Department of Mechanical Engineering, ECB 301J, University of Alaska Anchorage, 3211 Providence Dr., Anchorage, AK 99508, USA.
Department of Mechanical Engineering, Khalifa University of Science and Technology, Healthcare Engineering Innovation Center, SAN Campus, Abu Dhabi P.O. Box 127788, United Arab Emirates.
Sensors (Basel). 2022 May 24;22(11):3987. doi: 10.3390/s22113987.
We propose a sensor design for measurement of large strains where direct application of a fiber optic strain gauge is impossible due to the stiffness mismatch between the optical fiber and the structure under test. The sensor design is based on a rhombus type compliant mechanism, which functions to attenuate input strain and transfer it to the ends of the sensing beam with the mounted optical strain gauge. We developed an analytical model of the sensor, which allows us to relate actuation forces, input displacement/strain, and output strain. The analytical model was verified with the finite element analysis and validated against an experimental prototype. The prototype sensor was able to handle input strains exceeding ±2.5 × 10 µε. Potential application areas of the proposed sensor include compliant elastomeric structures, wearables, and soft robotics.
我们提出了一种传感器设计,用于测量大应变,由于光纤和待测结构之间的刚度不匹配,直接应用光纤应变计是不可能的。传感器设计基于菱形柔顺机构,其功能是衰减输入应变,并将其传递到安装有光纤应变计的传感梁的末端。我们开发了传感器的分析模型,该模型允许我们将激励力、输入位移/应变和输出应变联系起来。该分析模型通过有限元分析进行了验证,并通过实验原型进行了验证。原型传感器能够处理超过±2.5×10µε的输入应变。所提出的传感器的潜在应用领域包括柔顺弹性结构、可穿戴设备和软机器人。