Sage Journals: Discover world-class research

Abstract

Clustered (continuous) cables reflect an advantageous solution for reducing the number of tensile elements in engineering systems. During the tensioning or activation of tensile structures, such as cable structures, membranes and tensegrity structures, the deficiency of having to control too many elements can be overcome by employing clustered cables. The use of clustered cables has been shown to alter the structural behavior of tensile systems by modifying the force distribution in the systems. This effect has been showcased under the assumption of frictionless sliding of the cable elements across nodes or pulleys. However, friction can have also impact on the behavior of the system. In this paper, a new Finite Element formulation is proposed for the static analysis of tensile structures with clustered cables. The proposed formulation accommodates sliding-induced friction by the consideration of the Euler-Eytelwein equation as well as geometric nonlinearities. It is found that the sliding-induced friction can significantly modify the force distribution in the system. The applicability and importance of the proposed formulation is demonstrated through the analysis of two examples from the literature.

Keywords

Finite element clustered cable continuous cable sliding friction pulley

Get full access to this article

View all access options for this article.

References

Tran

Park

Lee

. A unique feasible mode of prestress design for cable domes. Finite Elem Anal Des 2012; 59: 44–54.

Moored

Bart-Smith

. Investigation of clustered actuation in tensegrity structures. Int J Solids Struct 2009; 46: 3272–3281.

Sultan

Skelton

. Deployment of tensegrity structures. Int J Solids Struct 2003; 40: 4637–4657.

Pauletti

RMO

Martins

. Modelling the slippage between membrane and border cables. In: IASS symposium 2009, evolution and trends in design, analysis and construction of shell and spatial structures, Valencia, 28 September–2 October 2009, pp.2059-2069.

Zhang

Gao

Liu

, et al. An efficient finite element formulation for nonlinear analysis of clustered tensegrity. Eng Comput 2016; 33: 252–273.

Aufaure

. A finite element of cable passing through a pulley. Comput Struct 1993; 46: 807–812.

Kwan

Pellegrino

. Matrix formulation of macro-elements for deployable structures. Comput Struct 1994; 50(2): 237–254.

Zhou

Accorsi

Leonard

. Finite element formulation for modeling sliding cable elements. Comput Struct 2004; 82: 271–280.

Chen

Yin

, et al. Formulation and application of multi-node sliding cable element for the analysis of Suspen-Dome structures. Finite Elem Anal Des 2010; 46: 743–750.

10.

Genovese

. Strutture tensegrity – Metodi di Analisi e Ricerca di Forma. Politecnica delle Marche, Italy: Universitá, 2008.

11.

Barnes

. Form finding and analysis of tension structures by dynamic relaxation. Int J Space Struct 1999; 14: 89–104.

12.

Barnes

Adriaenssens

Krupka

. A novel torsion/bending element for dynamic relaxation modeling. Comput Struct 2013; 119: 60–67.

13.

Bel Hadj Ali

Rhode-Barbarigos

Smith

IFC

. Analysis of clustered tensegrity structures using a modified dynamic relaxation algorithm. Int J Solids Struct 2011; 48: 637–647.

14.

Hincz

. Nonlinear analysis of cable net structures suspended from arches with block and tackle suspension system, taking into account the friction of the pulleys. Int J Space Struct 2009; 24: 143–152.

15.

Zhang

, et al. Geometrically nonlinear elasto-plastic analysis of clustered tensegrity based on the co-rotational approach. Int J Mech Sci 2015; 93: 154–165.

16.

Kan

Peng

Chen

, et al. A sliding cable element of multibody dynamics with application to nonlinear dynamic deployment analysis of clustered tensegrity. Int J Solids Struct 2018; 130–131: 61–79.

17.

Liu

Han

Chen

, et al. Precision control method for pre-stressing construction of suspen-dome structures. Advanced Steel Construction 2014; 10: 404–425.

18.

Rhode-Barbarigos

Ali

NBH

Motro

, et al. Design aspects of a deployable Tensegrity-Hollow-rope footbridge. Int J Space Struct 2012; 27: 81–95.

19.

Rhode-Barbarigos

Schulin

Ali

NBH

, et al. Mechanism-based approach for the deployment of a Tensegrity-ring module. J Struct Eng 2012; 138: 539–548.

20.

Veuve

Safaei

Smith

IFC

. Deployment of a Tensegrity Footbridge. J Struct Eng 2015; 141: 04015021.

21.

Sychterz

Smith

IFC

. Joint friction during deployment of a near-full-scale tensegrity footbridge. J Struct Eng 2017; 143: 04017081.

22.

Veuve

Sychterz

Smith

IFC

. Adaptive control of a deployable tensegrity structure. Eng Struct 2017; 152: 14–23.

23.

Pauletti

Pimenta

. Formulaçao de um elemento finito de cabo incorporando o efeito do atrito (Elemento de cabos escorregando). Revista internacional de métodos numéricos 1995; 11: 565–576.

24.

Lee

Choo

. Finite element modelling of frictional slip in heavy lift sling systems. Comput Struct 2003; 81: 2673–2690.

25.

Choo

. Super element approach to cable passing through multiple pulleys. Int J Solids Struct 2005; 42: 3533–3547.

26.

Chen

Liu

Wang

, et al. Establishing and application of cable-sliding criterion equation. Advanced Steel Construction 2011; 7: 131–143.

27.

Bel Hadj Ali

Sychterz

Smith

IFC

. A dynamic-relaxation formulation for analysis of cable structures with sliding-induced friction. Int J Solids Struct 2017; 126–127: 240–251.

A finite element formulation for clustered cables with sliding-induced friction

Abstract

Keywords

Get full access to this article

References