Origin and Evolution of Cracks in the Glaze Surface of a Ceramic during the Cooling Process

Because of the significant difference between the thermal expansion coefficients of ceramic blank and glaze, the glaze typically undergoes more pronounced shrinkage than the blank during ceramic cooling, which results in high stress concentrations and cracking. In this study, the mechanical mechanis...

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Published inMaterials Vol. 16; no. 16; p. 5508
Main Authors Chen, Tiantian, Gong, Bin, Tang, Chun’an
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.08.2023
MDPI
Subjects
Ambient temperature
Boundary conditions
ceramic
Ceramic materials
Ceramics
Continuum mechanics
Cooling
crack propagation
Cracking (fracturing)
Cracks
craquelure
Fractals
glaze cracking
Heat transfer
Heat transfer coefficients
High temperature
Mechanics
Microcracks
Stress concentration
Stress state
Temperature gradients
Thermal cycling
Thermal expansion
Thermal properties
Thickness
China
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Summary:Because of the significant difference between the thermal expansion coefficients of ceramic blank and glaze, the glaze typically undergoes more pronounced shrinkage than the blank during ceramic cooling, which results in high stress concentrations and cracking. In this study, the mechanical mechanism of glaze cracking is studied, based on the statistical strength theory, damage mechanics, and continuum mechanics. Furthermore, the influence of the glaze layer thickness, heat transfer coefficient, expansion coefficient, and temperature difference on the creation and propagation of inner microcracks is systematically investigated, and the final discrete fracture network of ceramics is discussed at the specific crack saturation state. The results show that (1) a higher heat transfer coefficient will lead to a more uniform distribution of the surface temperature and a faster cooling process of the ceramics, reducing the number of microcracks when the ambient temperature is reached; (2) the thinner glaze layer is less prone to cracking when its thickness is smaller than that of the blank. However, when the thickness of the glaze layer is similar to that of the blank, the increased thickness of the glaze layer will increase the number of cracks on its surface; and (3) when the expansion coefficient of the glaze layer is smaller than that of the blank, cracks will not occur inside the glaze layer. However, as the coefficient of the thermal expansion of the glaze layer continuously rises, the number of cracks on its surface will first increase and then decrease.
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ISSN:1996-1944
1996-1944
DOI:10.3390/ma16165508