Variable stiffness material and structural concepts for morphing applications

Variable stiffness material and structural concepts for morphing applications

Morphing, understood as the ability to undergo pronounced shape adaptations to optimally respond to a diversity of operational conditions, has been singled out as a future direction in the pursuit of maximised efficiency of lightweight structures. Whereas a certain degree of adaptivity can be accomp...

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Bibliographic Details
Published in:Progress in aerospace sciences Vol. 63; pp. 33 - 55
Main Authors: Kuder, Izabela K., Arrieta, Andres F., Raither, Wolfram E., Ermanni, Paolo
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-11-2013
Subjects:
Adaptive structures
Aerospace
Morphing
Variable stiffness
Wind turbines
Adaptive structures
Variable stiffness
Morphing
Wind turbines
Aerospace
Online Access:Get full text
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Summary:Morphing, understood as the ability to undergo pronounced shape adaptations to optimally respond to a diversity of operational conditions, has been singled out as a future direction in the pursuit of maximised efficiency of lightweight structures. Whereas a certain degree of adaptivity can be accomplished conventionally by means of mechanical systems, compliance allowing for substantial reversible deformability exhibits far more potential as a morphing strategy. A promising solution to the inherent contradiction between high stiffness and reversible deformation capacity posed by morphing is offered by introducing variable stiffness components. This notion indicates the provision of a controllable range of deformation resistance levels in place of fixed properties, as required by real-time shape adaptation dictated by maximum efficiency under changing external conditions. With special emphasis on the morphing context, the current review aims to identify the main tendencies, undertaking a systematic classification of existing approaches involving stiffness variability. Four broad categories in which variable stiffness has been applied to morphing are therefore distinguished and detailed: material engineering, active mechanical design, semi-active techniques and elastic structural behaviour. Adopting a wide perspective, the study highlights key capabilities, limitations and challenges. The need for attention directed to the variable stiffness strategy is recognised and the significance of intensive research activities in a highly integrated and multidisciplinary environment emphasised if higher maturity stages of the concepts are to be reached. Finally, the potential of emerging directions of semi-active design involving electro-bonded laminates and multi-stable structures is brought into focus.
ISSN:0376-0421
1873-1724
DOI:10.1016/j.paerosci.2013.07.001