The mechanics of composite corrugated structures: A review with applications in morphing aircraft

Dayyani, Iman; Shaw, Alexander D.; Flores, Erick I. Saavedra; Friswell, Michael I.

doi:10.1016/j.compstruct.2015.07.099

Cited by 221 publications

(98 citation statements)

References 111 publications

(154 reference statements)

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“…in roofs, walls and pipes), [104,240], in aerospace structures (e.g. the Junkers Ju-52 of the 1930's) [106,232,265,266] and in sandwich panels for marine and aerospace applications [48,86,117,194]. This is due to their high strength-to-weight ratio, energy absorption capabilities and anisotropic behaviour, which can be attributed to the high degree of stiffness transverse to the corrugation direction, in comparison to along the corrugation direction.…”

Section: Anisotropic Structuresmentioning

confidence: 99%

HCI meets Material Science

Qamar

Groh

Holman

et al. 2018

Proceedings of the 2018 CHI Conference on Human Factors in Computing Systems

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Section: Anisotropic Structuresmentioning

confidence: 99%

HCI meets Material Science

Qamar

Groh

Holman

et al. 2018

Proceedings of the 2018 CHI Conference on Human Factors in Computing Systems

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“…Utilization of the corrugated geometry has been shown to have potential to increase the necking strain of a material as a result of the unbending of the corrugation during loading. As outlined in the review paper by Dayyani et al, [10] this improved elongation in the longitudinal direction coupled with high transverse stiffness has made the corrugated geometry an excellent candidate in the construction industry, the packaging industry in the form of corrugated board, as explored in Luo et al [11] and Gilchrist et al, [12] and more recently in the aerospace industry for use in morphing wings, as studied by Ge et al, [13] Xia et al, [14] Kress and Winkler, [15] Yokozeki et al, [16] and Park et al [17] Studies of isolated corrugations or corrugated sandwich structures by Thill et al, [18] Dayyani et al, [19] Bouaziz, [20] Boke, [21] and Fraser et al [22] found that when subjected to a tensile load the stress-strain response is characterized by initially low levels of stress followed by increasing work hardening behavior that can be attributed to the unbending corrugation, followed by normal plastic behavior of the material once the corrugation is straightened. Ultimately, this leads to the material necking at a larger value of strain compared to a straight sample.…”

Section: Introductionmentioning

confidence: 99%

Corrugation Reinforced Composites: A Method for Filling Holes in Material‐Property Space

Fraser

Zurob

2017

Adv Eng Mater

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Material-property space is filled with holes representing desirable combinations of properties, such as high strength and high necking strain. One way to fill those holes is to use architectured materials. In this work, Finite Element Modeling (FEM) simulations are performed to evaluate composites with a corrugated reinforcement architecture across a range of volume fractions and corrugation heights for a model copper-steel system. The corrugated reinforcement geometry shows large improvements in necking strain, which increases with corrugation height, without sacrificing strength, and fills a desirable region in material-property space. Additionally, it is found that the necking strain of a matrix material can be increased by adding a less ductile reinforcing material provided it has a highly corrugated geometry. The improvement in necking strain seen in these composites is attributed to a boost in work hardening that results from an evolving reinforcement alignment as the corrugation unbends.

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“…11,12 Mechanisms can also be used for morphing purposes: Perera et al 13,14 present a wing morphing solution based upon the use of an eccentric curved beam, which converts an actuated rotation motion into a vertical displacement along the beam. 11,12 Mechanisms can also be used for morphing purposes: Perera et al 13,14 present a wing morphing solution based upon the use of an eccentric curved beam, which converts an actuated rotation motion into a vertical displacement along the beam.…”

Section: Introductionmentioning

confidence: 99%

Morphing structures and fatigue: The case of an unmanned aerial vehicle wing leading edge

Moreira

Tavares

Castro

2017

Fatigue Fract Eng Mat Struct

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With the emergence of novel aircraft structural concepts, which make use of large‐scale shape deflections to achieve improved flight performance across significantly different flight regimes and missions, unusual crack paths and mixed‐mode crack propagation situations may take place. Consequently, morphing concepts require a full understanding of the materials' behaviour in primary or secondary structures to reliably withstand unusual and demanding operating conditions. A case study of a morphing leading edge developed for the wings of an unmanned aerial vehicle is presented in this paper. Leading edges are subjected to damage originated by bird strike or other events, and those damages can compromise the structural integrity and stability of the flight. Due to the deflections during the morphing structure actuation, cracks will propagate eventually until critical sizes. Possible crack propagation scenarios are presented, considering the service operation of the morphing leading edge.

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The mechanics of composite corrugated structures: A review with applications in morphing aircraft

Cited by 221 publications

References 111 publications

HCI meets Material Science

HCI meets Material Science

Corrugation Reinforced Composites: A Method for Filling Holes in Material‐Property Space

Morphing structures and fatigue: The case of an unmanned aerial vehicle wing leading edge

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