A novel continuum damage evolution model based on the concept of damage driving force for unidirectional composites
A novel continuum damage evolution model based on the concept of damage driving force for unidirectional composites
A novel damage evolution model for unidirectional (UD) composites is established in this paper in the context of continuum damage mechanics (CDM). It addresses matrix cracking and it is to be applied along with the damage representation established previously. The concept of damage driving force is employed based on the Helmholtz free energy. It is shown that the damage driving force can be partitioned into three parts, resembling closely three conventional modes of fracture, respectively. A damage evolution law is derived accordingly based on the newly obtained expressions of the damage driving force. The fully rationalised Tsai-Wu criterion is employed in the model for predicting the initiation of matrix cracking damage and fibre failure, assisted with the rationalised maximum stress criterion for identifying the damage modes. A mechanism is introduced to describe the unloading behaviour as a part of the proposed model. The predictions were validated against experimental results, showing good agreement with the experiments and demonstrating the capability and effectiveness of the proposed model.
continuum damage mechanics (CDM), damage driving force, damage evolution, damage initiation, matrix cracking, UD composites
Yu, Tianhong
9f53d0aa-fdfc-4a12-981a-596f531af742
Qi, Wenxuan
d6ae39dc-cbc9-45df-9ee4-ea47bdb4f002
Sitnikova, Elena
e0c2f901-24fe-43d0-88e8-76f415675104
Li, Shuguang
f99c53b3-e42e-456f-97df-4c4e06de4a40
Yu, Tianhong
9f53d0aa-fdfc-4a12-981a-596f531af742
Qi, Wenxuan
d6ae39dc-cbc9-45df-9ee4-ea47bdb4f002
Sitnikova, Elena
e0c2f901-24fe-43d0-88e8-76f415675104
Li, Shuguang
f99c53b3-e42e-456f-97df-4c4e06de4a40
Yu, Tianhong, Qi, Wenxuan, Sitnikova, Elena and Li, Shuguang
(2024)
A novel continuum damage evolution model based on the concept of damage driving force for unidirectional composites.
International Journal of Damage Mechanics.
(doi:10.1177/105678952412927).
(In Press)
Abstract
A novel damage evolution model for unidirectional (UD) composites is established in this paper in the context of continuum damage mechanics (CDM). It addresses matrix cracking and it is to be applied along with the damage representation established previously. The concept of damage driving force is employed based on the Helmholtz free energy. It is shown that the damage driving force can be partitioned into three parts, resembling closely three conventional modes of fracture, respectively. A damage evolution law is derived accordingly based on the newly obtained expressions of the damage driving force. The fully rationalised Tsai-Wu criterion is employed in the model for predicting the initiation of matrix cracking damage and fibre failure, assisted with the rationalised maximum stress criterion for identifying the damage modes. A mechanism is introduced to describe the unloading behaviour as a part of the proposed model. The predictions were validated against experimental results, showing good agreement with the experiments and demonstrating the capability and effectiveness of the proposed model.
Text
yu-et-al-2024-a-novel-continuum-damage-evolution-model-based-on-the-concept-of-damage-driving-force-for-unidirectional
- Version of Record
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Accepted/In Press date: 31 October 2024
Additional Information:
Publisher Copyright:
© The Author(s) 2024.
Keywords:
continuum damage mechanics (CDM), damage driving force, damage evolution, damage initiation, matrix cracking, UD composites
Identifiers
Local EPrints ID: 497652
URI: http://eprints.soton.ac.uk/id/eprint/497652
ISSN: 1056-7895
PURE UUID: 782fc9d0-65d9-40f9-b2ec-6ae86437ce00
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Date deposited: 28 Jan 2025 18:13
Last modified: 22 Aug 2025 02:46
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Contributors
Author:
Tianhong Yu
Author:
Wenxuan Qi
Author:
Elena Sitnikova
Author:
Shuguang Li
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