Journal
MACHINES
Volume 11, Issue 2, Pages -Publisher
MDPI
DOI: 10.3390/machines11020135
Keywords
vehicle propulsion; spark ignition engine; hydrogen fueling; cycle-to-cycle variability; 0D; 1D modeling
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In this study, the conversion of a small-size passenger car to hydrogen fueling was evaluated based on achievable range and peak power. The concept was found to be feasible and comparable to a fully electric vehicle. Cylinder imbalance was identified as a possible issue compared to gasoline operation. The study also investigated the impact of cycle-to-cycle variability (CCV) on vehicle dynamics and noise-harshness-vibration (NHV), and found that hydrogen fuel can significantly improve stability while cylinder imbalance remained a main source of variability.
In the efforts to achieve zero-emission transportation, hydrogen offers a valid choice as a complete replacement of gasoline. Adapting spark ignition (SI) engines to this alternative fuel can be implemented with relatively minor changes and limited investment in added components. The conversion of a small-size passenger car to hydrogen fueling was evaluated initially from the perspective of achievable range and peak power. Overall, the concept was found to be feasible and comparable to the fully electric version of the vehicle. Cylinder imbalance was found to be one of the possible issues compared to gasoline operation. This study looks in more detail at cycle-to-cycle variability (CCV) and how this could influence vehicle dynamics as well as noise-harshness-vibration (NHV). CCV was simulated with a 0D/1D approach in vehicle-relevant engine speed-load conditions. A dedicated laminar flame speed sub-model was implemented so as to include fuel chemistry effects, while CCV was simulated by inducing perturbations in the initial combustion stages and fuel system characteristics as well as variation of air-fuel ratio throughout flame propagation. Significant improvement of stability was predicted with hydrogen, while cylinder imbalance was found to be one of the main sources of variability. Applying algorithms that compensate for the imbalance through individual injection valve regulation may not be enough to mitigate the identified issue, and more extensive changes of control strategies could be required. The start of injection settings may need to be adapted for each operating condition to maximize the effect of H-2 combustion stabilization.
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