Economically viable electromechanical tensile testing equipment for stretchable sensor assessment

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Ardi Wiranata , Witnadi Dardjat Premiaji , Widya Kartika , Burhan Febrinawarta , Zebing Mao , Hifni Mukhtar Ariyadi , Nyayu Aisyah , Ryan Anugrah Putra , Kevin G.H. Mangunkusumo , Muhammad Akhsin Muflikhun
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Abstract

The growing interest in soft robotics increases the demand for stretchable sensors. The high performance of stretchable sensors depends much on the linearity, reliability and hysteresis of the stretchable conductive materials. In the applications of conductive materials such as in dielectric elastomer actuators, a stretchable conductive material should maintain the conductivity while sustaining large and multiple cycles of stretch and release tests. To understand the stretchable electrode quality, researchers should perform an electromechanical test. However, researchers require a high investment cost to use a professional type of electromechanical tensile test. In this research, we proposed an economically viable version of the Do-it-yourself (DIY) electromechanical tensile test (EMTT) to resolve the high investment cost problems. The DIY-EMTT is based on the Arduino-nano module. We integrate the load cell, displacement sensor, motor linear stage and DIY resistance meter. We can use the DIY mechanism to suppress the instrumental cost from thousands to hundreds of dollars. Furthermore, we provide a step-by-step guide to build the DIY-EMTT. We expect our DIY-EMTT to boost stretchable sensor development in soft robotics.

Abstract Image

用于评估可拉伸传感器的经济可行的机电拉伸测试设备
随着人们对软机器人技术的兴趣与日俱增,对可拉伸传感器的需求也随之增加。可拉伸传感器的高性能在很大程度上取决于可拉伸导电材料的线性、可靠性和滞后性。在导电材料的应用中,例如在介电弹性体致动器中,可拉伸导电材料应在承受大量、多次拉伸和释放循环测试时保持导电性。为了解拉伸电极的质量,研究人员应进行机电测试。然而,研究人员使用专业的机电拉伸测试需要高昂的投资成本。在这项研究中,我们提出了一种经济可行的 "自己动手(DIY)"机电拉伸试验(EMTT),以解决投资成本高的问题。DIY-EMTT 基于 Arduino 纳米模块。我们集成了称重传感器、位移传感器、电机线性平台和 DIY 电阻表。我们可以利用 DIY 机制将仪器成本从数千美元降至数百美元。此外,我们还提供了 DIY-EMTT 的制作步骤指南。我们期待我们的 DIY-EMTT 能够推动软机器人领域可拉伸传感器的发展。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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