在复合结构中实现潜在自修复功能的策略

X. Tsilimigkra , A. Baltopoulos , S. Tsantzalis , A. Kotrotsos , N. Siakavellas , V. Kostopoulos , S. Flórez
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引用次数: 8

摘要

使用过程中产生的劣化会导致聚合物复合材料的特定性能发生灾难性失效。鉴于此,科学家们从自然生物系统及其独特的愈合外部伤口的能力中获得灵感,在材料内开发类似的修复系统。碳和玻璃纤维增强聚合物是在湿铺或预浸过程中制造的。微胶囊的含量为重量的5%或10%,由蜡和钢丝制成的血管网络,最后是可逆聚合物,作为潜在的自修复系统,在复合材料中实现。检查技术,包括超声c扫描和红外热成像,在可能的情况下应用。光学显微镜显示复合材料结构完整性的破坏,观察到层状波纹和血管结构周围的树脂到达区。三点弯曲实验确定了与参考材料相比,每种情况下的击倒因子,表示为抗弯强度和模量值的减少。减少幅度在12%-64%之间,主要取决于所选择的制造方法和不同实施的治疗系统。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Strategies on implementing a potential self-healing functionality in a composite structure

Deteriorations generated in service can cause catastrophic failure at the specific properties of the polymer composite materials. In view of this, scientists have drawn inspirations by natural biological systems and their unique ability to heal an external wound, to develop a similar repair system within a material. Carbon and glass fiber reinforced polymers were manufactured following the wet lay up or the prepreg process. Microcapsules at contents, 5% or 10% by weight, vascular networks from wax and steel wires and finally reversible polymers were implemented within a composite as a potential self-healing system. Inspection techniques, including Ultrasonic C-Scan and Infrared Thermography, were applied, where possible. Optical microscopy revealed the disruption of the composite structural integrity, regarding the observed ply waviness and the resin reach zones around the vascular structures. Three point bending experiments determined the knock down factor, expressed as a decrease on flexural strength and modulus values, for each case, compared to the reference material. The reduction ranged from 12%-64% depending mainly not only to the selected manufacturing method but also to the different implemented healing system.

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