期刊
IEEE-ASME TRANSACTIONS ON MECHATRONICS
卷 -, 期 -, 页码 -出版社
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TMECH.2022.3233669
关键词
Sensors; Hair; Shape; Springs; Liquids; Impedance; Fabrication; Biomimetics; force and tactile sensing; soft robot materials and design; soft sensors and actuators
This article presents the design of a soft airflow sensor that can detect the direction and magnitude of airflow using rapid prototyping. The sensor consists of an artificial hair structure and conductive ionogel channels. The sensor shows reliable responses to unidirectional airflows ranging from 6 to 13 m/s, and a clear relationship between applied loads and sensor outputs is observed. The proposed airflow sensor is also successfully applied to a small uncrewed ground vehicle for stable operation through atmospheric disturbance detection.
This article describes the design of a soft airflow sensor capable of detecting the direction and the magnitude of airflow, taking advantage of an additive manufacturing technique for rapid prototyping. The sensor consists of an artificial hair structure and conductive ionogel channels. The artificial hair, made by 3-D printing, is designed to maximize the moments at the base caused by the airflows applied to the hair structure. The ionogel channels are directly printed on a flexible printed circuit board and then embedded in an elastomeric layer. A compact readout circuit is prepared to acquire the impedance information from the sensing channels. The sensor shows reliable and repeatable responses to unidirectional airflows ranging from 6 to 13 m/s. A clear relationship between the applied loads and the sensor outputs is observed. We also demonstrate the performance and the application of the proposed airflow sensor by installing it on a small uncrewed ground vehicle that achieves stable operation through the detection of atmospheric disturbances.
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