Mechanical behavior of stretchable conductive materials based on elastomeric core: experimental and theoretical simulation

Avia J. Bar, Joey Mead, Hanna Dodiuk, Samuel Kenig
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Abstract

The mechanical behavior of braided carbon nanotube yarns (CNTYs) on an elastomeric core to produce stretchable conductive materials were theoretically modeled and experimentally studied under tension. The elastomeric core served as the stretchable spring and the CNTYs braiding, with shape changing capabilities, as the conductive shell. A variety of samples were produced having various braiding angles on an elastomeric core and subsequently loaded in tension, and their stress–strain behavior was characterized. The model predicts the stress–strain behavior of the composite as a function of the initial braiding angle and the number of pitches. The innovative aspect was included in the model related to the friction between the braid and the core. Results indicated good agreement between the theoretical simulations and the experimental results which was not discussed in previous studies. Since the rate of the diameter decrease of the CNTYs braid was higher than that of the elastomeric core diameter, squeezing out of the core through the braid inter yarn space occurred. This limited the maximum potential extension of the braid. Thus, a critical strain was defined where the braid came into contact with the core. The addition of the friction stresses made a significant contribution to the overall stresses and the accuracy of the theoretical simulation, and its agreement with the experimental results. An apparent friction coefficient was proposed to account for the effect of the elastomer core/braid interactive restriction and squeezing out of the elastomer through the braiding, as observed in experimental results. As the CNTYs are conductive, a stretchable conductive composite was obtained having a resistivity of 9.05 × 10–4 Ohm*cm, which remained constant throughout the tensile loading until failure and under cyclic loading.

基于弹性体芯的可拉伸导电材料的力学行为:实验与理论模拟
研究了在弹性芯上编织碳纳米管纱线(CNTYs)在拉伸作用下的力学行为。弹性体芯作为可拉伸弹簧,具有形状变化能力的CNTYs编织作为导电壳。在弹性体芯上制作了具有不同编织角度的各种样品,并对其进行了拉伸加载,并对其应力-应变行为进行了表征。该模型预测了复合材料的应力-应变行为作为初始编织角和节数的函数。创新的方面被包括在与编织与芯之间的摩擦有关的模型中。结果表明,理论模拟与实验结果吻合较好,这在以往的研究中没有得到讨论。由于CNTYs编织线直径减小的速率大于弹性体芯直径减小的速率,因此会产生从编织线间挤出芯的现象。这限制了辫子的最大潜在延伸。因此,在编织与芯接触的地方定义了临界应变。摩擦应力的加入对理论模拟的总应力和精度有显著的贡献,且与实验结果吻合。根据实验结果,提出了一个表观摩擦系数来解释弹性体芯/编织相互作用的限制和通过编织挤出弹性体的影响。由于CNTYs具有导电性,得到的可拉伸导电复合材料的电阻率为9.05 × 10-4 Ohm*cm,在整个拉伸加载过程中电阻率保持恒定,直至失效和循环加载。
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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