Failure process identification in C/SIC samples with a range of tensile performance using acoustic emission

Y. Z. Zhang; X. Y. Tong; L. J. Yao; A. T. Augousti

Failure process identification in C/SIC samples with a range of tensile performance using acoustic emission

Y. Z. Zhang
, X. Y. Tong
, L. J. Yao
, A. T. Augousti

Research output: Contribution to conference › Paper › peer-review

Abstract

C/SiC composites are important hot-structural materials for future aeronautical applications. However, due to the complexity of the processing method and microstructure, C/SiC often displays a varied mechanical performance. To identify the failure processes of C/SiC made of different size fiber bundles under mechanical load, acoustic emission (AE), an effective continuous damage monitoring technique, was used to monitor tensile tests of C/SiC composites. Combined with the SEM observation on the fracture surface, five damage mechanisms were identified, and their evolution was described. It was found: (1) the main damage mechanisms of C/SiC prepared by the precursor impregnation-pyrolysis (PIP) process under tensile load are matrix cracking, fiber cluster fracture, and fiber cluster pull-out friction; (2) the size of fiber bundles makes the distribution of matrix defects in fiber bundles vary greatly, which has an important influence on the macroscopic properties and damage evolution process of materials; (3) for the C/SiC composites with a lager fiber bundle, lots of matrix cracks appear in the matrix in the fiber bundle at the early stage of loading, which leads to the decrease of material stiffness, in the later stage of loading, the large energy damage such as fiber cluster fracture and matrix cracking between fiber bundles appear and increase rapidly, which accelerates the fracture failure process of the material.

Original language	English
Publication status	Published - 8 Sept 2021
Event	32nd Congress of the International Council of the Aeronautical Sciences, ICAS 2021 - Shangri-La Hotel, Pudong, Shanghai, China. Duration: 6 Sept 2021 → 10 Sept 2021

Conference

Conference	32nd Congress of the International Council of the Aeronautical Sciences, ICAS 2021
Period	6/09/21 → 10/09/21

Bibliographical note

Note: Published in volume 4.1 ('Material issues, fatigue and damage tolerances') of the 32nd Congress of the International Council of the Aeronautical Sciences (ICAS 2021), Shanghai, China, International Council of the Aeronautical Sciences, ISBN: 9781713841012, pp. 2830-2841

Organising Body: International Council of the Aeronautical Sciences

Keywords

Acoustic-emissions
C/SiC
C/SiC composites
General engineering and mineral and mining engineering
aeronautical applications
damage mechanism
failure process
fibre bundle
matrix cracking
process identification
tensile performance

1 Conference contribution

Failure process identification in C/SIC samples with a range of tensile performance using acoustic emission
Zhang, Y. Z., Tong, X. Y., Yao, L. J. & Augousti, A. T., 8 Sept 2021, Published in volume 4.1 ('Material issues, fatigue and damage tolerances') of the 32nd Congress of the International Council of the Aeronautical Sciences (ICAS 2021), Shanghai, China, International Council of the Aeronautical Sciences, ISBN: 9781713841012, pp. 2830-2841 Organising Body: International Council of the Aeronautical Sciences Organising Body: International Council of the Aeronautical Sciences.
Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Cite this

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title = "Failure process identification in C/SIC samples with a range of tensile performance using acoustic emission",

abstract = "C/SiC composites are important hot-structural materials for future aeronautical applications. However, due to the complexity of the processing method and microstructure, C/SiC often displays a varied mechanical performance. To identify the failure processes of C/SiC made of different size fiber bundles under mechanical load, acoustic emission (AE), an effective continuous damage monitoring technique, was used to monitor tensile tests of C/SiC composites. Combined with the SEM observation on the fracture surface, five damage mechanisms were identified, and their evolution was described. It was found: (1) the main damage mechanisms of C/SiC prepared by the precursor impregnation-pyrolysis (PIP) process under tensile load are matrix cracking, fiber cluster fracture, and fiber cluster pull-out friction; (2) the size of fiber bundles makes the distribution of matrix defects in fiber bundles vary greatly, which has an important influence on the macroscopic properties and damage evolution process of materials; (3) for the C/SiC composites with a lager fiber bundle, lots of matrix cracks appear in the matrix in the fiber bundle at the early stage of loading, which leads to the decrease of material stiffness, in the later stage of loading, the large energy damage such as fiber cluster fracture and matrix cracking between fiber bundles appear and increase rapidly, which accelerates the fracture failure process of the material.",

