Litcius/Paper detail

Development of a pneumatic actuated low-pressure direct injection gas injector for hydrogen-fueled internal combustion engines

Karsten Wittek, Vitor Cogo, Geovane Prante

2022International Journal of Hydrogen Energy24 citationsDOIOpen Access PDF

Abstract

Mixture formation is one of the greatest challenges for the development of robust and efficient hydrogen-fueled internal combustion engines. In many reviews and research papers, authors pointed out that direct injection (DI) has noteworthy advantages over a port fuel injection (PFI), such as higher power output, higher efficiency, the possibility of mixture stratification to control NOx-formation and reduce heat losses and above all to mitigate combustion abnormalities such as back-firing and pre-ignitions. When considering pressurized gas tanks for on-vehicle hydrogen storage, a low-pressure (LP) injection system is advantageous since the tank capacity can be better exploited accordingly. The low gas density upstream of the injector requires cross-sectional areas far larger than any other injectors for direct injection in today's gasoline or diesel engines. The injector design proposed in this work consists of a flat valve seat to enable the achievement of lifetime requirements in heavy-duty applications. The gas supply pressure is used as the energy source for the actuation of the valve plate by means of a pneumatic actuator. This article describes the design and the performed tests carried out to prove the concept readiness of the new LP-DI-injector.

Topics & Concepts

InjectorFuel injectionGasoline direct injectionAutomotive engineeringCombustionInternal combustion engineCabin pressurizationGasolineDiesel fuelEnvironmental scienceNuclear engineeringMechanical engineeringEngineeringWaste managementChemistryOrganic chemistryAdvanced Combustion Engine TechnologiesVehicle emissions and performanceElectric and Hybrid Vehicle Technologies