Aligned carbon nanotube composite belts stitching of laminated composites for enhanced fracture toughness and enriched functionalities

This special issue of Polymer Composites on “Additive Manufacturing of Composites” seeks to provide insight into recent advances in the field of additive manufacturing (AM), often termed 3D printing, using composite materials. We hope this issue provides help to the practicing engineer, material suppliers, original equipment manufacturers (OEMs), Tier‐1 suppliers, academics and scientists, and others with an interest in using or applying AM to their products and systems. This issue presents new materials, new material systems, enhancements of the final part performance, novel manufacturing methods, and applications, and improvements of existing manufacturing methods for AM. Solutions are presented by the research community to solve specific scientific and engineering challenges within the field in this issue. This issue is highlighted by several review articles on recent advances within the field of polymer composite additive manufacturing.

Section: D Printing Additive Manufacturing Polymer Compositesmentioning

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confidence: 99%

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confidence: 99%

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Polymer composites–Special issue review for additive manufacturing of composites

Osswald,

Jack,

Thompson

2023

“…CNT exhibits its potential as an effective adhesive material due to its high strength and bonding performance. [23][24][25] C-C covalent bond results in high tensile strength, and the large surface area of carbon nanotube guaranteed the adhesion with surrounding material. [26][27][28] Nevertheless, research in the application of CNT modified epoxy resin adhesive agent in CFRP forcebearing structure is relatively limited.…”

Section: Introductionmentioning

confidence: 99%

“…CNT exhibits its potential as an effective adhesive material due to its high strength and bonding performance 23–25 . C‐C covalent bond results in high tensile strength, and the large surface area of carbon nanotube guaranteed the adhesion with surrounding material 26–28 .…”

Section: Introductionmentioning

confidence: 99%

Aminated carbon nanotube enhanced composite T‐joints mediating CFRP load‐bearing capacity improvement

Bai,

Yan,

et al. 2023

Adhesive bond is the weakest part of carbon fiber reinforced composites (CFRP) force‐bearing structure. Therefore, enhancing the strength of the adhesive bond is key to improve force‐bearing structure. In this study, adhesive strength of the common CFRP T‐joint was enhanced by aminated carbon nanotubes (CNT). To begin with, shear tensile strength of single‐lap‐joint laminated composites with various CNT content was verified, which peaked at 0.5 wt%. It was indicated that the adhesive bond of deltoid is the weakest area in a T‐joint. CNT was applied in the deltoid of composite T‐joint and pull‐off test was conducted to investigate the progress from the initiation and evolution of damage as well as the final failure. The aminated CNT employed in this study formed an effective load transmission through physical engagement and chemical bonding; the addition of 0.5 wt% CNT effectively enhanced tensile strength and toughness, improving mechanical property of the adhesive bond. This study provides a solution to enhance the adhesive area of CFRP load‐bearing structure with CNT, consequently improve the load‐bearing strength of composite.Highlights Aminated CNT is substantially improve the adhesive strength of CFRP T‐joint. Tensile strength and toughness of T‐joint deltoid was optimized by 0.5 wt% CNT. Effective load transmission through physical engagement and chemical bonding.

Tensile properties at various strain rates of flexible carbon nanotube film densified by the combination of chlorosulfuric acid and uniaxial drawing

Tang,

Yin,

et al. 2024

The quasi‐static tensile properties of carbon nanotube (CNT) films have been extensively investigated, yet research on their impact tensile properties at high strain rates remains scarce. In this article, CNT films prepared by floating catalyst chemical vapor deposition (FCCVD) method were densely arranged by chlorosulfuric acid (CSA) under wet stretching. The Instron 3365 and miniaturized split Hopkinson tension bar (SHTB) were used to conduct tensile testing at different strain rates. The findings reveal that CSA wet‐stretching markedly enhances the density and orientation of CNT films, resulting in significant improvements in tensile properties with a notable strain rate effect. Specifically, when immersed for 60 s under a draft ratio of 40% and a strain rate of 1900 s−1, the densified CNT films exhibit maximum stress and energy absorption values of 777.44 MPa and 54.79 MJ/m3, respectively, achieving a 637.1% and 425.7% increase compared with the original film. This research provides a convenient and feasible strategy to prepare CNT films with high energy absorption tolerance across various strain rates, thus expanding the practical application potential of CNT films.Highlights The study innovates a posttreatment way to produce superior FCCVD CNT films. CSA treatment and wet stretching enhance CNT films' mechanical properties. Dynamic fracture strength boosts over 600% and energy absorption raises over 400%. CSA can purify FCCVD‐prepared CNT films, greatly improving their properties. The Prep can be effectively integrated with the direct spinning process.