Andreas Meyer, Martin Wagner, S. Gratz-Kelly, S. Nalbach, Paul Motzki
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引用次数: 0
摘要
介电弹性体传感器兼具灵活性和高度的可集成性以及精确的传感能力,因此可以集成到各种应用中。由于这些集成机会,特别是在智能纺织品领域,这些传感器系统可以大显身手。基于电阻式和电容式传感器的鞋用传感器嵌体能够对我们脚上的负荷和负荷分布进行部分监测,但与鞋轴之间的相互作用仍是未知数。这项工作正在研究将新型传感器集成到鞋轴中,并结合无线实时测量的方法。鞋内的这种新型传感器系统为数据采集奠定了基础,最终可为患有糖尿病足综合症的糖尿病患者提供支持,为分析行走模式的运动员提供支持,并将安全鞋带入数字化时代。这篇论文展示了传感器概念以及相应的电子产品开发。第一款智能鞋集中整合了分布在鞋内的六个轴传感器,并对其进行实时测量。这款鞋是与皮尔马森 Prüf- und Forschungsinstitut 合作设计和制造的。通过对传感器信号的评估,可以对不同的负载情况进行分析。
Concept studies and application development of textile integrated dielectric elastomer sensors for smart shoe technologies
The combination of flexibility and high integrability as well as their precise sensing capability enable dielectric elastomer sensors to be integrated into a variety of applications. Because of these integration opportunities especially in the field of smart textiles these sensor systems can make a difference. Sensor inlays for shoes based on resistive and capacitive sensors enable a partial monitoring of the loads and load distributions on our feet while the interaction with the shoe shaft remains unknown. The novel sensor integration into the shaft combined with a wireless real-time measurement is being studied in this work. This new sensor system within the shoe creates the basis for the data acquisition to finally support diabetic patients who suffer under the diabetic foot syndrome, to support athletes analyzing walking patterns as well as bringing safety shoes to a digital age. This contribution displays sensor concepts as well as the corresponding electronics development. The first smart shoe concentrates on the integration of six shaft sensors distributed over the shoe and their measurement in real-time. The shoe is designed and manufactured in collaboration with the Prüf- und Forschungsinstitut Pirmasens. The evaluation of the sensor signals allows the analysis of different load scenarios.