Abstract
<div class="section abstract"><div class="htmlview paragraph">Heavy duty hydrogen (H<sub>2</sub>) internal combustion engines (ICEs), typically conversions from base diesel engines, can experience significant deterioration of combustion efficiency with enleanment despite relative engine stability due in part to non-optimized combustion chamber geometry for spark ignited (SI) combustion. This causes un-combusted H<sub>2</sub> to “slip” into the exhaust largely undetected since it is not a typically measured exhaust species. In this study, several implications of H<sub>2</sub> slip in H<sub>2</sub> ICEs are explored. The sensitivity of air fuel ratio (AFR) measurement to H<sub>2</sub> slip is discussed. The challenge this poses for closed-loop transient controls and the impact on nitrogen oxides (NOx) emissions are also shown. Finally, test results from an H<sub>2</sub> ICE using an active pre-chamber highlight the improvement in combustion efficiency and transient stability relative to a baseline SI engine.</div></div>
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