G. Delapuente et al., MODELING OF VOLATILE PRODUCT EVOLUTION IN COAL PYROLYSIS - THE ROLE OF AERIAL OXIDATION, Journal of analytical and applied pyrolysis, 44(2), 1998, pp. 205-218
Non-isothermal thermogravimetry has been applied to study the pyrolysi
s behaviour of coal and its changes as a consequence of aerial oxidati
on. A mathematical model has been developed to calculate the kinetic p
arameters of the coal pyrolysis process, which takes into account thre
e different groups of thermal decomposition reactions for fresh coal,
and two groups for oxidised coals. The agreement between the model pre
dictions, for any heating rate, and the experimental values was fairly
good. The volatile matter release profile of fresh coal can be descri
bed using three stages: Stage I (250-475 degrees C), mainly light spec
ies are liberated; Stage II (475-575 degrees C), characteristic of bit
uminous coals, high molecular weight species (tar) and hydrocarbons (p
rimary gases) are evolved, which may lead to melting (metaplast); Stag
e III (>575 degrees C), secondary gases are produced while undergoing
ring condensation and leading to the formation of coke. The decrease i
n the amount of aliphatic hydrocarbons released in the pyrolysis of ox
idised coals implies that stage II is not observed, 'mobile' phase is
insufficient to allow aromatic planar units to slide over each other,
the melting cannot begin, and oxidised coals pass directly to stage II
I. This causes loss of plasticity and is therefore, responsible for th
e degradation of coking properties, as a consequence of oxidation. The
aromatic fractions, that cannot rearrange, form a poor ordered struct
ure and yield a powdered char. (C) 1998 Elsevier Science B.V.