Multiscale modelling for the thermal transport behaviour of ceramic matrix composites with hierarchical structures

Suning Yang; Liang Shen; Wenhao Li; Zhongwei Zhang; Zhengmao Yang

doi:10.1016/j.coco.2024.101848

Multiscale modelling for the thermal transport behaviour of ceramic matrix composites with hierarchical structures

Suning Yang, Liang Shen, Wenhao Li, Zhongwei Zhang^*, Zhengmao Yang^*

^*Corresponding author for this work

Institute of Advanced Structure Technology

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

1 Citation (Scopus)

Abstract

Ceramic matrix composites contain many initial defects due to their “ceramic” properties and process characteristics, which presents challenges for the accurate prediction of their material equivalent properties. In this paper, multiscale and high-fidelity modelling of fibre-reinforced C/SiC composites are carried out on a “macro-meso-micro” cross-scale, and the thermal conductivity and relative thermal conductivity of multilevel structure composites based on a hierarchical multiscale model are proposed. The influence laws of SiC porous matrix, carbon fibre volume fraction and temperature on the thermal conductivity of composite materials are given. These findings provide useful insights into equivalent computational methods for material properties under the defect growth of thermomechanical loading.

Original language	English
Article number	101848
Journal	Composites Communications
Volume	46
DOIs	https://doi.org/10.1016/j.coco.2024.101848
Publication status	Published - Feb 2024

Keywords

Ceramic-matrix composites
Hierarchical structure
Multiscale modelling
Porosity
Thermal conductivity

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10.1016/j.coco.2024.101848

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title = "Multiscale modelling for the thermal transport behaviour of ceramic matrix composites with hierarchical structures",

abstract = "Ceramic matrix composites contain many initial defects due to their “ceramic” properties and process characteristics, which presents challenges for the accurate prediction of their material equivalent properties. In this paper, multiscale and high-fidelity modelling of fibre-reinforced C/SiC composites are carried out on a “macro-meso-micro” cross-scale, and the thermal conductivity and relative thermal conductivity of multilevel structure composites based on a hierarchical multiscale model are proposed. The influence laws of SiC porous matrix, carbon fibre volume fraction and temperature on the thermal conductivity of composite materials are given. These findings provide useful insights into equivalent computational methods for material properties under the defect growth of thermomechanical loading.",

keywords = "Ceramic-matrix composites, Hierarchical structure, Multiscale modelling, Porosity, Thermal conductivity",

author = "Suning Yang and Liang Shen and Wenhao Li and Zhongwei Zhang and Zhengmao Yang",

note = "Publisher Copyright: {\textcopyright} 2024 Elsevier Ltd",

year = "2024",

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doi = "10.1016/j.coco.2024.101848",

language = "English",

volume = "46",

journal = "Composites Communications",

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T1 - Multiscale modelling for the thermal transport behaviour of ceramic matrix composites with hierarchical structures

AU - Yang, Suning

AU - Shen, Liang

AU - Li, Wenhao

AU - Zhang, Zhongwei

AU - Yang, Zhengmao

PY - 2024/2

Y1 - 2024/2

N2 - Ceramic matrix composites contain many initial defects due to their “ceramic” properties and process characteristics, which presents challenges for the accurate prediction of their material equivalent properties. In this paper, multiscale and high-fidelity modelling of fibre-reinforced C/SiC composites are carried out on a “macro-meso-micro” cross-scale, and the thermal conductivity and relative thermal conductivity of multilevel structure composites based on a hierarchical multiscale model are proposed. The influence laws of SiC porous matrix, carbon fibre volume fraction and temperature on the thermal conductivity of composite materials are given. These findings provide useful insights into equivalent computational methods for material properties under the defect growth of thermomechanical loading.

AB - Ceramic matrix composites contain many initial defects due to their “ceramic” properties and process characteristics, which presents challenges for the accurate prediction of their material equivalent properties. In this paper, multiscale and high-fidelity modelling of fibre-reinforced C/SiC composites are carried out on a “macro-meso-micro” cross-scale, and the thermal conductivity and relative thermal conductivity of multilevel structure composites based on a hierarchical multiscale model are proposed. The influence laws of SiC porous matrix, carbon fibre volume fraction and temperature on the thermal conductivity of composite materials are given. These findings provide useful insights into equivalent computational methods for material properties under the defect growth of thermomechanical loading.

KW - Ceramic-matrix composites

KW - Hierarchical structure

KW - Multiscale modelling

KW - Porosity

KW - Thermal conductivity

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DO - 10.1016/j.coco.2024.101848

M3 - Article

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SN - 2452-2139

VL - 46

JO - Composites Communications

JF - Composites Communications

M1 - 101848

ER -

Multiscale modelling for the thermal transport behaviour of ceramic matrix composites with hierarchical structures

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Keywords

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