Highly-Stretchable Biomechanical Strain Sensor using Printed Liquid Metal Paste

2018 IEEE Biomedical Circuits and Systems Conference (BioCAS) Pub Date : 2018-10-01 DOI:10.1109/BIOCAS.2018.8584671

Callen Votzke, U. Daalkhaijav, Y. Mengüç, M. Johnston

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引用次数: 19

Abstract

Stretchable electronic circuits and systems will be critical for future wearable devices and smart textiles, where existing rigid and flexible fabrication approaches severely limit conformal deformation. This is especially true for wearable sensors and actuators, critical for emerging physical human-machine interfaces and stretchable electrical interconnects. In this work, we present a 3D-printed, highly-stretchable strain sensor that uses a modified liquid metal paste to provide high-strain conductors. This approach provides near-zero hysteresis compared with nanotube-based inks, and improved conductivity over carbon- and metal-based inks, both critical for integration of soft sensors with stretchable measurement circuitry. We present an approach for fabrication of the wearable sensors and demonstrate stable conductivity of the liquid metal paste with near-zero hysteresis over 375 cycles at 200% strain. The device is demonstrated for measurement of elbow flexion angle, providing proof-of-concept of the approach for biomechanical sensor applications and wearable human-machine interfaces.

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使用印刷液态金属膏体的高可拉伸生物力学应变传感器

可拉伸电子电路和系统对未来的可穿戴设备和智能纺织品至关重要，现有的刚性和柔性制造方法严重限制了保形变形。对于可穿戴传感器和执行器来说尤其如此，这对于新兴的物理人机界面和可拉伸的电气互连至关重要。在这项工作中，我们提出了一种3d打印的，高度可拉伸的应变传感器，它使用改性液态金属糊状物来提供高应变导体。与基于纳米管的油墨相比，这种方法提供了接近零的滞后，并且优于碳基和金属基油墨的导电性，这对于软传感器与可拉伸测量电路的集成至关重要。我们提出了一种制造可穿戴传感器的方法，并证明了液态金属膏体在200%应变下的375次循环中具有接近零迟滞的稳定电导率。该设备用于测量肘关节弯曲角度，为生物力学传感器应用和可穿戴人机界面提供了概念验证。

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2018 IEEE Biomedical Circuits and Systems Conference (BioCAS)

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