Experimental Study on Polymer Nanocomposites Based Strain Sensors for Structural Health Monitoring

Journal of Minerals and Materials Characterization and Engineering Pub Date : 2021-08-26 DOI:10.4236/jmmce.2021.95034

R. Kiran, Kupparavalli Ramamurthy Prakash, P. Chandra, Venkatarayappa Ravi Kumar, Padubidere Bhaskara Asha, C. Rao

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引用次数: 1

Abstract

The aim is to develop a mechanically flexible polymer nanocomposite film-based strain sensors that could act towards sustainable structural health monitoring for civil structures. The developed polymer nanocomposite film combinations will be monitored for their structural, electrical and mechanical behaviors and the optimized formulations will be tried for strain sensing applications. The films were cast by using PVA as the base polymer and copper doped silver nitrate as the nanofiller along with the use of glycine as fuel which is a combination of silver and copper nitrate. After preparing the films, they were tested for conductivity under tensile loading using a digital multi meter connected to a UTM. The samples were subjected to XRD, FTIR and SEM for further analysis. The results of the experiments shown I-V characteristics of PVA-CuAgO composites from 5% to 25% CuAgO have been increased tremendously with the incorporation of filler material. For 100 V, the maximum current value obtained for plain PVA is only 7.7E-8 A, whereas CuAgO particles shown 0.0025 A at 5% reinforcements and further increased nearly to 0.025 A for 25% of CuAgO particles into the PVA matrix.

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基于聚合物纳米复合材料的结构健康监测应变传感器实验研究

目的是开发一种机械柔性聚合物纳米复合薄膜应变传感器，可用于土木结构的可持续结构健康监测。开发的聚合物纳米复合薄膜组合将被监测其结构、电气和机械行为，优化的配方将被用于应变传感应用。以PVA为基体聚合物，掺杂铜的硝酸银为纳米填料，以甘氨酸为燃料(甘氨酸是银和硝酸铜的混合物)浇铸薄膜。在制备薄膜后，使用连接到UTM的数字万用表测试薄膜在拉伸载荷下的导电性。采用XRD、FTIR、SEM对样品进行进一步分析。实验结果表明，在5% ~ 25% CuAgO范围内，填料的掺入大大提高了PVA-CuAgO复合材料的I-V特性。在100 V时，普通PVA得到的最大电流值仅为7.7E-8 A，而CuAgO颗粒在5%增强时的电流值为0.0025 A，当CuAgO颗粒加入PVA基体时，电流值进一步增加到接近0.025 A。

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Journal of Minerals and Materials Characterization and Engineering

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