritical mixing, and thus, cover the whole range of P-T values that diesel fuel undergoes during its injection into combustion engines. The model assumes mechanical and thermal equilibrium between the liquid, vapour and surrounding air phases and thus, it avoids utilization of case-dependent empirical phase-change models for predicting in-nozzle cavitation and vaporization of fuels.

Optimization of geometric and operating parameters controlling the fuel injection rate of in-line pump-based fuel injection system for small-sized industrial DI diesel engines can be obtained using computer models simulating simultaneously the flow inside the fuel injection system and the subsequent spray development. Empirical sub-models accounting for the effect of injection hole cavitation both on hole exit velocity and on the atomization of the injected liquid have been included in order to enhance model predictions. Validation of the FIE model s performed by comparing model predictions against experimental data for the pumping chamber pressure, delivery valve lift, line pressure, needle lift and injection rate for various pump designs and for a wide range of pump operating conditions. The results confirm that the FIE simulation model is capable of predicting the flow characteristics inside the fuel injection system for all cases investigated.