Quantifying the Human Perception: Development and Characterization of Textile-Based Capacitive Strain and Pressure Sensors

Mareen N Warncke, Carola H. Böhmer, P. Böhnke, Ann-Malin Schmidt, A. Nocke, Johannes Mersch, Chokri Cherif
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Abstract

In the research field of smart textiles, one main goal concerns quantifying environmental forces acting on the wearer's body since textiles, acting as the boundary between the two, are an excellent way of integrating sensors. Integrating strain and pressure sensors into wearables promises a simple way of monitoring a person's posture and forces acting on their body. Sensors relying on a capacitive measuring principle are highly suitable for this, as they are less sensitive to changes in temperature than resistive or inductive types. In this paper, textile-based capacitive sensors are produced by braiding conductive yarns with and without an electrically insulating TPU sheath. The produced sensors are analyzed in cyclic strain and compression tests. Moreover, their behavior under changing temperatures is tested to prove their resilience against environmental changes. To extend their capabilities from an integral measurement to a localized assessment of the strain, time-domain-reflectometry (TDR) is employed. Finally, the sensors are integrated into a flexible actuated bending beam, and their adoption for soft robotics is discussed. Strain is tested cyclically, showing good long-term stability. Pressure sensitivity is measured in a static compression test under increasing force. TDR is used to localize strain in two discreet sections of the sensor. Although strain could not be quantified through TDR, characteristic points in the measured response signal indicating the position of the strain were identified. Textile-based capacitive sensors are suitable for strain up to 10 % and pressure up to 8 N. The determined gauge factors are satisfactory, with strain sensors inherently having a higher gauge factor than pressure sensors. Furthermore, they display good long-term stability and no adverse reaction to changes in temperature. TDR is proven to provide localization of strain in flexible sensors.
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量化人类感知:基于纺织品的电容式应变和压力传感器的开发与特性分析
在智能纺织品研究领域,一个主要目标是量化作用在穿戴者身体上的环境力,因为纺织品作为两者之间的边界,是集成传感器的绝佳方式。将应变和压力传感器集成到可穿戴设备中,是监测人的姿势和作用在其身体上的力的一种简单方法。与电阻式或电感式传感器相比,基于电容式测量原理的传感器对温度变化的敏感性较低,因此非常适合用于此目的。本文通过编织导电纱线(带或不带电绝缘热塑性聚氨酯护套)制作了基于纺织品的电容式传感器。在循环应变和压缩测试中对所生产的传感器进行了分析。此外,还测试了它们在温度变化下的行为,以证明它们对环境变化的适应能力。为了将传感器的功能从整体测量扩展到局部应变评估,采用了时域反射测量法(TDR)。最后,将传感器集成到柔性驱动弯曲梁中,并讨论了其在软机器人技术中的应用。对应变进行了周期性测试,显示出良好的长期稳定性。压力灵敏度是在增加力的静态压缩测试中测量的。使用 TDR 对传感器的两个不同部分进行应变定位。虽然无法通过 TDR 量化应变,但在测量的响应信号中确定了表明应变位置的特征点。纺织电容式传感器适用于最大 10 % 的应变和最大 8 N 的压力。确定的测量系数令人满意,应变传感器的测量系数本来就比压力传感器高。此外,它们还具有良好的长期稳定性,对温度变化没有不良反应。事实证明,TDR 可以对柔性传感器中的应变进行定位。
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