Investigation of thermal, moisture, and mechanical properties of wet and dry fired clay materials to assess frost damage risk

Frost action is one of the main causes for deterioration of porous building materials under defined hygrothermal conditions. For an accurate assessment of the frost damage risk under various environmental conditions, thermal, moisture, and mechanical properties should be considered; the hygrothermal...

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Bibliographic Details
Published in:MATEC web of conferences 2019, Vol.282, p.2083
Main Authors: Fukui, Kazuma, Iba, Chiemi, Taniguchi, Madoka, Takahashi, Kouichi, Ogura, Daisuke
Format: Article
Language:English
Subjects:
Building materials
Clay
Construction materials
Damage assessment
Dependence
Frost
Frost damage
Frost resistance
Material properties
Mechanical properties
Moisture content
Porosity
Porous materials
Risk assessment
Sintering (powder metallurgy)
Thermodynamic properties
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Summary:Frost action is one of the main causes for deterioration of porous building materials under defined hygrothermal conditions. For an accurate assessment of the frost damage risk under various environmental conditions, thermal, moisture, and mechanical properties should be considered; the hygrothermal properties affect the distribution of temperature and amount of frozen water in the material, whereas the mechanical properties are necessary to predict deformation and damage. Moreover, the dependency of these properties on the moisture content should be understood. Therefore, in this study, thermal, moisture, and mechanical properties of wet and dry fired clay materials were measured. The fired clay materials were sintered at two different temperatures, 1000 °C and 1100 °C (samples T10 and T11, respectively) for comparison. The measured thermal and mechanical properties are considerably different in the wet state compared to the dry state. Freeze–thaw tests were conducted to investigate the relation between the material properties and the frost resistance under a simple experimental condition. As expected, based on the pore structure and obtained mechanical properties, T10 exhibited lower frost resistance than T11 in the freeze–thaw test. Finally, frost damage risk was assessed under various environmental conditions based on the obtained hygrothermal and mechanical properties.
ISSN:2261-236X
2274-7214
2261-236X
DOI:10.1051/matecconf/201928202083