Energy method solution for the postbuckling response of an axially loaded bilaterally constrained beam
Autor: | Nizar Lajnef, Wassim Borchani, Rigoberto Burgueño |
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Rok vydání: | 2015 |
Předmět: |
Engineering
Bistability Deformation (mechanics) business.industry Mechanical Engineering Mechanics Condensed Matter Physics Kinetic energy Potential energy Classical mechanics Buckling Mechanics of Materials General Materials Science Buckle Axial symmetry business Beam (structure) Civil and Structural Engineering |
Zdroj: | Mechanics Research Communications. 70:114-119 |
ISSN: | 0093-6413 |
Popis: | Bistable and multistable structures have shown great usefulness in many applications such as MEMS actuation and energy harvesting. Bistability of structures can be achieved through buckling. Confining a buckled beam between two lateral constraints allows it to buckle into higher modes as the axial load increases. This paper presents a theoretical study of the postbuckling response of a bilaterally constrained elastica subjected to gradually increased axial load. Equilibrium states are determined using an energy method. Under small deformation assumptions, the total potential energy is minimized under the defined constraints. The presented model allows for an accurate representation of the flatting behavior and the increase in the length of contact areas with the lateral constraints before the sudden snapping between equilibrium states. Mode transitions are manifested by jumps in the response curves. Previously developed models based on geometry and symmetries overestimate the required forces for higher equilibrium modes and do not match experimental observations. Results are validated with experimental force–displacement measurements under both force- and displacement-control. The kinetic energy released during buckling mode transitions is determined by a dynamic analysis. |
Databáze: | OpenAIRE |
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