Characterization of high temperature optical spectra of glass melts and modeling of thermal radiation conductivity

Two innovative experimental techniques for measuring the high temperature near infrared optical spectra of glass melts are compared. The critical experimental features of both techniques, one based on transmission and the other based on emittance measurements, are reviewed. Typical results of both t...

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Published inInternational journal of applied glass science Vol. 11; no. 3; pp. 442 - 462
Main Authors Faber, Anne‐Jans, Rongen, Mathi, Lankhorst, Adriaan, Meneses, Domingos De Sousa
Format Journal Article
LanguageEnglish
Published Westerville Wiley Subscription Services, Inc 01.07.2020
Subjects
Absorptivity
Chemical analysis
Chromium oxides
color< optical properties
Conductivity
Emittance
Empirical analysis
Glass
glass forming melts< properties
High temperature
Infrared spectra
Iron oxides
Lime
Melts
Near infrared radiation
Temperature dependence
thermal conductivity< glass forming melts
Thermal radiation
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Summary:Two innovative experimental techniques for measuring the high temperature near infrared optical spectra of glass melts are compared. The critical experimental features of both techniques, one based on transmission and the other based on emittance measurements, are reviewed. Typical results of both techniques, including high temperature spectra and values for the Rosseland mean absorption coefficient and thermal radiation conductivity versus temperature for similar glass melts, are compared. The study is focused on sulfate fined soda lime silicate glass melts colored with iron oxide and chromium oxide and on the effect of the glass redox state on the thermal radiation conductivity. It is shown that essentially different measuring principles provide consistent results for similar glass melt types, that is, colors. Using the high temperature spectra of a large variety of (colored) glasses, a new semi‐empirical model is developed for predicting the Rosseland radiation conductivity of arbitrary sulfate fined soda lime silicate glass melts, colored with iron oxide and chromium oxide. By separating the effects of (a) the temperature‐dependent redox state, (b) the high temperature changes in ligand field strengths and (c) the glass matrix, the model reliably predicts the Rosseland radiation conductivity, with a chemical analysis of the glass as input only.
ISSN:2041-1286
2041-1294
DOI:10.1111/ijag.15111