由共连续土工聚合物和 3d 印刷聚合物制成的生物启发复合材料的力学性能

Siyuan Pang, Mahmoud A. Mahrous, Ana Carolina Constancio Trindade, Andrij Kozych, Nupur Kale, Waltraud M. Kriven, Iwona Jasiuk
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引用次数: 0

摘要

土工聚合物是新兴的低密度陶瓷材料,制造简单,弹性模量和强度高,但韧性低。纤维增强材料已被用于实现各种韧性行为,但人们对聚合物框架结构中添加土工聚合物的情况知之甚少。因此,本文从骨骼的纳米结构中汲取灵感,研究了一种互穿共连续复合材料,该复合材料由土工聚合物(作为刚性脆性相)和三维打印聚合物(PA12 White)(作为软性可变形相)组成。通过单轴压缩和四点弯曲试验对该复合材料的机械性能和破坏模式进行了实验研究。共连续网络限制了土工聚合物内部的脆性开裂,并减少了聚合物中的应变局部化。结果表明,在特定几何形状下,复合材料的强度(56.11 ± 2.12 MPa)和弹性模量(6.08 ± 1.37 GPa)均高于三维打印聚合物,韧性(5.98 ± 0.24 MJ/mm3)也高于土工聚合物。形状效应研究表明,与矩形棱柱结构相比,立方体结构具有更高的弹性模量和强度,但韧性较低。对尺度效应的研究表明,在保持体积尺寸一致的情况下,增加周期性单元格的数量可提高强度和韧性,尽管在统计上弹性模量没有显著变化。因此,本文通过实验展示了一种新颖的受生物启发的互渗土工聚合物-聚合物复合材料设计,该设计具有更高的强度和韧性。本文受版权保护。本文受版权保护,保留所有权利。
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Mechanical behavior of bio-inspired composites made of co-continuous geopolymer and 3D-printed polymer

Geopolymers (GPs) are emerging, low-density ceramic materials that are simple to manufacture, with high elastic modulus and strength, albeit with low toughness. Fiber reinforcements have been used to achieve varied ductile behaviors, but little is known about the GP addition to polymeric frame structures. Thus, drawing inspiration from the nanostructure of bones, this paper investigated an interpenetrating, co-continuous composite consisting of a GP as the stiff but brittle phase, and a 3D-printed polymer (PA12 White) as the soft and deformable phase. The composite mechanical properties and failure modes were studied experimentally using uniaxial compression and four-point bending tests. The co-continuous network constrained brittle cracking within the GP and reduced strain localization in the polymer. The results showed that the composite had higher strength (56.11 ± 2.12 MPa) and elastic modulus (6.08 ± 1.37 GPa) than the 3D-printed polymer and had higher toughness (5.98 ± 0.24 MJ/mm3) than the GP for the specific geometries examined. The shape effect study demonstrated that cubic structures had higher elastic modulus and strength but at the expense of lower toughness when compared to rectangular prism structures. The study of scale effects indicated that increasing the number of periodic unit cells while maintaining consistent bulk dimensions led to augmented strength and toughness, albeit without statistically significant alterations in elastic modulus. Thus, this paper presents an experimental realization of a novel, bio-inspired, interpenetrating, GP–polymer composite design, offering improved strength and toughness. It also provides valuable insights into the shape and size effects on the mechanical properties of this new composite.

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