Alexander Revisited: Upper- and Lower-Bound Approaches for Axial Crushing of a Circular Tube

•The essential limitations of Alexander's classical method on tube crushing are explored and a common misconception of Alexander's method being upper-bound is highlighted and corrected.•A new collapse mechanism involving both inward and outward folding is proposed, while the folding length...

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Bibliographic Details
Published in:International journal of mechanical sciences 2021-09, Vol.206, p.106610, Article 106610
Main Authors: Lu, G., Yu, J.L., Zhang, J.J., Yu, T.X.
Format: Article
Language:English
Subjects:
Alexander model
Circular tube
Force-displacement curve
Large plastic deformation
Lower-bound method
Upper-bound method
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Summary:•The essential limitations of Alexander's classical method on tube crushing are explored and a common misconception of Alexander's method being upper-bound is highlighted and corrected.•A new collapse mechanism involving both inward and outward folding is proposed, while the folding length and a complete force-displacement curve are obtained by correctly using upper bound method.•The lower-bound analysis re-produces the results of the upper-bound method.•The paper illustrates how to appropriately apply upper-bound and low-bound theories for structures experiencing large plastic deformation. In the classical Alexander model for a rigid, perfectly plastic circular tube under axial progressive crushing, an expression for the average crushing force over one complete folding cycle was given in terms of the folding length while the value of the folding length was determined by minimising the average force. This approach is often misunderstood as a correct upper-bound method and has been widely used for analysing large plastic deformation of structures. In this paper, it is highlighted that Alexander approach is strictly not an upper-bound analysis and alternative analyses are presented. A new initial collapse mechanism involving folding both inwards and outwards of the tube wall is proposed for an upper-bound analysis, which leads to the determination of the folding characteristics such as the folding length. Subsequently, a repeatable mechanism is idealised for the periodic folding process. The upper-bound analysis is performed by minimizing the instant force required for maintaining the folding process, which is equivalent to adopting the energy balance for the incremental plastic deformation rather than the total deformation of one complete folding cycle. Instead of merely obtaining the average force as Alexander did, the present theoretical analysis gives a complete force-displacement curve as well as plastic folding length, etc., which agrees well with the existing knowledge. Furthermore, an equilibrium approach is presented involving detail stress state for a deforming configuration of the tube. The lower-bound results re-produce the variation of the force as obtained from the upper-bound analysis when the folding configurations are the same as those in the assumed collapse mechanisms. The present study conceptually reconciles the upper-bound and low-bound theories in structural plasticity for large deformation analysis. [Display omitted]
ISSN:0020-7403
1879-2162
DOI:10.1016/j.ijmecsci.2021.106610