Structural Optimization and Form-Finding of Cylindrical Shells for Targeted Elastic Postbuckling Response

Hu, Nan; Burgueño, Rigoberto; Lajnef, Nizar

doi:10.1115/smasis2014-7446

Cited by 3 publications

(3 citation statements)

References 25 publications

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“…A prior numerical study by Hu and Burgueño [9] found that there is a strong correlation between K i , DP max , and A. This observation is confirmed by the tests reported here.…”

Section: Resultssupporting

confidence: 90%

“…Prior studies by the authors [9][10][11][12] have shown that the elastic postbuckling response of cylindrical shells can be modified by providing large and strategically designed imperfections, namely, a seeded geometric imperfection (SGI). Specifically, the first paper [10] only presented the SGI concept as one of three approaches to modify the postbuckling behavior.…”

Section: Introductionmentioning

confidence: 99%

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Harnessing Seeded Geometric Imperfection to Design Cylindrical Shells With Tunable Elastic Postbuckling Behavior

Burgueño²

2016

Journal of Applied Mechanics

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Geometric imperfection, known as a detrimental effect on the buckling load of cylindrical shells, has a new role under the emerging trend of using buckling for smart purposes. Eigenshape-based geometries were designed on the shell surface with the aim of tailoring the postbuckling response. Fourteen seeded geometric imperfection (SGI) cylinders were fabricated using polymer-based 3D printing, and their postbuckling responses were numerically simulated with a general-purpose finite element program. Results on the prototyped SGI cylinders showed a tunable elastic postbuckling response in terms of initial and final stiffness, the maximum load drop from mode switching, and the number of snap-buckling events. A response contour and discrete map is presented to show how the number of waves in the axial and circumferential directions in the seeded eigenshape imperfection can control the elastic postbuckling response. SGI cylinders provide diverse design opportunities for controllable unstable response and are good candidates for use in smart and adaptive materials/structures.

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“…A prior numerical study by Hu and Burgueño [9] found that there is a strong correlation between K i , DP max , and A. This observation is confirmed by the tests reported here.…”

Section: Resultssupporting

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Harnessing Seeded Geometric Imperfection to Design Cylindrical Shells With Tunable Elastic Postbuckling Behavior

Burgueño²

2016

Journal of Applied Mechanics

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“…as a cylindrical rocket structure. Most promisingly, a research group at Michigan State University have shown that the elastic post-buckling response of cylinders can be modified by providing large and strategically designed imperfections [18,19,2,20,21,22] in the form of seeded geometric alterations.…”

Section: Introductionmentioning

confidence: 99%

Nudging Axially Compressed Cylindrical Panels Toward Imperfection Insensitivity

Cox

Groh

Pirrera

2019

Journal of Applied Mechanics

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Curved shell structures are known for their excellent load-carrying capability and are commonly used in thin-walled constructions. Although theoretically able to withstand greater buckling loads than flat structures, shell structures are notoriously sensitive to imperfections owing to their postbuckling behavior often being governed by subcritical bifurcations. Thus, shell structures often buckle at significantly lower loads than those predicted numerically and the ensuing dynamic snap to another equilibrium can lead to permanent damage. Furthermore, the strong sensitivity to initial imperfections, as well as their stochastic nature, limits the predictive capability of current stability analyses. Our objective here is to convert the subcritical nature of the buckling event to a supercritical one, thereby improving the reliability of numerical predictions and mitigating the possibility of catastrophic failure. We explore the elastically nonlinear postbuckling response of axially compressed cylindrical panels using numerical continuation techniques. These analyses show that axially compressed panels exhibit a highly nonlinear and complex postbuckling behavior with many entangled postbuckled equilibrium curves. We unveil isolated regions of stable equilibria in otherwise unstable postbuckled regimes, which often possess greater load-carrying capacity. By modifying the initial geometry of the panel in a targeted—rather than stochastic—and imperceptible manner, the postbuckling behavior of these shells can be tailored without a significant increase in mass. These findings provide new insight into the buckling and postbuckling behavior of shell structures and opportunities for modifying and controlling their postbuckling response for enhanced efficiency and functionality.

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Elastic postbuckling response of axially-loaded cylindrical shells with seeded geometric imperfection design

Burgueño

2015

Thin-Walled Structures

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Structural Optimization and Form-Finding of Cylindrical Shells for Targeted Elastic Postbuckling Response

Cited by 3 publications

References 25 publications

Harnessing Seeded Geometric Imperfection to Design Cylindrical Shells With Tunable Elastic Postbuckling Behavior

Harnessing Seeded Geometric Imperfection to Design Cylindrical Shells With Tunable Elastic Postbuckling Behavior

Nudging Axially Compressed Cylindrical Panels Toward Imperfection Insensitivity

Elastic postbuckling response of axially-loaded cylindrical shells with seeded geometric imperfection design

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