Real-fluid simulation of ammonia cavitation in a heavy-duty fuel injector

The reduction of greenhouse gases (GHG) emitted into the earth's atmosphere, such as carbon dioxide, has obviously become a priority. Replacing fossil fuels with cleaner renewable fuels (such as ammonia) in internal combustion engines for heavy-duty vehicles is one promising solution to reduce GHG emissions. This paper aims to study the cavitation formation in a heavy-duty injector using ammonia as fuel. The simulation is carried out using a fully compressible two-phase multi-component real-fluid model (RFM) developed in the CONVERGE CFD solver. In the RFM model, the thermodynamic and transport properties are stored in a table which is used during the run-time. The thermodynamic table is generated using the in-house Carnot thermodynamic library based on vapor-liquid equilibrium calculations coupled with a real-fluid equation of state. The RFM model allows to consider the effects of the dissolved non-condensable gas such as nitrogen on the phase change process. The obtained numerical results have confirmed that the model can tackle the phase transition phenomenon under the considered conditions. In contrast to previous numerical studies of the cavitation phenomenon using hydrocarbon fuels, the formed cavitation pockets were found to be primarily composed of ammonia vapor due to its high vapor pressure, with minimal contribution of the dissolved non-condensable nitrogen.Comment: 32nd European Conference on Liquid Atomization & Spray Systems, ILASS Europe, Sep 2023, Napoli, Ital