Foaming during nuclear waste melter feeds conversion to glass: Application of evolved gas analysis

During the final stages of batch‐to‐glass conversion in a waste‐glass melter, gases evolving in the cold cap produce primary foam, the formation and collapse of which control the glass production rate via its effect on heat transfer to the reacting batch. We performed quantitative evolved gas analys...

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Bibliographic Details
Published in:International journal of applied glass science 2018-10, Vol.9 (4), p.487-498
Main Authors: Hujova, Miroslava, Pokorny, Richard, Klouzek, Jaroslav, Lee, Seungmin, Traverso, Joseph J., Schweiger, Michael J., Kruger, Albert A., Hrma, Pavel
Format: Article
Language:English
Subjects:
Atmospheric models
Carbonates
Chemical evolution
Cold
Conversion
Decomposition reactions
evolved gas analysis
feed‐to‐glass conversion
Foaming
Gas analysis
Gas evolution
Gases
Glass
Heating rate
Nitrogen dioxide
Porosity
Radioactive wastes
Residual gas
Visual observation
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Summary:During the final stages of batch‐to‐glass conversion in a waste‐glass melter, gases evolving in the cold cap produce primary foam, the formation and collapse of which control the glass production rate via its effect on heat transfer to the reacting batch. We performed quantitative evolved gas analysis (EGA) for several HLW melter feeds with temperatures ranging from 100 to 1150°C, the whole temperature span in a cold cap. EGA results were supplemented with visual observation of batch‐to‐glass transition using the feed expansion tests. Upon heating, most of the gases—mainly H2O, CO2, NO, NO2, N2, and O2—evolve at temperatures below 700°C and escape directly to the atmosphere through open porosity. However, as open porosity closes when enough glass‐forming melt appears at ~720°C, the residual gas evolution leads to the formation of primary foam. We found that primary foaming is mostly caused by the decomposition of residual carbonates, though oxygen evolution from iron‐redox reaction can also play a role. We also show that the gas evolution shifts to a higher temperature when the heating rate increases. The implications for the mathematical modeling of foam layer in the cold cap are presented.
ISSN:2041-1286
2041-1294
DOI:10.1111/ijag.12353