3D Reticulated Actuator Inspired by Plant Up-Righting Movement Through a Cortical Fiber Network

Overview

Journal Biomimetics (Basel)

Date 2021 Jun 2

PMID 34071936

Citations 2

Authors

Tom Masselter

Olga Speck

Thomas Speck

Affiliations

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Abstract

Since most plant movements take place through an interplay of elastic deformation and strengthening tissues, they are thus ideal concept generators for biomimetic hingeless actuators. In the framework of a biomimetic biology push process, we present the transfer of the functional movement principles of hollow tubular geometries that are surrounded by a net-like structure. Our plant models are the recent genera (balsa) and (papaya) as well as the fossil seed fern , which hold a net of macroscopic fiber structures enveloping the whole trunk. Asymmetries in these fiber nets, which are specifically caused by asymmetric growth of the secondary wood, enable the up-righting of inclined and stems. In a tubular net-like structure, the fiber angles play a crucial role in stress-strain relationships. When braided tubes are subjected to internal pressure, they become shorter and thicker if the fiber angle is greater than 54.7°. However, if the fiber angle is less than 54.7°, they become longer and thinner. In this article, we use straightforward functional demonstrators to show how insights into functional principles from living nature can be transferred into plant-inspired actuators with linear or asymmetric deformation.

Citing Articles

Bridging the Gap: From Biomechanics and Functional Morphology of Plants to Biomimetic Developments.

Speck O, Speck T Biomimetics (Basel). 2021; 6(4).

PMID: 34698061 PMC: 8544236. DOI: 10.3390/biomimetics6040060.

Biomimetics and Education in Europe: Challenges, Opportunities, and Variety.

Speck O, Speck T Biomimetics (Basel). 2021; 6(3).

PMID: 34449558 PMC: 8395498. DOI: 10.3390/biomimetics6030049.

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