Fankai Lin , Mingxin Ye , Xin Min , Zhaohui Huang , Fei Cheng , Xiaozhi Hu
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引用次数: 0
摘要
本研究旨在通过随机分布的纳米/微米芳纶浆料(AP)纤维的原位交联,为强度更高、更可靠的单向玻璃纤维(UD-GF)复合材料提供一种有效的结构设计策略。由于 AP 交联和 "砖浆 "结构,横向和纵向的抗弯强度和刚度都有大幅提高。当 AP 值为 8 g/m2 时,挠曲强度(横向和纵向)提高了 60-70%,"有效模量 "提高了 20-37%。纵向强度的明显改善归功于超薄 AP 中间膜提供的树脂加固和层间交联,以及由此带来的压缩下微弯曲阻力的改善。由于稀疏分布的纳米/微 AP 可以很容易地融入拉挤和预浸料制造工艺中,因此这项研究不仅对微观力学研究具有重要意义,而且还为制造工艺的改进提供了可能。
Micro-buckling resistant unidirectional glass fiber composites with excellent transverse and longitudinal flexural properties from cross-linking by nano-/micro-aramid fibers
This study aims at obtaining an effective structural design strategy for stronger and more reliable Unidirectional glass fiber (UD-GF) composites by in-situ formed cross-linking from randomly distributed nano-/micro- Aramid pulp (AP) fibers. The flexural strength and stiffness have shown substantial improvements in both the transverse and longitudinal directions due to the AP cross-linking and the “brick-slurry” structure. With AP of 8 g/m2, up to 60–70 % improvement in flexural strengths (both transverse and longitudinal directions) and up to 20–37 % improvement in “effective modulus” have been observed. The noticeable longitudinal improvements have been attributed to the resin reinforcement and interlayer cross-linking provided by ultra-thin AP interlayers, and the resultant improvement in micro-buckling resistance under compression. Since sparsely distributed nano-/micro-AP can be readily incorporated in pultrusion and pre-preg manufacturing processes, this study is not only important for micro-mechanism study, but also provides a plausible improvement in manufacturing.
期刊介绍:
Composites Science and Technology publishes refereed original articles on the fundamental and applied science of engineering composites. The focus of this journal is on polymeric matrix composites with reinforcements/fillers ranging from nano- to macro-scale. CSTE encourages manuscripts reporting unique, innovative contributions to the physics, chemistry, materials science and applied mechanics aspects of advanced composites.
Besides traditional fiber reinforced composites, novel composites with significant potential for engineering applications are encouraged.
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