3D Printed Carbon Nanotubes Reinforced Polydimethylsiloxane Flexible Sensors for Tactile Sensing

Bhavya Jain, Krishnakant Phand, Vaibhav Jain, Indranil Lahiri, D. Lahiri
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Abstract

Technology is constantly evolving, and chronic health issues are on the rise. It is essential to have affordable and easy access to remote biomedical measurements. This makes flexible sensors a more attractive choice owing to their high sensitivity and flexibility along with low cost and ease of use. As an additional advantage, 3D printing has become increasingly popular in areas such as biomedicine, environment, and industry. This study demonstrates 3D-printed flexible sensors for tactile sensing. A biocompatible silicone elastomer such as polydimethylsiloxane (PDMS) with low elastic modulus and high stretchability makes an excellent wearable sensor material. Incorporating CNTs at varying concentrations (0.5, 1, 2)wt% enhances the sensor’s mechanical strength, conductivity, and responsiveness to mechanical strain. In addition to enhancing the thermal stability of the composite by 44%, multi-walled carbon nanotubes (MWCNTs) also enhanced the breaking strength by 57% with a 2 wt% CNT loading. Moreover, the contact angle values improved by 15%, making it a biomedical-grade hydrophobic surface. The electrical characteristics of these sensors reveal excellent strain sensitivity, making them perfect for monitoring finger movements and biomedical measurements. Overall, 2 wt% CNT-PDMS sensors exhibit optimal performance, paving the way for advanced tactile sensing in biomedical and industrial settings.
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用于触觉传感的 3D 打印碳纳米管增强型聚二甲基硅氧烷柔性传感器
技术在不断发展,慢性健康问题也在不断增加。因此,必须以低廉的价格和便捷的方式进行远程生物医学测量。因此,柔性传感器因其高灵敏度、灵活性、低成本和易用性而成为更具吸引力的选择。此外,3D 打印技术在生物医学、环境和工业等领域也越来越受欢迎。本研究展示了用于触觉传感的 3D 打印柔性传感器。聚二甲基硅氧烷(PDMS)是一种生物相容性硅弹性体,具有低弹性模量和高拉伸性,是一种极佳的可穿戴传感器材料。加入不同浓度(0.5、1、2)重量百分比的碳纳米管可增强传感器的机械强度、导电性和对机械应变的响应能力。多壁碳纳米管(MWCNTs)除了能将复合材料的热稳定性提高 44%,还能将 2 wt% CNT 负载的断裂强度提高 57%。此外,接触角值提高了 15%,使其成为生物医学级疏水表面。这些传感器的电气特性显示出出色的应变灵敏度,使其成为监测手指运动和生物医学测量的完美选择。总体而言,2 wt% CNT-PDMS 传感器表现出最佳性能,为生物医学和工业环境中的先进触觉传感技术铺平了道路。
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