A double-phase field model for multiple failures in composites

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Peng Zhang
  • Siyuan Tan
  • Xiaofei Hu
  • Weian Yao
  • Xiaoying Zhuang

Organisationseinheiten

Externe Organisationen

  • Dalian University of Technology
  • Tongji University
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Aufsatznummer115730
FachzeitschriftComposite structures
Jahrgang293
Frühes Online-Datum13 Mai 2022
PublikationsstatusVeröffentlicht - 18 Mai 2022

Abstract

Fiber reinforced composites have very excellent mechanical properties due to their sophistic microstructures. At the same time these microstructures can induce complex failure mechanisms including intralaminar damage, interlaminar damage and the interactions between them. Nevertheless, high fidelity simulations for these complex failure mechanisms are still challenging. In this paper, we develop a double-phase field model for complex failure in fiber reinforced composite. In the model, two different phase fields, i.e., fiber phase field and matrix phase field, are adopted for characterizing fiber damage and matrix damage, respectively. The failure mechanisms of fiber damage as well as the other modes in matrix damage are identified through a new strain energy density form that contains four different effective strain variables as well as a new effective constitutive tensor. Then by coupling with redefined degradation functions corresponding to different failure mechanisms, specified damage initiation and evolution criteria can be embedded into the proposed model automatically. Moreover, the new model is implemented in an explicit manner. The proposed model is verified and validated through the comparison between the predicted results and that of the experiments on the failure in unidirectional block and composite laminate.

ASJC Scopus Sachgebiete

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A double-phase field model for multiple failures in composites. / Zhang, Peng; Tan, Siyuan; Hu, Xiaofei et al.
in: Composite structures, Jahrgang 293, 115730, 18.05.2022.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Zhang P, Tan S, Hu X, Yao W, Zhuang X. A double-phase field model for multiple failures in composites. Composite structures. 2022 Mai 18;293:115730. Epub 2022 Mai 13. doi: 10.1016/j.compstruct.2022.115730
Zhang, Peng ; Tan, Siyuan ; Hu, Xiaofei et al. / A double-phase field model for multiple failures in composites. in: Composite structures. 2022 ; Jahrgang 293.
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abstract = "Fiber reinforced composites have very excellent mechanical properties due to their sophistic microstructures. At the same time these microstructures can induce complex failure mechanisms including intralaminar damage, interlaminar damage and the interactions between them. Nevertheless, high fidelity simulations for these complex failure mechanisms are still challenging. In this paper, we develop a double-phase field model for complex failure in fiber reinforced composite. In the model, two different phase fields, i.e., fiber phase field and matrix phase field, are adopted for characterizing fiber damage and matrix damage, respectively. The failure mechanisms of fiber damage as well as the other modes in matrix damage are identified through a new strain energy density form that contains four different effective strain variables as well as a new effective constitutive tensor. Then by coupling with redefined degradation functions corresponding to different failure mechanisms, specified damage initiation and evolution criteria can be embedded into the proposed model automatically. Moreover, the new model is implemented in an explicit manner. The proposed model is verified and validated through the comparison between the predicted results and that of the experiments on the failure in unidirectional block and composite laminate.",
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T1 - A double-phase field model for multiple failures in composites

AU - Zhang, Peng

AU - Tan, Siyuan

AU - Hu, Xiaofei

AU - Yao, Weian

AU - Zhuang, Xiaoying

N1 - Funding Information: This work was supported by the National Natural Science Foundation of China (No. 12172079 ).

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Y1 - 2022/5/18

N2 - Fiber reinforced composites have very excellent mechanical properties due to their sophistic microstructures. At the same time these microstructures can induce complex failure mechanisms including intralaminar damage, interlaminar damage and the interactions between them. Nevertheless, high fidelity simulations for these complex failure mechanisms are still challenging. In this paper, we develop a double-phase field model for complex failure in fiber reinforced composite. In the model, two different phase fields, i.e., fiber phase field and matrix phase field, are adopted for characterizing fiber damage and matrix damage, respectively. The failure mechanisms of fiber damage as well as the other modes in matrix damage are identified through a new strain energy density form that contains four different effective strain variables as well as a new effective constitutive tensor. Then by coupling with redefined degradation functions corresponding to different failure mechanisms, specified damage initiation and evolution criteria can be embedded into the proposed model automatically. Moreover, the new model is implemented in an explicit manner. The proposed model is verified and validated through the comparison between the predicted results and that of the experiments on the failure in unidirectional block and composite laminate.

AB - Fiber reinforced composites have very excellent mechanical properties due to their sophistic microstructures. At the same time these microstructures can induce complex failure mechanisms including intralaminar damage, interlaminar damage and the interactions between them. Nevertheless, high fidelity simulations for these complex failure mechanisms are still challenging. In this paper, we develop a double-phase field model for complex failure in fiber reinforced composite. In the model, two different phase fields, i.e., fiber phase field and matrix phase field, are adopted for characterizing fiber damage and matrix damage, respectively. The failure mechanisms of fiber damage as well as the other modes in matrix damage are identified through a new strain energy density form that contains four different effective strain variables as well as a new effective constitutive tensor. Then by coupling with redefined degradation functions corresponding to different failure mechanisms, specified damage initiation and evolution criteria can be embedded into the proposed model automatically. Moreover, the new model is implemented in an explicit manner. The proposed model is verified and validated through the comparison between the predicted results and that of the experiments on the failure in unidirectional block and composite laminate.

KW - Composite laminate

KW - Effective strain variables

KW - Explicit scheme

KW - Phase field model

KW - Progressive failure

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