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The goal of mitigating climate change has driven research to the use of carbon-free energy sources. In this regards, green hydrogen appears as one of the best options, however, its storage remains difficult and expensive. Indeed, there is room to consider the use of ammonia (an efficient hydrogen carrier) directly as a fuel for internal combustion engines or gas turbines. Currently, there are very few works in the literature describing liquid ammonia sprays, both from experimental and modeling point of view, and especially dealing with flash-boiling conditions. In this research work, the direct injection ammonia spray is modeled with the Lagrangian particle approach, building up a numerical model within the OpenFOAM framework, for transient analyses using the U-RANS approach.

In this paper, a semi-empiric fuel spray tip penetration model is proposed. It is applied to single and double injection strategies taking into account the early and far field penetration. The model is based on the momentum flux as initially proposed by [1] for single injection but it is derived from mean mass flow rate herein. Fuel spray interaction with entrainment air is taken into account for the second injection. The proposed model is calibrated and validated using data from 9 experiments conducted with an indirect piezoelectric diesel injector under various injection strategies. The experiments included 1) injection rate measurements using the Bosch method to determine mean mass flow rate during injector opening as well as obtaining injection duration which are both entry parameters to the model; 2) Fuel spray tip penetrations were measured in a pressure vessel using high speed photography for single and double injection strategies.

Fossil fuel reserves are being depleted due to increasing energy requirements. One of the solutions is to partly replace fossil fuel by renewable biodiesel fuel. However, the physical properties of biodiesel fuels need to be thoroughly investigated before applying biodiesel or diesel-biodiesel blends in diesel engines, in order to improve the combustion efficiency. This paper presents the experimental study of diesel fuel and biodiesel blends on injection flow characteristics and fuel spray behavior. Seven fuels were tested: diesel fuel, five diesel-biodiesel blends: 10%(B10), 20%(B20), 30%(B30), 40%(B40), 50%(B50), and pure biodiesel(B100) in a diesel engine equipped with a piezo injector. Injection pressures were set at 30-180 MPa for the study of the injection flow characteristics and at 30-150 MPa for the study of spray behavior in non-vaporizing conditions.