Enhanced electromagnetic shielding of lightweight copper-coated nonwoven laminate with carbon filament reinforcement

Hu, Shi; Wang, Dan; Venkataraman, Mohanapriya; Křemenáková, Dana; Militký, Jiří; Yang, Kai; Wang, Yuanfeng; Palanisamy, Sundaramoorthy

doi:10.1177/15589250231199970

Journal of Engineered Fibers and Fabrics

2023

DOI: 10.1177/15589250231199970

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Enhanced electromagnetic shielding of lightweight copper-coated nonwoven laminate with carbon filament reinforcement

Shi Hu,

Dan Wang,

Mohanapriya Venkataraman

et al.

Abstract: Textile-based electromagnetic interference (EMI) shielding materials with good flexibility and high EMI shielding effectiveness (SE) are highly desirable. Still, the poor mechanical properties of textile-based EMI shielding materials limit their application. The carbon filaments (CF) combine superior mechanical properties and conductivity. Therefore, we demonstrate the CF-reinforced material, which was laminated with two types of copper-coated nonwoven polyester (CuPET10 and CuPET20) for EMI shielding. Compare… Show more

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2024

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Impact of different matrix systems on mechanical, thermal, and electrical properties of carbon fiber reinforced epoxy resin matrix composites

Wang,

Hu,

Vecernik

et al. 2024

Polymer Composites

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Carbon fiber reinforced epoxy resin matrix composite is one of the most important composite materials in the world. Many researchers have conducted a lot of research on epoxy resin matrix systems in recent years, mainly to improve the problem with the short curing time of the matrix system and epoxy resin's high viscosity. The final aim is to enhance various aspects of composites' performance and optimize the production process. A new type of water dispersed epoxy resin matrix system is investigated in this paper and the target is to optimize the mechanical, thermal, and electrical performances of the composites with the water dispersed epoxy resin matrix by varying different doping particles and different resin/catalyst ratios. Through a series of experiments, it is evident that varying the ratio of resin to catalyst in the matrix system will not significantly improve the mechanical as well as thermal properties of the composites. However, increasing the amount of catalyst in the matrix system can greatly improve the electrical properties of its composite samples. In addition to this, the addition of doping particles to the matrix systems has the effect of slightly enhancing the tensile modulus, thermal conductivity, and electrical conductivity of their composites.Highlights A new water‐dispersed epoxy resin matrix system improves processing technology. Increasing amount of catalyst in the matrix system improves electrical resistivity. Adding particles to matrix systems has a slight effect on different properties.

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Impact of different matrix systems on mechanical, thermal, and electrical properties of carbon fiber reinforced epoxy resin matrix composites

Wang,

Hu,

Vecernik

et al. 2024

Polymer Composites

View full text Add to dashboard Cite

show abstract

The experimental characterization of the torsional and transverse stiffnesses of a braided parachute suspension line

Barry,

Olson,

Willis

et al. 2024

Journal of Engineered Fibers and Fabrics

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GPS-guided parachutes are used by the military to deliver supplies to personnel in the field. During descent, the suspension lines can vibrate as a result of vortex shedding and oscillating aerodynamic forces. In addition to challenging the targeting accuracy, these vibrations can generate sound that can compromise silent entry operations. The availability of a fundamental understanding of the relationship between braid architecture and associated vibrations would provide insight on how changes in the design of suspension lines could mitigate these vibrations. In the current research, the torsional and transverse stiffnesses of a braided parachute suspension line are characterized as a function of the state of tension. The torsional behavior is investigated using static and dynamic torsion tests, and the transverse behavior is studied using a pluck test. The torsional and transverse stiffnesses are found to increase with increasing tension on the suspension line. The effective transverse stiffness is found to correlate to that which can be derived from the vibrating string under tension equation. These stiffness properties can be used as inputs for fluid-structure-interaction (FSI) models to develop a calibrated FSI simulation to investigate the role that the mechanical behavior of the suspension line plays in its flow-induced vibrational response.

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Enhanced electromagnetic shielding of lightweight copper-coated nonwoven laminate with carbon filament reinforcement

Cited by 2 publications

References 50 publications

Impact of different matrix systems on mechanical, thermal, and electrical properties of carbon fiber reinforced epoxy resin matrix composites

Impact of different matrix systems on mechanical, thermal, and electrical properties of carbon fiber reinforced epoxy resin matrix composites

The experimental characterization of the torsional and transverse stiffnesses of a braided parachute suspension line

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