Journal
INTERNATIONAL JOURNAL OF ENERGY RESEARCH
Volume 46, Issue 11, Pages 15347-15361Publisher
WILEY
DOI: 10.1002/er.8235
Keywords
ammonia; biodiesel; CI engine; dual fuel; emissions
Categories
Funding
- AVL List [NOR/POLNOR/ACTIVATE/0046/2019-00]
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This study investigates the use of ammonia as a primary fuel with biodiesel in a dual-fuel mode. The results show that up to 69.4% of the input energy can be provided by ammonia, but increasing the ammonia mass flow rate slightly decreases the brake thermal efficiency. Furthermore, increasing the ammonia load contribution significantly reduces CO2, CO, and HC emissions, but increases NO emissions. Ammonia delays the start of combustion and decreases the combustion duration compared to pure biodiesel operation.
Ammonia is a promising alternative fuel that can replace current fossil fuels. Hydrogen carrier, zero carbon base emissions, liquid unlike hydrogen, and can be produced using renewable resources, making ammonia a future green fuel for the internal combustion engine. This study aims to show the procedure of utilizing ammonia as a primary fuel with biodiesel in a dual-fuel mode. Hence, a single-cylinder diesel engine was retrofitted to inject ammonia into the intake manifold, and then a pilot dose of biodiesel is sprayed into the cylinder to initiate combustion of the premixed ammonia-air mixture. The effects of various ammonia mass flow rates with a constant biodiesel dose on engine performance and emissions were investigated. Furthermore, a one-dimensional model has been developed to analyze the combustion of ammonia and biodiesel. The results reveal that 69.4% of the biodiesel input energy can be replaced by ammonia but increasing the ammonia mass flow rate slightly decreases the brake thermal efficiency. Moreover, increasing the ammonia load contribution significantly reduced the emissions of CO2, CO, and HC but increased the emission of NO. It was found that ammonia delayed the start of combustion by 2.6CAD compared with pure biodiesel due to the low in-cylinder temperature and the high resistance of ammonia to autoignition. However, the combustion duration of biodiesel/ammonia decreased 19CAD compared with only biodiesel operation at full load, since most of the heat was released during the premixed combustion phase. Highlights Ammonia biodiesel dual-fuel CI engine has been investigated experimentally. Maximum 69.4% of the input energy is provided by ammonia in reasonable operation. Higher ammonia contribution in the engine load delays the SOC and decreases the combustion duration. Significant reduction in CO2, CO, and HC emissions in the ammonia-/biodiesel-fueled engine.
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