Design of tensegrity structures using parametric analysis and stochastic search

Rhode-Barbarigos, Landolf; Jain, Himanshu; Kripakaran, Prakash; Smith, Ian F. C.

doi:10.1007/s00366-009-0154-1

Cited by 32 publications

(22 citation statements)

References 23 publications

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“…The equilibrium between tension and compression forces is responsible for the structural stability and load bearing capacity of tensegrities. Previous studies have found that the self-stress level initially introduced in tensegrity members before applying loads have a direct impact on both the weight and the deflection of the tensegrity footbridge [26,27]. This suggests that initial self-stresses, together with the cross-sectional areas of tensioned and compressed members are the key design parameters that affect the structural performance and cost of a tensegrity structure.…”

Section: Design Variablesmentioning

confidence: 99%

“…Recently, Motro [25] proposed a new family of tensegrity modules called "tensegrity rings" that can be assembled in a "hollow rope". As shown in previous work [26,27], the concept of "hollow rope" shows promise for architecture and civil engineering applications such as footbridges. Few studies on design and optimization of tensegrity structures have been observed to be of practical significance.…”

Section: Introductionmentioning

confidence: 99%

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Design optimization and dynamic analysis of a tensegrity-based footbridge

Ali

Rhode-Barbarigos

Albi

et al. 2010

Engineering Structures

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Tensegrity structures are spatial structural systems composed of struts and cables with pin-jointed connections. Their stability is provided by the self-stress state in tensioned and compressed members. Although much progress has been made in advancing research into the tensegrity concept, a rapid survey of current activities in engineering practice shows that much of its potential has yet to be accomplished. A design optimization study for a tensegrity-based footbridge is presented in order to further advance the tensegrity concept in modern structural engineering. In the absence of specific design guidelines, design requirements for a tensegrity footbridge are stated. A genetic algorithm based optimization scheme is used to find a cost-effective design solution. The dynamic performance of the tensegrity footbridge is studied through parametric studies. Design results illustrate that the proposed tensegrity-based footbridge meets typical static and dynamic design criteria.

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Section: Design Variablesmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Design optimization and dynamic analysis of a tensegrity-based footbridge

Ali

Rhode-Barbarigos

Albi

et al. 2010

Engineering Structures

Self Cite

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“…Moreover, designing a tensegrity structure is a challenging task due to a complex coupled nonlinear behavior that is closely related to the topology explored. Furthermore, there are no generally accepted design guidelines for tensegrity structures except a few studies underlying critical parameters of their structural behavior such as self-stress and the strut-to-cable stiffness ratio [9,10]. Due to the complexity of the design task, the use of stochastic search methods or other optimization techniques has been explored [10,11].…”

Section: Introductionmentioning

confidence: 99%

“…Furthermore, there are no generally accepted design guidelines for tensegrity structures except a few studies underlying critical parameters of their structural behavior such as self-stress and the strut-to-cable stiffness ratio [9,10]. Due to the complexity of the design task, the use of stochastic search methods or other optimization techniques has been explored [10,11]. However, no study takes into account shape changes such as deployment and actuation schemes for the design of the tensegrity structure.…”

Section: Introductionmentioning

confidence: 99%

Design Aspects of a Deployable Tensegrity-Hollow-rope Footbridge

Rhode-Barbarigos

Ali

Motro

et al. 2012

International Journal of Space Structures

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Tensegrity structures are composed of cables and struts in a pre-stressed self-equilibrium. Although tensegrity first appeared in the 1950s, it is seldom used in civil engineering. This paper focuses on the design aspects of a deployable tensegrity-hollow-rope footbridge. Deployment is usually not a critical design case for traditional deployable structures. However, for tensegrity systems deployment may be critical due to the actuation required. In this paper, deployment is investigated in a general design framework. The influence of clustered (continuous) cables and spring elements in statics and dynamics is studied. Finally, actuation schemes are explored to identify cases where deployment becomes a critical design case. For this configuration, deployment is a critical design case when the structure has spring elements and continuous cables.

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“…Although tensegrity rings are composed of a single strut circuit, their deployment can be completed without strut collision. The "hollow rope" concept shows promise for architecture and civil engineering applications such as pedestrian bridges (Rhode-Barbarigos et al 2010b;Rhode-Barbarigos et al 2010a). However, its application for a deployable footbridge has not been explored.…”

Section: Introductionmentioning

confidence: 99%