Study of diesel-biodiesel blends combustion and emission characteristics in a CI engine by adding nanoparticles of Mn (II) supramolecular complex
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Date
2020Author
Elkelawy, M.Etaiw, S.E.-D.H.
Bastawissi, H.A.-E.
Marie, H.
Elbanna, A.
Panchal, H.
Sadasivuni, Kishor kumar
Bhargav, H.
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The supramolecular complex (SC1) [Mn(EIN)4(NCS)2] was synthesized and characterized as a new nanosized emulsion additive to improve the fuel incineration and emission formation behavior of a diesel-biodiesel blends-fueled CI engine. X-ray diffraction of one crystal, a spectroscopy technique and transmission electron microscopy (TEM) have been entirely examined for the structure formation of SC1. Adding 50, 100, and 150 ppm of SC1 with hydrogen peroxide (H2O2) is used to prepare the nanofluids emulsions. Nanosized SC1 with an average particle size of 15.25 nm is used as the heterogeneous medium for generating •OH radicals and O2 which are essential for the improvement of diesel-biodiesel blends fuel reactivity in a CI engine cylinder. Three Diesel-Biodiesel Blends with SC1 nanofluid emulsions have been prepared by blending 49% of diesel #1 fuel, 49% waste cooking oil biodiesel, 2% of SC1 nanofluid emulsion with hydrogen peroxide (H2O2) by the motorized agitator. The CI engine features are examined with all three SC1 nanofluid emulsions and the findings are discussed under separate conditions with conventional diesel and diesel-biodiesel blends. The operations of the diesel engine in the presence of SC1 nanofluid emulsions improve the thermal brake efficiency by 14.8–20.52% for diesel fuel. Furthermore, for SC1 nanofluid emulsions, CO and HC emissions are drastically decreased by 48.19–62.05% and 15.34–60.94% compared to pure diesel fuel, respectively. It is observed that the NOx emissions for all SC1 nanofluids combustion increase by 30.41–67.62% and the smoke emissions reduce by 32–44.27% as has been compared with pure Diesel.
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