Actuation of Liquid Flow by Guided Acoustic Waves on Punched Steel Tapes with Protruding Loop

doi:10.1007/s42235-021-0051-x

Journal of Bionic Engineering ›› 2021, Vol. 18 ›› Issue (3): 534-547.doi: 10.1007/s42235-021-0051-x

Actuation of Liquid Flow by Guided Acoustic Waves on Punched Steel Tapes with Protruding Loop

lexander Backer*, Johannes Landskron, Klaus Stefan Drese, Gerhard Lindner

Institute of Sensor and Actuator Technology, Coburg University of Applied Sciences and Arts, 96450 Coburg, Germany

收稿日期:2019-08-08 修回日期:2020-03-05 接受日期:2020-04-30 出版日期:2021-05-10 发布日期:2021-11-30
通讯作者: Alexander Backer E-mail:alexander.backer@hs-coburg.de
作者简介:lexander Backer*, Johannes Landskron, Klaus Stefan Drese, Gerhard Lindner

Actuation of Liquid Flow by Guided Acoustic Waves on Punched Steel Tapes with Protruding Loop

lexander Backer*, Johannes Landskron, Klaus Stefan Drese, Gerhard Lindner

Institute of Sensor and Actuator Technology, Coburg University of Applied Sciences and Arts, 96450 Coburg, Germany

Received:2019-08-08 Revised:2020-03-05 Accepted:2020-04-30 Online:2021-05-10 Published:2021-11-30
Contact: Alexander Backer E-mail:alexander.backer@hs-coburg.de
About author:lexander Backer*, Johannes Landskron, Klaus Stefan Drese, Gerhard Lindner

摘要/Abstract

摘要： In a biomimetic approach the feasibility of liquid flow actuation by vibrating protruding structures excited via guided acoustic waves is investigated. Inspired by periodically beating cilia the loop part of a punched metallic hook-and-loop tape with tilted protruding loops was used as a waveguide for plate waves in water. Such waves were excited in the frequency range of 110 Hz to 220 Hz by directly coupling the tape to a loudspeaker membrane. A flow generated in the tilt direction of the loops with velocities up to
60 mm·s?1 was visualized by ink droplets deposited on the tape. The phenomenon persisted, when the protruding length of the loops was reduced by decreasing the protrusion angle. However, after closing the punch holes near the loops with sticking tape streaming could not be observed any longer. The same happened with open punch holes when the ink was replaced by glycerol. Low-frequency acoustic streaming around vibrating sharp edges is proposed as an explanation for the observed phenomena. Applications are expected with respect to the modification of flow profiles and the enhancement of transport processes along and across liquid-solid boundaries.

关键词: bio-inspired, guided acoustic waves, metallic hook-and-loop tape, artificial cilia, liquid propulsion

Abstract: In a biomimetic approach the feasibility of liquid flow actuation by vibrating protruding structures excited via guided acoustic waves is investigated. Inspired by periodically beating cilia the loop part of a punched metallic hook-and-loop tape with tilted protruding loops was used as a waveguide for plate waves in water. Such waves were excited in the frequency range of 110 Hz to 220 Hz by directly coupling the tape to a loudspeaker membrane. A flow generated in the tilt direction of the loops with velocities up to
60 mm·s?1 was visualized by ink droplets deposited on the tape. The phenomenon persisted, when the protruding length of the loops was reduced by decreasing the protrusion angle. However, after closing the punch holes near the loops with sticking tape streaming could not be observed any longer. The same happened with open punch holes when the ink was replaced by glycerol. Low-frequency acoustic streaming around vibrating sharp edges is proposed as an explanation for the observed phenomena. Applications are expected with respect to the modification of flow profiles and the enhancement of transport processes along and across liquid-solid boundaries.

Key words: bio-inspired, guided acoustic waves, metallic hook-and-loop tape, artificial cilia, liquid propulsion

lexander Backer, Johannes Landskron, Klaus Stefan Drese, Gerhard Lindner. Actuation of Liquid Flow by Guided Acoustic Waves on Punched Steel Tapes with Protruding Loop [J]. Journal of Bionic Engineering, 2021, 18(3): 534-547.

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Actuation of Liquid Flow by Guided Acoustic Waves on Punched Steel Tapes with Protruding Loop

Actuation of Liquid Flow by Guided Acoustic Waves on Punched Steel Tapes with Protruding Loop

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