用于多功能层压板的多材料编织:导电通厚增强

Caroline O’Keeffe, Laura Rhian Pickard, Juan Cao, Giuliano Allegri, Ivana K. Partridge, Dmitry S. Ivanov
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引用次数: 2

摘要

众所周知,传统的碳纤维层压板在平面内具有中等导电性,但具有较差的通厚导电性。这对工业中越来越重要的功能方面提出了一个问题,例如传感,电流收集,电感/电阻加热,电磁干扰(EMI)屏蔽等。对于非导电复合材料增强材料,如玻璃、有机或天然纤维,这种限制当然更为明显。在提高导电率的各种解决方案中,用混合微编织金属-碳纤维纱线进行簇织是最有前途的解决方案之一。作为一种特性良好的全厚度补强方法,簇植很容易在制造环境中实现。编织中材料的杂交促进了纱线的弹性和完整性,同时集成金属丝开辟了广泛的多功能应用。通过不同的编织模式和构成纱线/钢丝可以产生多种结构。因此,预测设计工具对于选择适合所需功能和结构性能的正确材料配置是必要的。本文提出了一种快速、鲁棒的编织有限元模型生成方法,验证了编织簇的微结构和电导率预测,并演示了编织簇增强复合材料的成功制造。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Multi-material braids for multifunctional laminates: conductive through-thickness reinforcement

Multi-material braids for multifunctional laminates: conductive through-thickness reinforcement

Conventional carbon fibre laminates are known to be moderately electrically conductive in-plane, but have a poor through-thickness conductivity. This poses a problem for functionality aspects that are of increasing importance to industry, such as sensing, current collection, inductive/resistive heating, electromagnetic interference (EMI) shielding, etc. This restriction is of course more pronounced for non-conductive composite reinforcements such as glass, organic or natural fibres. Among various solutions to boost through-thickness electrical conductivity, tufting with hybrid micro-braided metal-carbon fibre yarns is one of the most promising. As a well-characterised method of through thickness reinforcement, tufting is easily implementable in a manufacturing environment. The hybridisation of materials in the braid promotes the resilience and integrity of yarns, while integrating metal wires opens up a wide range of multifunctional applications. Many configurations can be produced by varying braid patterns and the constituting yarns/wires. A predictive design tool is therefore necessary to select the right material configuration for the desired functional and structural performance. This paper suggests a fast and robust method for generating finite-element models of the braids, validates the prediction of micro-architecture and electrical conductivity, and demonstrates successful manufacturing of composites enhanced with braided tufts.

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