Feasible route towards decarbonising marine transport with flexible, hydrogen – enriched, reactivity controlled compression ignition mid-speed engines

Hydrogen (H₂) admixing in Reactivity Controlled Compression Ignition (RCCI) technology engines is touted to enhance indicated efficiency (ITE>50%), optimize combustion and reduce greenhouse gas emissions. However, many pending issues remain regarding engine durability, nitrogen oxide (NO_X) emissions and blending limits. These issues are addressed by employing a novel performance-oriented model which simulates under 3 min, combustion physics with similar predictivity (>95% accuracy) as computational fluid dynamic results. This so-called multizone model is parameterized to real-world operating cycles from a dual-fuel mid-speed marine engine. By considering port-fuel injected H₂, the simulations show that combustion phasing advances at an average rate of 0.3⁰CA/% H₂, accompanied by a peak reduction in methane slip of 80% achievable at 25% H₂ energy share. Also, engine control oriented issues are addressed by demonstrating either intake temperature or diesel fuel share optimization to negate the drawbacks of combustion harshness and NO_X emissions, while improving ITE 1–1.5pp over baseline operation.