Differences in the Corrosive Spalling Behavior of Alumina-Rich Castables: Microstructural and Crystallographic Considerations of Alumina and Calcium Aluminate Matrices

Differences in the Corrosive Spalling Behavior of Alumina-Rich Castables: Microstructural and Crystallographic Considerations of Alumina and Calcium Aluminate Matrices

The energy transition from the incineration and gasification of fossil fuels to the incineration and gasification of biomass refractory linings is being held up by a severe corrosion issue, caused by high alkali contents and the wide variety of biomass sources. Incinerators optimized for fossil fuel...

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Main Authors: Lise Loison, Mouna Sassi, Thorsten Tonnesen, Emmanuel De Bilbao, Rainer Telle, Jacques Poirier
Format: Article
Language:English
Published: MDPI AG 2020-05-01
Series:Ceramics
Subjects:
refractory
calcium hexa-aluminate
alkali bursting
Online Access:https://www.mdpi.com/2571-6131/3/2/20
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spelling doaj-a8e388a91b5e4390b020b36c8b37971b2020-11-25T03:02:48ZengMDPI AGCeramics2571-61312020-05-0132022323410.3390/ceramics3020020Differences in the Corrosive Spalling Behavior of Alumina-Rich Castables: Microstructural and Crystallographic Considerations of Alumina and Calcium Aluminate MatricesLise Loison0Mouna Sassi1Thorsten Tonnesen2Emmanuel De Bilbao3Rainer Telle4Jacques Poirier5Institute of Mineral Engineering GHI, RWTH Aachen University, 52064 Aachen, GermanyCNRS, CEMHTI UPR3079, Univ. Orléans,45100 Orléans, FranceInstitute of Mineral Engineering GHI, RWTH Aachen University, 52064 Aachen, GermanyCNRS, CEMHTI UPR3079, Univ. Orléans,45100 Orléans, FranceInstitute of Mineral Engineering GHI, RWTH Aachen University, 52064 Aachen, GermanyCNRS, CEMHTI UPR3079, Univ. Orléans,45100 Orléans, FranceThe energy transition from the incineration and gasification of fossil fuels to the incineration and gasification of biomass refractory linings is being held up by a severe corrosion issue, caused by high alkali contents and the wide variety of biomass sources. Incinerators optimized for fossil fuels are commonly lined with mullite, Al<sub>2</sub>O<sub>3</sub>-Cr or SiC-based refractory products; however, those materials are not always suitable for the use of organic fuels. Hibonite (CaO·6Al<sub>2</sub>O<sub>3</sub>)-based refractory products have shown promising performance because of their high resistance against alkali attacks. Indeed, previous works have shown that the reaction between calcium hexa-aluminate and an alkali does not lead to the strong volume expansion observed with other mineral phases, such as corundum or andalusite. The present work aims to describe the reactions kinetics occurring between hibonite-based raw materials and biomass ashes. Therefore, the three main oxides contained in an average biomass, namely, CaO, SiO<sub>2</sub> and K<sub>2</sub>O, were selected to examine the high temperature reactions with a calcium hexa-aluminate matrix. The resulting phase composition and microstructure were compared with the performance of an alumina matrix through, respectively, X-ray diffraction (XRD) analysis and scanning electron microscopy (SEM). The post-mortem observations show a higher extent of reaction for the alumina than for the calcium hexa-aluminate. Moreover, the microstructure of the alumina matrix suffered a strong chemical spalling, while the calcium hexa-aluminate microstructure remained undamaged after the corrosion.https://www.mdpi.com/2571-6131/3/2/20refractorycalcium hexa-aluminatealkali bursting
collection DOAJ
language English
format Article
sources DOAJ
author Lise Loison
Mouna Sassi
Thorsten Tonnesen
Emmanuel De Bilbao
Rainer Telle
Jacques Poirier
spellingShingle Lise Loison
Mouna Sassi
Thorsten Tonnesen
Emmanuel De Bilbao
Rainer Telle
Jacques Poirier
Differences in the Corrosive Spalling Behavior of Alumina-Rich Castables: Microstructural and Crystallographic Considerations of Alumina and Calcium Aluminate Matrices
Ceramics
refractory
calcium hexa-aluminate
alkali bursting
author_facet Lise Loison
Mouna Sassi
Thorsten Tonnesen
Emmanuel De Bilbao
Rainer Telle
Jacques Poirier
author_sort Lise Loison
title Differences in the Corrosive Spalling Behavior of Alumina-Rich Castables: Microstructural and Crystallographic Considerations of Alumina and Calcium Aluminate Matrices
title_short Differences in the Corrosive Spalling Behavior of Alumina-Rich Castables: Microstructural and Crystallographic Considerations of Alumina and Calcium Aluminate Matrices
title_full Differences in the Corrosive Spalling Behavior of Alumina-Rich Castables: Microstructural and Crystallographic Considerations of Alumina and Calcium Aluminate Matrices
title_fullStr Differences in the Corrosive Spalling Behavior of Alumina-Rich Castables: Microstructural and Crystallographic Considerations of Alumina and Calcium Aluminate Matrices
title_full_unstemmed Differences in the Corrosive Spalling Behavior of Alumina-Rich Castables: Microstructural and Crystallographic Considerations of Alumina and Calcium Aluminate Matrices
title_sort differences in the corrosive spalling behavior of alumina-rich castables: microstructural and crystallographic considerations of alumina and calcium aluminate matrices
publisher MDPI AG
series Ceramics
issn 2571-6131
publishDate 2020-05-01
description The energy transition from the incineration and gasification of fossil fuels to the incineration and gasification of biomass refractory linings is being held up by a severe corrosion issue, caused by high alkali contents and the wide variety of biomass sources. Incinerators optimized for fossil fuels are commonly lined with mullite, Al<sub>2</sub>O<sub>3</sub>-Cr or SiC-based refractory products; however, those materials are not always suitable for the use of organic fuels. Hibonite (CaO·6Al<sub>2</sub>O<sub>3</sub>)-based refractory products have shown promising performance because of their high resistance against alkali attacks. Indeed, previous works have shown that the reaction between calcium hexa-aluminate and an alkali does not lead to the strong volume expansion observed with other mineral phases, such as corundum or andalusite. The present work aims to describe the reactions kinetics occurring between hibonite-based raw materials and biomass ashes. Therefore, the three main oxides contained in an average biomass, namely, CaO, SiO<sub>2</sub> and K<sub>2</sub>O, were selected to examine the high temperature reactions with a calcium hexa-aluminate matrix. The resulting phase composition and microstructure were compared with the performance of an alumina matrix through, respectively, X-ray diffraction (XRD) analysis and scanning electron microscopy (SEM). The post-mortem observations show a higher extent of reaction for the alumina than for the calcium hexa-aluminate. Moreover, the microstructure of the alumina matrix suffered a strong chemical spalling, while the calcium hexa-aluminate microstructure remained undamaged after the corrosion.
topic refractory
calcium hexa-aluminate
alkali bursting
url https://www.mdpi.com/2571-6131/3/2/20
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AT thorstentonnesen differencesinthecorrosivespallingbehaviorofaluminarichcastablesmicrostructuralandcrystallographicconsiderationsofaluminaandcalciumaluminatematrices
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