keywords = "Acoustic-emissions, C/SiC, C/SiC composites, General engineering and mineral and mining engineering, aeronautical applications, damage mechanism, failure process, fibre bundle, matrix cracking, process identification, tensile performance",

author = "Zhang, \{Y. Z.\} and Tong, \{X. Y.\} and Yao, \{L. J.\} and Augousti, \{A. T.\}",

note = "Note: Published in volume 4.1 ('Material issues, fatigue and damage tolerances') of the 32nd Congress of the International Council of the Aeronautical Sciences (ICAS 2021), Shanghai, China, International Council of the Aeronautical Sciences, ISBN: 9781713841012, pp. 2830-2841 Organising Body: International Council of the Aeronautical Sciences; 32nd Congress of the International Council of the Aeronautical Sciences, ICAS 2021 ; Conference date: 06-09-2021 Through 10-09-2021",

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T1 - Failure process identification in C/SIC samples with a range of tensile performance using acoustic emission

AU - Zhang, Y. Z.

AU - Tong, X. Y.

AU - Yao, L. J.

AU - Augousti, A. T.

N1 - Note: Published in volume 4.1 ('Material issues, fatigue and damage tolerances') of the 32nd Congress of the International Council of the Aeronautical Sciences (ICAS 2021), Shanghai, China, International Council of the Aeronautical Sciences, ISBN: 9781713841012, pp. 2830-2841 Organising Body: International Council of the Aeronautical Sciences

PY - 2021/9/8

Y1 - 2021/9/8

N2 - C/SiC composites are important hot-structural materials for future aeronautical applications. However, due to the complexity of the processing method and microstructure, C/SiC often displays a varied mechanical performance. To identify the failure processes of C/SiC made of different size fiber bundles under mechanical load, acoustic emission (AE), an effective continuous damage monitoring technique, was used to monitor tensile tests of C/SiC composites. Combined with the SEM observation on the fracture surface, five damage mechanisms were identified, and their evolution was described. It was found: (1) the main damage mechanisms of C/SiC prepared by the precursor impregnation-pyrolysis (PIP) process under tensile load are matrix cracking, fiber cluster fracture, and fiber cluster pull-out friction; (2) the size of fiber bundles makes the distribution of matrix defects in fiber bundles vary greatly, which has an important influence on the macroscopic properties and damage evolution process of materials; (3) for the C/SiC composites with a lager fiber bundle, lots of matrix cracks appear in the matrix in the fiber bundle at the early stage of loading, which leads to the decrease of material stiffness, in the later stage of loading, the large energy damage such as fiber cluster fracture and matrix cracking between fiber bundles appear and increase rapidly, which accelerates the fracture failure process of the material.

AB - C/SiC composites are important hot-structural materials for future aeronautical applications. However, due to the complexity of the processing method and microstructure, C/SiC often displays a varied mechanical performance. To identify the failure processes of C/SiC made of different size fiber bundles under mechanical load, acoustic emission (AE), an effective continuous damage monitoring technique, was used to monitor tensile tests of C/SiC composites. Combined with the SEM observation on the fracture surface, five damage mechanisms were identified, and their evolution was described. It was found: (1) the main damage mechanisms of C/SiC prepared by the precursor impregnation-pyrolysis (PIP) process under tensile load are matrix cracking, fiber cluster fracture, and fiber cluster pull-out friction; (2) the size of fiber bundles makes the distribution of matrix defects in fiber bundles vary greatly, which has an important influence on the macroscopic properties and damage evolution process of materials; (3) for the C/SiC composites with a lager fiber bundle, lots of matrix cracks appear in the matrix in the fiber bundle at the early stage of loading, which leads to the decrease of material stiffness, in the later stage of loading, the large energy damage such as fiber cluster fracture and matrix cracking between fiber bundles appear and increase rapidly, which accelerates the fracture failure process of the material.

KW - Acoustic-emissions

KW - C/SiC

KW - C/SiC composites

KW - General engineering and mineral and mining engineering

KW - aeronautical applications

KW - damage mechanism

KW - failure process

KW - fibre bundle

KW - matrix cracking

KW - process identification

KW - tensile performance

M3 - Paper

T2 - 32nd Congress of the International Council of the Aeronautical Sciences, ICAS 2021

Y2 - 6 September 2021 through 10 September 2021

ER -

Failure process identification in C/SIC samples with a range of tensile performance using acoustic emission

Abstract

Conference

Bibliographical note

Keywords

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Research output

Failure process identification in C/SIC samples with a range of tensile performance using acoustic emission

Cite this