Long-term failure of transversely loaded glass/iPP

Ozan Erartsın; Stijn A.J.J. Arntz; Enrico M. Troisi; Leonid V. Pastukhov; Martin van Drongelen; Laurent Warnet; Leon E. Govaert

doi:10.1002/app.50878

Long-term failure of transversely loaded glass/iPP

Ozan Erartsın, Stijn A.J.J. Arntz, Enrico M. Troisi, Leonid V. Pastukhov, Martin van Drongelen, Laurent Warnet, Leon E. Govaert (Corresponding author)

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

2 Citations (Scopus)

Abstract

Herein, temperature-dependent long-term behavior of polypropylene and its transversely loaded unidirectional glass fiber reinforced composite is investigated and a lifetime prediction method is proposed, which is based on the observed long-term failure mechanisms. Furthermore, the effect of cooling rate during processing on the time-dependent behavior is addressed. The composite is revealed to exhibit multiple molecular deformation mechanisms, similar to neat polypropylene, which is modeled using the Ree–Eyring approach. Failure kinetics under constant-strain-rate and creep tests are found to be identical and switching from creep to cyclic loading decelerates the failure, which are signs of plasticity-controlled failure. Hence, lifetime is predicted well by using a lifetime prediction methodology for the plasticity-controlled failure which combines the Ree–Eyring approach and the concept of critical strain. A change in the cooling rate alters the deformation and failure kinetics: lower cooling rates promote embrittlement.

Original language	English
Article number	e50878
Number of pages	19
Journal	Journal of Applied Polymer Science
Volume	138
Issue number	35
DOIs	https://doi.org/10.1002/app.50878
Publication status	Published - 15 Sept 2021

Funding

Theodoor Stoverinck is highly acknowledged for his experimental contributions in scope of his BSc thesis assignment. The authors would like to thank to DSM for its financial support.

Keywords

composites
mechanical properties
structure-property relationships
thermoplastics

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10.1002/app.50878

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title = "Long-term failure of transversely loaded glass/iPP",

abstract = "Herein, temperature-dependent long-term behavior of polypropylene and its transversely loaded unidirectional glass fiber reinforced composite is investigated and a lifetime prediction method is proposed, which is based on the observed long-term failure mechanisms. Furthermore, the effect of cooling rate during processing on the time-dependent behavior is addressed. The composite is revealed to exhibit multiple molecular deformation mechanisms, similar to neat polypropylene, which is modeled using the Ree–Eyring approach. Failure kinetics under constant-strain-rate and creep tests are found to be identical and switching from creep to cyclic loading decelerates the failure, which are signs of plasticity-controlled failure. Hence, lifetime is predicted well by using a lifetime prediction methodology for the plasticity-controlled failure which combines the Ree–Eyring approach and the concept of critical strain. A change in the cooling rate alters the deformation and failure kinetics: lower cooling rates promote embrittlement.",

keywords = "composites, mechanical properties, structure-property relationships, thermoplastics",

author = "Ozan Erartsın and Arntz, {Stijn A.J.J.} and Troisi, {Enrico M.} and Pastukhov, {Leonid V.} and {van Drongelen}, Martin and Laurent Warnet and Govaert, {Leon E.}",

note = "Funding Information: Theodoor Stoverinck is highly acknowledged for his experimental contributions in scope of his BSc thesis assignment. The authors would like to thank to DSM for its financial support. Publisher Copyright: {\textcopyright} 2021 The Authors. Journal of Applied Polymer Science published by Wiley Periodicals LLC.",

year = "2021",

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doi = "10.1002/app.50878",

language = "English",

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AU - Erartsın, Ozan

AU - Arntz, Stijn A.J.J.

AU - Troisi, Enrico M.

AU - Pastukhov, Leonid V.

AU - van Drongelen, Martin

AU - Warnet, Laurent

AU - Govaert, Leon E.

N1 - Funding Information: Theodoor Stoverinck is highly acknowledged for his experimental contributions in scope of his BSc thesis assignment. The authors would like to thank to DSM for its financial support. Publisher Copyright: © 2021 The Authors. Journal of Applied Polymer Science published by Wiley Periodicals LLC.

PY - 2021/9/15

Y1 - 2021/9/15

N2 - Herein, temperature-dependent long-term behavior of polypropylene and its transversely loaded unidirectional glass fiber reinforced composite is investigated and a lifetime prediction method is proposed, which is based on the observed long-term failure mechanisms. Furthermore, the effect of cooling rate during processing on the time-dependent behavior is addressed. The composite is revealed to exhibit multiple molecular deformation mechanisms, similar to neat polypropylene, which is modeled using the Ree–Eyring approach. Failure kinetics under constant-strain-rate and creep tests are found to be identical and switching from creep to cyclic loading decelerates the failure, which are signs of plasticity-controlled failure. Hence, lifetime is predicted well by using a lifetime prediction methodology for the plasticity-controlled failure which combines the Ree–Eyring approach and the concept of critical strain. A change in the cooling rate alters the deformation and failure kinetics: lower cooling rates promote embrittlement.

AB - Herein, temperature-dependent long-term behavior of polypropylene and its transversely loaded unidirectional glass fiber reinforced composite is investigated and a lifetime prediction method is proposed, which is based on the observed long-term failure mechanisms. Furthermore, the effect of cooling rate during processing on the time-dependent behavior is addressed. The composite is revealed to exhibit multiple molecular deformation mechanisms, similar to neat polypropylene, which is modeled using the Ree–Eyring approach. Failure kinetics under constant-strain-rate and creep tests are found to be identical and switching from creep to cyclic loading decelerates the failure, which are signs of plasticity-controlled failure. Hence, lifetime is predicted well by using a lifetime prediction methodology for the plasticity-controlled failure which combines the Ree–Eyring approach and the concept of critical strain. A change in the cooling rate alters the deformation and failure kinetics: lower cooling rates promote embrittlement.

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KW - structure-property relationships

KW - thermoplastics

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JO - Journal of Applied Polymer Science

JF - Journal of Applied Polymer Science

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ER -

Long-term failure of transversely loaded glass/iPP

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Keywords

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