Carbon Nanotubes Reinforced Natural Rubber Composites

Carbon Nanotubes - Redefining the World of Electronics [Working Title] Pub Date : 2021-02-24 DOI:10.5772/INTECHOPEN.95913

A. Krainoi, J. Johns, E. Kalkornsurapranee, Y. Nakaramontri

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引用次数: 4

Abstract

Several advanced methods have been introduced to disperse CNTs in the NR matrix. Various aspects highlighted in this chapter include the mixing processes such as melt mixing and latex mixing methods. As well as, formations of functional groups on the surfaces of CNT using silane coupling agents (i.e., ex-situ and in-situ functionalization). Moreover, hybrid CNT are beneficial to achieve better electrical conductivity of NR/CNT composites. These efforts are aimed to reduce the percolation threshold concentration in the NR composites for application as conducting composites based on electrically insulating rubber matrix. Sensor application is developed based on conducting NR composites. NR composites showed changing of resistivity during elongation termed as piezoresistivity. The most commonly used rubber matrices such as NR, ENR and IR are mixed with a combination of CNT and CB fillers as hybrid filler. The presence of linkages in the ENR composites results in the least loss of conductivity during external strain. It is found that the conductivity becomes stable after 3000 cycles. This is found to be similar to the NR-CNT/CB composite, while a few cycles are needed for IR-CNT/CB owing to the higher filler agglomeration and poor filler-rubber interactions. This is attributed to the polar chemical interactions between ENR and the functional groups on the surfaces of CNT/CB.

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碳纳米管增强天然橡胶复合材料

目前已有几种先进的方法将碳纳米管分散到NR基体中。本章强调的各个方面包括混合过程，如熔融混合和乳胶混合方法。以及，使用硅烷偶联剂在碳纳米管表面形成官能团(即，原位和原位功能化)。此外，杂化碳纳米管有利于NR/CNT复合材料获得更好的导电性。这些努力的目的是为了降低NR复合材料的渗透阈值浓度，从而应用于基于电绝缘橡胶基体的导电复合材料。在导电NR复合材料的基础上，开发了传感器应用。NR复合材料在伸长过程中表现出电阻率的变化，称为压阻性。最常用的橡胶基体如NR、ENR和IR是与CNT和CB填料的组合混合作为杂化填料。在ENR复合材料中存在的链接导致在外部应变期间电导率损失最小。经过3000次循环后，电导率趋于稳定。这与NR-CNT/CB复合材料相似，而IR-CNT/CB复合材料由于填料团聚率高，填料与橡胶相互作用差，需要较少的循环时间。这归因于ENR与CNT/CB表面官能团之间的极性化学相互作用。

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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Carbon Nanotubes - Redefining the World of Electronics [Working Title]

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