The reactivity and micro-structure of three coals and two cokes used in
iron and steel manufacture have been studied by a variety of techniques,
including gas sorption analysis, thermal analysis and microscopy.
Changes in surface areas and porosities of the coals and cokes during combustion
have been determined by a gravimetric nitrogen sorption technique at
77K.
The cokes and coals have been studied by thermal analysis under isothermal
and dynamic conditions in different gas atmospheres. Rates of reaction
have been correlated with surface area changes. Attempts have been made
to calculate activation energies from Kissinger plots of DTA data.
Microstructural changes in the cokes and coals during carbon burn-off have
been investigated by electron microscopy. Relative porosities have been
estimated by image analysis. Mechanical strengths of the cokes have been
measured and correlated with porosity data.
Selected metals in the carbons have been determined by flame photometry,
atomic absorption spectroscopy and Mossbauer spectroscopy. The composition
of residual mineral matter (ash) has been investigated by X-ray diffraction.
The chemical compositions of the coal distillates have been characterised
by ir/uv spectrosopy, NMR spectroscopy and by GC-MS techniques. Calorific
values of the carbons have been determined.
Results are discussed in relation to previous work and to applications 1n
blast furnace practice. In coal combustion the surface areas increase during
the initial stages of carbon burn-off, reaching maximum at about 50% burn-off
before decreasing. The increases are considerably higher at 400° and
500° C than at 300° C for all three coals. Hysteresis data from the sorption
isotherms show that the coals develop full ranges of mesa-porosity and some
micro-porosity during burn-off at the higher temperatures.
However, the coal oxidation is only slightly accelerated, since most of
the new surface is located in the micro- and meso- pores where access to
atmospheric oxygen is restricted by slow diffusion, so that the earlier
stages of oxidation are approximately linear with time. This improves our
knowledge of current empirical industrial carbon solution tests.
There is comparatively little change in surface during the coking of the
Coals at 1000° C and only restricted sintering of the coal ashes at 300-
500° C. In the combustion of the cokes in carbon dioxide at 1000° C the maxima
in surface areas occur within 25% burn-off. However, one of the cokes shows
a second maximum at later stages of burn-off, ascribed to the European component
in the parent coal blend. This gives a more uniform rate of burn-off which
is advantageous industrially.
Date of Award | 1988 |
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Original language | English |
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Awarding Institution | |
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THE STRUCTURE AND REACTIVITY OF SOME METALLURGICAL CARBONS
Adams, K. E. (Author). 1988
Student thesis: PhD