Heat transfer mechanism and characteristics of lightweight high temperature ceramic cellular sandwich

•Heat transfer models of the high temperature ceramic panel are originally established.•It is found that the insulation material can well improve the temperature uniformity.•Filling insulation material can block the cavity radiation, and hence can remarkably enhance the insulation efficiency. Consid...

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Bibliographic Details
Published in:Applied thermal engineering 2019-05, Vol.154, p.562-572
Main Authors: Wei, Kai, Wang, Xiuwu, Yang, Xujing, Qu, Zhaoliang, Tao, Yong, Fang, Daining
Format: Article
Language:English
Subjects:
Bearing capacity
Coupling
Finite element analysis
Finite element method
Heat flux
Heat transfer
High temperature
High temperature ceramic
Insulation
Lightweight
Mechanical properties
Refractory materials
Sandwich structure
Sandwich structures
Temperature
Temperature gradients
Thermal analysis
Thermal engineering
Thermal protection
Thermal short effect
Zirconium compounds
Zirconium dioxide
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Summary:•Heat transfer models of the high temperature ceramic panel are originally established.•It is found that the insulation material can well improve the temperature uniformity.•Filling insulation material can block the cavity radiation, and hence can remarkably enhance the insulation efficiency. Consider the severe thermal loads in thermal engineering applications of lightweight ZrO2 and ZrB2 corrugated sandwich structures, here, their heat transfer mechanism and characteristics are originally explored in this work. Finite element (FE) models for heat transfer of ZrO2 and ZrB2 sandwiches, sandwiches filled with insulation material and the corresponding bulk ceramics are respectively well established. The insulation efficiency, temperature gradient, thermal short effect and thermal-mechanical coupling effect are well calculated and analyzed. It is found that cavity radiation heat flux is increased with the height, leading to low insulation efficiency. The insulation material can block the cavity radiation, and hence can remarkably enhance the insulation efficiency and improve the temperature uniformity. Low temperature gradient is found in ZrO2 and ZrB2 sandwiches, while, remarkable temperature gradients are found in sandwiches filled with insulation material. With the increasing height, the insulation effect is improved, while the mechanical properties are weakened, suggesting pronounced thermal-mechanical coupling effect between loading bearing capacity and insulation effect. The heat transfer mechanism and characteristic revealed here provide the thermal basis for engineering applications of the ZrO2 and ZrB2 cellular sandwiches.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2019.03.126