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Bioinspired airwings: design and additive manufacturing of a geometrically graded microscale maple seed

Großmann, Alexander ; Klyk, Maximilian ; Kohn, Leonie ; Meyer, Guillaume ; Greiner, Matthias ; Yang, Yangyiwei ; Mittelstedt, Christian (2024)
Bioinspired airwings: design and additive manufacturing of a geometrically graded microscale maple seed.
In: Materials Today Communications
doi: 10.1016/j.mtcomm.2023.108014
Article, Bibliographie

Abstract

Additive manufacturing is a key enabler for the fabrication and industrial application of open-celled cellular lattice structures bearing significant potential for lightweight design with advantageous stiffness–weight ratio and reduced build time. For components with strut thicknesses in the micrometer region, however, the influence of the process dominates the quality and properties of the lattice component. This includes geometrical accuracy, surface roughness, internal porosity, nodal constrictions, and elongated grains in the microstructure. The utilization of process-property correlation in the additive design process is rarely shown in the available literature. In this contribution, we develop an ultralight thin-walled maple seed that exhibits a geometrically graded strut design to maintain center of gravity and load per area. This is done by a preliminary closed-form analytical consideration to determine the design space. Second, topology optimization is carried out to obtain a re-designable structure. Using non-dimensional scaling laws enables an accurate prediction of the desired strut thickness. The maple seed has been manufactured with each strut being assigned different process parameters according to the scaling law, coated with clear varnish, and subjected to a flight test as a proof of concept.

Item Type: Article
Erschienen: 2024
Creators: Großmann, Alexander ; Klyk, Maximilian ; Kohn, Leonie ; Meyer, Guillaume ; Greiner, Matthias ; Yang, Yangyiwei ; Mittelstedt, Christian
Type of entry: Bibliographie
Title: Bioinspired airwings: design and additive manufacturing of a geometrically graded microscale maple seed
Language: English
Date: January 2024
Publisher: Elsevier
Journal or Publication Title: Materials Today Communications
DOI: 10.1016/j.mtcomm.2023.108014
Abstract:

Additive manufacturing is a key enabler for the fabrication and industrial application of open-celled cellular lattice structures bearing significant potential for lightweight design with advantageous stiffness–weight ratio and reduced build time. For components with strut thicknesses in the micrometer region, however, the influence of the process dominates the quality and properties of the lattice component. This includes geometrical accuracy, surface roughness, internal porosity, nodal constrictions, and elongated grains in the microstructure. The utilization of process-property correlation in the additive design process is rarely shown in the available literature. In this contribution, we develop an ultralight thin-walled maple seed that exhibits a geometrically graded strut design to maintain center of gravity and load per area. This is done by a preliminary closed-form analytical consideration to determine the design space. Second, topology optimization is carried out to obtain a re-designable structure. Using non-dimensional scaling laws enables an accurate prediction of the desired strut thickness. The maple seed has been manufactured with each strut being assigned different process parameters according to the scaling law, coated with clear varnish, and subjected to a flight test as a proof of concept.

Additional Information:

Artikel-ID: 108014

Divisions: 11 Department of Materials and Earth Sciences
11 Department of Materials and Earth Sciences > Material Science
11 Department of Materials and Earth Sciences > Material Science > Mechanics of functional Materials
16 Department of Mechanical Engineering
16 Department of Mechanical Engineering > Institut für Leichtbau und Strukturmechanik (LSM)
Date Deposited: 11 Jan 2024 06:41
Last Modified: 11 Jan 2024 07:37
PPN: 51461465X
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