基于摩擦电纳米发电机的假肢触觉传感系统

Li Chien Shen, Kuie-Bin Chang, Zong-Hong Lin, Jin-Jia Hu
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摘要

被截肢者残肢与义肢窝之间的界面应力分布被认为与舒适性直接相关。假体承口是定制的,目前的技术非常成熟,无论是手工成型还是3D扫描,都可以制作出适合患者残肢的假体,但当患者实际佩戴假体时,由于佩戴时间长,异物摩擦,佩戴者仍然可能会感到不适。因此,研究人员一直对量化这些界面应力感兴趣,以便评估对残肢的任何潜在损伤的程度,并通过避免对假体进行重复更改来降低假体制造成本。然而,现有的压力传感器不仅价格昂贵,而且与残肢存在兼容性问题,在外界环境的影响下容易出现不稳定,极大地影响了该区域的实际受力读数。本研究开发了一种基于摩擦电纳米发电机(TENG)的触觉传感器,该传感器利用摩擦电效应收集力能,其材料选择广泛、制造简单、自动驾驶等特性越来越受到人们的关注。在我们的研究中,我们提出了一种基于聚二甲基硅氧烷(PDMS)和聚己内酯(PCL)两种材料的多点阵列触觉传感器。PDMS表面具有液滴微观结构,通过静电纺丝将PCL制成纳米纤维薄膜,增加接触材料的比表面积,从而改善器件的输出特性,实现更大的检测范围和灵敏度。除了优异的10,000次循环耐久性外,该器件的特性在不同湿度和温度下也表现出良好的稳定性。最后,我们将该多点阵列传感器与多通道测量系统集成在一起,将其附着在3d打印残肢和假肢模型的接触界面上,并从压缩侧采集实时通信信号,以验证该应用的可行性。我们相信这种新颖的设计提供了一种新的方法来改善假肢佩戴的舒适性,并且具有相当大的潜力。
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A Tactile Sensing System Based on the Triboelectric Nanogenerator for Prosthetic Application
The distribution of interfacial stress between the amputee's residual limb and the prosthetic socket is thought to be directly related to comfort. Prosthetic sockets are custom-made and the current technology is very mature, whether, by manual molding or 3D scanning, the prosthesis can be made to fit the patient's residual limb, but when the patient actually wears the prosthesis, the wearer may still experience discomfort due to long wear time and foreign body friction. Therefore, researchers have been interested in quantifying these interfacial stresses in order to assess the extent of any potential damage to the residual limb and to reduce the cost of prosthetic fabrication by avoiding repetitive changes to the prosthesis. However, the existing pressure sensors are not only expensive but also have compatibility problems with the residual limb and are prone to instability under the influence of the external environment, which greatly affects the actual force readings in the area. Here, we developed a tactile sensor by triboelectric nanogenerator(TENG), which collects force energy by triboelectric effect, and its wide material selection, easy fabrication, and self-driving properties are receiving more and more attention. In our research, we propose to develop a multi-point array tactile sensor based on two materials: polydimethylsiloxane (PDMS) and polycaprolactone (PCL). The surface of PDMS has a droplet microstructure, and PCL is made into a nanofiber film by electrospinning to increase the specific surface area of the material in contact to improve the output characteristics of the device and achieve a larger detection range and sensitivity. In addition to the excellent durability at 10,000 cycles, the characteristics of the device also show good stability at different humidity and temperature. Finally, we integrated this multi-point array sensor with a multi-channel measurement system, attached it to the contact interface of a 3D-printed residual limb and prosthetic model, and collected real-time correspondence signals from the compressed side to demonstrate the feasibility of this application. We believe that this novel design offers a new approach to improve the comfort of prosthetic wear for amputees and has considerable potential.
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