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Autori principali: Xuemin Wang, Yong Li, Songxue Chen, Bing Han, Jiaqi Shi, Yue Qiu, Chunling Zhu
Natura: Artículo Open Access
Pubblicazione: Wiley 2024
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Accesso online:https://4spepublications.onlinelibrary.wiley.com/doi/10.1002/pc.29413
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author Xuemin Wang
Yong Li
Songxue Chen
Bing Han
Jiaqi Shi
Yue Qiu
Chunling Zhu
author_facet Xuemin Wang
Yong Li
Songxue Chen
Bing Han
Jiaqi Shi
Yue Qiu
Chunling Zhu
Xuemin Wang
Yong Li
Songxue Chen
Bing Han
Jiaqi Shi
Yue Qiu
Chunling Zhu
collection Wiley Open Access
contents Study on interlayer properties of multilayer complex structures of graphene papers/harness satin weave glass fibers/epoxy reinforced composites with electric heating de‐icing Xuemin Wang Yong Li Songxue Chen Bing Han Jiaqi Shi Yue Qiu Chunling Zhu Polymer Composites AbstractThe graphene electrothermal de‐icing system has attracted extensive attention due to its efficient anti‐icing/de‐icing ability, but the interlayer properties of the heating layer are relatively weak. Currently, there is limited research on the interlayer properties of multilayer complex structures of graphene papers (GPs)/glass fibers (GFs)/epoxy (EP) reinforced resin composites (GPs/GE). In this study, a GPs/GE sandwich structure was prepared using a vacuum bag molding, and the effects of fabric structure and core material on the interlaminar mechanical properties of the sandwich structure were studied using the T‐peel test. A multiscale morphological investigation was conducted to analyze the crack growth and failure modes in the sandwich structures. The results indicated that the fabric structure caused anisotropy in the interlaminar peel performance of the composite material. The weft fibers contributed to inhibiting crack propagation. The GPs/GE achieved the highest peel strength of 0.533 N/mm under the (0,90)s layup configuration. The peel performance of GPs/GE was only 5.5% lower than that of conventional metal sandwich composite materials. In addition, GPs demonstrated the advantage of being lighter and thinner within the composite material. Through co‐curing bonding, the T‐peel performance of the GPs/GE sandwich structure was improved by 72.2%, thereby solving the problem of weak interlayer properties of the heating layer.Highlights Damage and failure mechanisms at different GPS/GE interfaces were explained. The fabric structure resulted in anisotropy in the peel performance of GPs/GE. The area ratio and arrangement of GPs influenced the stress distribution. GPs/GE exhibited excellent interlayer properties after co‐curing bonding. 10.1002/pc.29413 http://onlinelibrary.wiley.com/termsAndConditions#vor
doi_str_mv 10.1002/pc.29413
format Artículo Open Access
id wiley_oa_10_1002_pc_29413
institution Wiley Open Access
license_str_mv http://onlinelibrary.wiley.com/termsAndConditions#vor
publishDate 2024
publisher Wiley
record_format wiley_oa
spellingShingle Study on interlayer properties of multilayer complex structures of graphene papers/harness satin weave glass fibers/epoxy reinforced composites with electric heating de‐icing
Xuemin Wang
Yong Li
Songxue Chen
Bing Han
Jiaqi Shi
Yue Qiu
Chunling Zhu
Polymer Composites
Study on interlayer properties of multilayer complex structures of graphene papers/harness satin weave glass fibers/epoxy reinforced composites with electric heating de‐icing Xuemin Wang Yong Li Songxue Chen Bing Han Jiaqi Shi Yue Qiu Chunling Zhu Polymer Composites AbstractThe graphene electrothermal de‐icing system has attracted extensive attention due to its efficient anti‐icing/de‐icing ability, but the interlayer properties of the heating layer are relatively weak. Currently, there is limited research on the interlayer properties of multilayer complex structures of graphene papers (GPs)/glass fibers (GFs)/epoxy (EP) reinforced resin composites (GPs/GE). In this study, a GPs/GE sandwich structure was prepared using a vacuum bag molding, and the effects of fabric structure and core material on the interlaminar mechanical properties of the sandwich structure were studied using the T‐peel test. A multiscale morphological investigation was conducted to analyze the crack growth and failure modes in the sandwich structures. The results indicated that the fabric structure caused anisotropy in the interlaminar peel performance of the composite material. The weft fibers contributed to inhibiting crack propagation. The GPs/GE achieved the highest peel strength of 0.533 N/mm under the (0,90)s layup configuration. The peel performance of GPs/GE was only 5.5% lower than that of conventional metal sandwich composite materials. In addition, GPs demonstrated the advantage of being lighter and thinner within the composite material. Through co‐curing bonding, the T‐peel performance of the GPs/GE sandwich structure was improved by 72.2%, thereby solving the problem of weak interlayer properties of the heating layer.Highlights Damage and failure mechanisms at different GPS/GE interfaces were explained. The fabric structure resulted in anisotropy in the peel performance of GPs/GE. The area ratio and arrangement of GPs influenced the stress distribution. GPs/GE exhibited excellent interlayer properties after co‐curing bonding. 10.1002/pc.29413 http://onlinelibrary.wiley.com/termsAndConditions#vor
title Study on interlayer properties of multilayer complex structures of graphene papers/harness satin weave glass fibers/epoxy reinforced composites with electric heating de‐icing
topic Polymer Composites
url https://4spepublications.onlinelibrary.wiley.com/doi/10.1002/pc.29413