Abstract
The self-learning capabilities of artificial neural networks (ANNs) from large datasets have led to their deployment in the prediction of various physical and chemical phenomena. In the present work, an ANN model was developed to predict the yield sooting index (YSI) of oxygenated fuels using the functional group approach. A total of 265 pure compounds comprising six chemical classes, namely paraffins (n and iso), olefins, naphthenes, aromatics, alcohols, and ethers, were dis-assembled into eight constituent functional groups, namely paraffinic CH3 groups, paraffinic CH2 groups, paraffinic CH groups, olefinic –CH=CH2 groups, naphthenic CH-CH2 groups, aromatic C-CH groups, alcoholic OH groups, and ether O groups. These functional groups, in addition to molecular weight and branching index, were used as inputs to develop the ANN model. A neural network with two hidden layers was used to train the model using the Levenberg–Marquardt (ML) training algorithm. The developed model was tested with 15% of the random unseen data points. A regression coefficient (R2) of 0.99 was obtained when the experimental values were compared with the predicted YSI values from the test set. An average error of 3.4% was obtained, which is less than the experimental uncertainty associated with most reported YSI measurements. The developed model can be used for YSI prediction of hydrocarbon fuels containing alcohol and ether-based oxygenates as additives with a high degree of accuracy.
Highlights
Carbonaceous particles known as soot, which are formed and emitted during the incomplete combustion of fossil fuels, have a negative impact on human health and the environment
Studies [5] have shown that limiting the emissions of particulate matter (PM) from fossil fuel combustion can be one of the most effective ways of slowing the rate of global warming, and a net 20–45% reduction in global warming can be realized by eliminating PM emissions
Soot emitted from internal combustion (IC) engines has a short lifetime of around a week and the positive impact of net soot reduction can be realized quickly
Summary
Carbonaceous particles known as soot, which are formed and emitted during the incomplete combustion of fossil fuels, have a negative impact on human health and the environment. The objective of the present work was to develop an artificial neural network (ANN)based model using the unified YSI database [27] that can predict the YSI of pure compounds and real fuels, containing the following chemical classes: paraffins (n and iso), olefins, naphthenes, aromatics, alcohols, and ethers. BI represents the degree of branching in a compound, in which both the size and position of the side chains are taken into account while computing the value This parameter helps to distinguish isomers (for example, 2-methyl heptane and 3methyl heptane) that have the same functional group distribution but have slightly different combustion properties, such as DCN, octane number, TSI, and YSI.
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