A thermo-damage-dependent thermal shock resistance model for ultrahigh temperature ceramics for temperature rising thermal shock environment

Weiguo Li; Dingyu Li; Ruzhuan Wang; Daining Fang

A thermo-damage-dependent thermal shock resistance model for ultrahigh temperature ceramics for temperature rising thermal shock environment

Weiguo Li^*, Dingyu Li, Ruzhuan Wang, Daining Fang

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

5 Citations (Scopus)

Abstract

A thermo-damage-dependent thermal shock resistance (TSR) model, which takes into account the sensitivities of thermo-physical properties to temperature and the evolution of the mechanisms of strength of ultra-high temperature ceramics (UHTCs) at elevated temperature is established. The model incorporates the effects of micro-crack size, density, damage evolution, and temperature on TSR of UHTCs. A detailed study about the effects of damage and its different nucleation laws on thermal shock performance of UHTCs is made by using this model. Results obtained show that through material microstructure design to introduce micro-cracks of a certain density and length into UHTCs while manufacturing and control damage evolution as the nucleation mode, not only the high strength of UHTCs can be kept, but also its TSR can be improved enormously.

Original language	English
Pages (from-to)	21-26
Number of pages	6
Journal	Ying Yong Li Xue Xue Bao/Chinese Journal of Applied Mechanics
Volume	29
Issue number	1
Publication status	Published - Feb 2012
Externally published	Yes

Keywords

Damage
Micro-cracks
Thermal shock resistance
Ultra-high temperature ceramics

Cite this

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abstract = "A thermo-damage-dependent thermal shock resistance (TSR) model, which takes into account the sensitivities of thermo-physical properties to temperature and the evolution of the mechanisms of strength of ultra-high temperature ceramics (UHTCs) at elevated temperature is established. The model incorporates the effects of micro-crack size, density, damage evolution, and temperature on TSR of UHTCs. A detailed study about the effects of damage and its different nucleation laws on thermal shock performance of UHTCs is made by using this model. Results obtained show that through material microstructure design to introduce micro-cracks of a certain density and length into UHTCs while manufacturing and control damage evolution as the nucleation mode, not only the high strength of UHTCs can be kept, but also its TSR can be improved enormously.",

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AU - Li, Weiguo

AU - Li, Dingyu

AU - Wang, Ruzhuan

AU - Fang, Daining

PY - 2012/2

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N2 - A thermo-damage-dependent thermal shock resistance (TSR) model, which takes into account the sensitivities of thermo-physical properties to temperature and the evolution of the mechanisms of strength of ultra-high temperature ceramics (UHTCs) at elevated temperature is established. The model incorporates the effects of micro-crack size, density, damage evolution, and temperature on TSR of UHTCs. A detailed study about the effects of damage and its different nucleation laws on thermal shock performance of UHTCs is made by using this model. Results obtained show that through material microstructure design to introduce micro-cracks of a certain density and length into UHTCs while manufacturing and control damage evolution as the nucleation mode, not only the high strength of UHTCs can be kept, but also its TSR can be improved enormously.

AB - A thermo-damage-dependent thermal shock resistance (TSR) model, which takes into account the sensitivities of thermo-physical properties to temperature and the evolution of the mechanisms of strength of ultra-high temperature ceramics (UHTCs) at elevated temperature is established. The model incorporates the effects of micro-crack size, density, damage evolution, and temperature on TSR of UHTCs. A detailed study about the effects of damage and its different nucleation laws on thermal shock performance of UHTCs is made by using this model. Results obtained show that through material microstructure design to introduce micro-cracks of a certain density and length into UHTCs while manufacturing and control damage evolution as the nucleation mode, not only the high strength of UHTCs can be kept, but also its TSR can be improved enormously.

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KW - Micro-cracks

KW - Thermal shock resistance

KW - Ultra-high temperature ceramics

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A thermo-damage-dependent thermal shock resistance model for ultrahigh temperature ceramics for temperature rising thermal shock environment

Abstract

Keywords

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