Investigations into the air heater ash deposit formation in large scale pulverised coal fired boiler

•Mineralogical and chemical analysis provided valuable insights into precursors of ash deposits.•Dew point calculations reveal that temperature could be another contributing factor for deposition on air heater sections.•No reported information on air heater deposits and mineralogy in the literature....

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Bibliographic Details
Published in:Fuel (Guildford) 2015-01, Vol.140, p.27-33
Main Authors: Vuthaluru, Hari B., H. French, David
Format: Article
Language:English
Subjects:
Air heater
Ash
Boiler
Deposition
Sulphate
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Summary:•Mineralogical and chemical analysis provided valuable insights into precursors of ash deposits.•Dew point calculations reveal that temperature could be another contributing factor for deposition on air heater sections.•No reported information on air heater deposits and mineralogy in the literature.•Current study indicate that large temperature fluctuations are a significant factor in deposit formation. A mineralogical study was undertaken of air heater deposits in a 300MWe pf boiler located in Western Australia in order to understand deposit formation in the air heater sections of the boiler as an aid to implement possible remediation actions. Several air heater deposit samples were collected in the selected regions of the air heater along with samples of the feed coal, bottom ash and fly ash for comparison of ash chemistry and mineralogy. The deposit samples were examined using a combination of ash chemistry and quantitative X-ray diffraction analysis; the ash samples by bulk chemical analysis to determine the major element chemistry and mineralogy by quantitative X-ray diffraction. Chemical and mineralogical analysis showed that the deposits are unusual in containing high amounts of sulphate, particularly of aluminium and, to a lesser extent, iron. From the analyses it appears that the formation of the deposits is due to the high sulphate content which is acting as a cementing agent. There is an indication that temperature could be another factor in formation of the deposits, with a decrease in temperature leading to the formation of sulphurous acid which then reacts with the reactive glassy amorphous fly ash phase to form the aluminium and iron sulphates. Dew point calculations indicated that this is a possible deposit formation mechanism based upon the air heater temperature data obtained from the utility. There was no evidence that unburnt carbon has played a significant role in deposit formation. Large temperature fluctuations resulting from the inherent nature of the operation of the air heater are a significant factor in deposit formation and a practical solution to consider would be the use of an SO2 absorbent placed prior to the air heater.
ISSN:0016-2361
1873-7153
DOI:10.1016/j.fuel.2014.09.040