Tensegrities and Tensioned Structures

Authors

  • Mª Dolores Álvarez Elipe CEIPSO Salvador Dalí

DOI:

https://doi.org/10.30564/jaeser.v3i3.2155

Abstract

“Push-and-pull” efficient structures have been inconceivable between XVIII centuries. It is because of the incapacity of obtain an efficient behaviour of tensioned material. Since XVIII centuries, architecture developed some structural knowledge generating novel structural forms in the architecture and engineering that were not known before. Tensegrities and tensioned structures were studied due to the knowledge of geometry and tension. Some investigations about tensegrities and tensioned structures have been developed since that moment. Tensegrities are bar and cable structures that work only in compression or tension efforts. Bars and cables are balanced, but in appearance the growth is disorderly. Most of deployable structures are based on tensegrity systems. The research is focused in presenting a summary of tensegrities and tensioned architectures that have been used in the structural design of novel patterns. The research of adequate materials to tension efforts will be crucial in this study. The investigation presents an important state of the art that provides technical solutions to apply on novel architectures based on tensegrities and tensioned structures. The research is useful to produce the current constructive solutions based on these constructive systems.

Keywords:

Tensegrity;Tensioned;Geometry;Structure;Compression;Tension;Effort

References

[1] Edmondson, A. C. A Fuller Explanation: The Synergetic Geometry of R. Buckminster Fuller. Cambridge, Mass, (USA): Birkhäuser Boston, 1987.

[2] Tibert, G. Numerical Analyses of Cable Roof Structures. Unpublished Licentiate thesis. Royal Institute of Technology, Stockholm (Sweden), 1999.

[3] Burstow, R. Symbols for ’51, the Royal Festival Hall,Skylon and Sculptures for the Festival of Britain, The Ballroom, Main Foyer, Royal Festival Hall, London,1996.

[4] Cruickshank, D. The 1951 Dome of Discovery, London. The Architectural Review, 1995, 197.1175: 80-85.

[5] Francis, A.J. Introducing Structures. Oxford: Pergammon Press, 1980.

[6] Drew, P. Frei Otto. Form and structure. London:Crosby Lockwood Staples, 1976.

[7] Pugh, A. An Introduction to Tensegrity. Berkeley,California: University of California Press, 1976.

[8] Williams, W.O. A Primer on the Mechanics of Tensegrity Structures. Pittsburgh (USA), 2003.

[9] Geiger, D.H. Roof structure. U.S. Patent No.4,736,553, 1988.

[10] Motro, R. Tensegrity: Structural Systems for the Future. London: Kogan Page Science, 2003.

[11] Fuller, R.B. Suspension Building, U.S. Patent No. 3,1964, 139: 957.

[12] GÓMEZ, V. Tensegrity Structures and their Application to Architecture. Tesis Doctoral. School of Architecture, Queen’s University, Belfast, 2004.

[13] FOX, H. N. Portrait of an Atomist. Catalog Essay for Kenneth Snelson Exhibition at Hirshhorn Museum and Sculpture Garden, Smithsonian Institution,Washington, D.C., Junio - Agosto, 1981. Also avaliable in:http://www.kennethsnelson.net/icons/art.htm

[14] Fuller, R.B. Tensegrity. Portfolio and Art News Annual, 1961, 4: 112-127+144+148. Also avaliable in: http://www.rwgrayprojects.com/rbfnotes/fpapers/tensegrity/tenseg01.html

[15] Fuller, R.B. Octahedronal building truss, U.S. Patent No. 3,3 54,591, 1967.

[16] Fuller, R.B. Non-symmetrical tensegrity, U.S. Patent No. 3,866,366, 1975.

[17] Kenner, H. Geodesic Math and How to Use It, Berkeley, California: University of California Press, 1976.

[18] Fuller, R.B. Correspondence with Robert Burkhardt,Enero 29 -Marzo 18, 1982. También disponible en. http://www.bfi.org/burkhardt/section1.html

[19] Burkhardt, R.W. A practical guide to tensegrity design, [on-line], Cambridge (USA), 1994-2017. Avaliable in: http://www.channel1.com/users/bobwb/tenseg/book/cover.html Last access 27 of may of 2017

[20] Hanaor, A. Preliminary Investigation of Double-Layer Tensegrities. H.V. Topping, ed., Proceedings of International Conference on the Design and Construction of Non-conventional Structures (Vol.2),Edinburgh, Scotland: Civil-Comp Press, 1987.

[21] Nestorovic, M. Metallic Integrally Tensioned (Tensegrity) Cupola. H.V. Topping, ed., Proceedings of International Conference on the Design and Construction of Non-conventional Structures, Edinburgh,Scotland: Civil-Comp Press, 1987, 2.

[22] Connelly, R., Back, A. Mathematics and Tensegrity. American Scientist. 1998a, 86(2).

[23] Connelly, R., Back, A. Catalogue of SymmetricTensegrities, [online], Cornell University, Ithaca (USA), 1998b. http://mathlab.cit.cornell.edu/visualization/tenseg/in_progress/short_top.html Last access 28 of may of 2017

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How to Cite

Elipe, M. D. Álvarez. (2020). Tensegrities and Tensioned Structures. Journal of Architectural Environment & Structural Engineering Research, 3(3), 10–16. https://doi.org/10.30564/jaeser.v3i3.2155

Issue

Vol. 3 , Iss. 3 (July 2020)

Article Type

Article

License

Copyright © 2020 Mª Dolores Álvarez Elipe

Creative Commons License

This is an open access article under the Creative Commons Attribution-NonCommercial 4.0 International (CC BY-NC 4.0) License.

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