A review on the mechanical behaviour of microcellular and nanocellular polymeric foams: What is the effect of the cell size reduction?

IF 3.2 4区 工程技术 Q2 CHEMISTRY, APPLIED Journal of Cellular Plastics Pub Date : 2024-05-25 DOI:10.1177/0021955x241246066
Louise Le Barbenchon, Jean-Benoît Kopp
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Abstract

Research on nanocellular foams is motivated in part by the promise of physical properties, in particular mechanical properties, that can go beyond the classical mechanical framework. However, due to the difficulty in obtaining foams of a given density but different cell sizes, determining the effect of cell size on the mechanical properties of polymer foams remains a challenge. To overcome this difficulty, studies on the mechanical behaviour of mesocellular, microcellular and nanocellular polymer foams have been compiled in this review article. After describing the different cellular structures between meso-, micro- and nanocellular foams, the mechanical properties are examined as a function of relative density and cell size. It is shown that for small strains and at low strain rates, nanocellular foams exhibit mechanical behaviour predicted by the Gibson and Ashby model. Relative density remains the first important factor to be taken into account when studying the Young’s modulus and buckling stress of nanocellular foams. The focus then shifts to fracture properties, as microcellular foams have already been shown to be far superior to more conventional foams. As studies are still scarce and different methodologies have been used, no general conclusions can be drawn. However, the fracture and impact properties could be greatly improved by this change in scale. The local confinement of molecular chains in polymeric nanocellular foams or the relaxation of the triaxial stress state in front of the crack tip could explain these observations.
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微孔和纳米孔聚合物泡沫机械性能综述:细胞尺寸缩小有何影响?
对纳米细胞泡沫进行研究的部分原因是其物理特性,特别是机械特性有望超越传统的机械框架。然而,由于难以获得特定密度但不同细胞大小的泡沫,确定细胞大小对聚合物泡沫机械性能的影响仍是一项挑战。为了克服这一困难,本综述文章汇编了有关中孔、微孔和纳米孔聚合物泡沫机械性能的研究。在介绍了中孔、微孔和纳米孔泡沫的不同细胞结构后,文章研究了机械性能与相对密度和细胞大小的函数关系。研究表明,对于小应变和低应变率,纳米细胞泡沫表现出 Gibson 和 Ashby 模型所预测的机械性能。在研究纳米细胞泡沫的杨氏模量和屈曲应力时,相对密度仍然是首先要考虑的重要因素。然后重点转向断裂特性,因为微孔泡沫已被证明远远优于传统泡沫。由于研究还很少,而且采用的方法也不尽相同,因此无法得出一般性结论。不过,这种规模上的变化可能会大大改善断裂和冲击性能。聚合物纳米泡沫中分子链的局部限制或裂纹尖端前的三轴应力状态的松弛可以解释这些观察结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Cellular Plastics
Journal of Cellular Plastics 工程技术-高分子科学
CiteScore
5.00
自引率
16.00%
发文量
19
审稿时长
3 months
期刊介绍: The Journal of Cellular Plastics is a fully peer reviewed international journal that publishes original research and review articles covering the latest advances in foamed plastics technology.
期刊最新文献
I-WP geometry structural assessment: A theoretical, experimental, and numerical analysis Foam density measurement using a 3D scanner Effect of temperature on the mechanical behavior of pvc foams Preparation and energy absorption of flexible polyurethane foam with hollow glass microsphere A review on the mechanical behaviour of microcellular and nanocellular polymeric foams: What is the effect of the cell size reduction?
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