Factors affecting coal particle ignition under oxyfuel combustion atmospheres

C. K. Man*, J. R. Gibbins

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

Abstract

A set of 13 coals of different rank has been tested for ignition propensity in a 20-L explosion chamber simulating oxyfuel combustion gas conditions. Their char residues were also analysed thermogravimetrically. The effects of coal type, coal concentration (from 100 to 600 g/m(3)), O(2) in CO(2) atmospheres (up to 40% v/v) and particle size were investigated.

The higher rank coals were significantly more difficult to ignite and mostly required higher energy chemical igniters (1000 or 2500 J) whereas the lower rank coals could be ignited with a 500 J igniter even at low coal dust concentrations.

The minimum explosibility limit/ignition concentration in air varied slightly around a value of 200 g/m(3), a little higher for low volatile coals and a little lower for high volatile coals.

The ignition limit changed significantly, however, with O(2) concentration in CO(2), where coals required more oxygen to ignite. Most coals failed to ignite at all in 21% v/v O(2) in CO(2), but an increase to 30 or 35% v/v O(2) gave ignition patterns similar to those in air. In addition, the minimum ignition concentration decreased with increase in O(2). However, a further increase to 40% v/v O(2) did not generally affect the minimum ignition concentration.

Particle size had a non-linear effect on coal ignition. The fine particles (53 mu m) was generally more difficult to ignite and exhibited a much lower weight loss. Published by Elsevier Ltd.

Original languageEnglish
Pages (from-to)294-304
Number of pages11
JournalFuel
Volume90
Issue number1
DOIs
Publication statusPublished - Jan 2011

Keywords

  • DUST EXPLOSIBILITY
  • Carbon capture
  • Deflagration
  • CO(2)
  • Coal ignition
  • CO2
  • Oxyfuel combustion

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