Mathematical modeling of thermal decomposition of coal

Mathematical models are proposed to predict the true density of coal, semi-coke and coke and the porosity of a coke oven charge during carbonization. These models are combined in a further model which predicts the hitherto unexplained 'twin-peaked' contraction curve observed for semi-coke. It is fou

Published data on the specific heat of coal and coke have been analysed and have been used to define a model which predictsthe specific heat of coal during thermal decomposition. The Einstein model is used to describethevariation of specific heat with temperature and the effect of composition isdete

A mathematical model to predict the strength of a coke manufactured from a blend of coals is proposed. The model operates in terms of 'bond strengths' between the constituents. The magnitudes of these bond strengths may be determined from the strengths of cokes manufactured from the individual const

One of the main uncertainties in analysing the coking process is the path followed by thevolatile gases as they leave the oven. The objective of this study was to make a first attempt at developing a model for determining the gas flow distribution within an oven during carbonization. The model repor

The thermal decomposition of acetonitrile in the temperature range is modeled with a reaction scheme containing 23 species and 43 elementary 1350-1950 K reactions. Values of which were reported in a previous investigation {[product] /[CH CN] }/t, t 3 0 are computed with this scheme at intervals and