The Use of Structural Aluminum for the Design of Large Span Roofs: The Case of the “Cubierta De Oviedo”

Beatrice Faggiano; Giacomo Iovane; Alessia Ricci; Antonino Squillace; Antonello Astarita; Francesco Passeggio; Alfonso Fernández Canteli; Federico M. Mazzolani

doi:10.4028/www.scientific.net/KEM.710.371

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HomeKey Engineering MaterialsKey Engineering Materials Vol. 710The Use of Structural Aluminum for the Design of...

The Use of Structural Aluminum for the Design of Large Span Roofs: The Case of the “Cubierta De Oviedo”

Abstract:

The architectural artwork “Cubierta de Oviedo” is located in the Buenavista building complex, it being the movable roof of the City of Oviedo (Asturie, Spain) conference centre. The original design and realization was by the archistar Santiago Calatrava (2004-11). The structure is made in steel. Since the testing of the structure, it was not possible to open the roof. From this occurrence, the idea to design the cubierta in structural aluminum seemed to be a challenge, due to the lowest weight of aluminum as respect to steel. In this perspective, the study focuses on the design of the main beam, spanning 134m total length, with 110m cantilever length, in the most unfavorable condition of open roof. The more appropriate aluminum alloy 7075 has been selected, according to the required mechanical properties. Considering the large height (4.20m) of the cross section, which is a special welded box section, for connecting the component elements, the Friction Stir Welding innovative technique is examined and proposed. The EC9 design codes for aluminum structures is applied with some adaptations due to the peculiarities of the structure. A comparison of steel and aluminum solutions is then presented, in terms of internal forces, mechanical efficiency, deformability, weight and costs, it evidencing the advantages of aluminum for large span roofs.

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Periodical:

Key Engineering Materials (Volume 710)

Pages:

371-377

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.710.371

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Online since:

September 2016

Authors:

Beatrice Faggiano*, Giacomo Iovane, Alessia Ricci, Antonino Squillace, Antonello Astarita, Francesco Passeggio, Alfonso Fernández Canteli, Federico M. Mazzolani

Keywords:

Design Criteria for Aluminum Structures, Friction Stir Welding, Large Span Roof, Structural Aluminum

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References

[1] Fco. Javier Fernandez Pozuelo, R. Rodriguez Fajardo, E. Goberna Perez (2012).

Google Scholar

[2] S. Calatrava L.L.C. Project Design: Conjunto de edificaciones Buenavista, Cubierta P.E.C. Proyecto, Excmo Ayuntamiento de Oviedo, Jovellanos XXI, S.A. 24-03-(2006).

Google Scholar

[3] F. M. Mazzolani (1995), Aluminium alloy structures, Second Edition, E &FN SPON, an imprint of Chapman & Hall, London. ISBN: 9780419177708.

Google Scholar

[4] MIL-HDBK-5H (1998), Metallic materials and elements for aerospace vehicle structures. Publisher: U.S. Dept. of Defense. ISBN: 1591241723.

Google Scholar

[5] G. Mathers (2002), The welding of aluminium and its alloys, Woodhead Publishing Ltd and CRC Press LLC, Cambridge England. ISBN-9781855735675.

Google Scholar

[6] C. Gambaro, L. Fratini, A. Squillace, J. Adamowki, M. Ponte, G. Buffa (2009), Friction Stir Welding – Introduction to the technology, AITM. ARACNE, ISBN 9788854825307 (in Italian).

Google Scholar

[7] R.S. Mishraa, Z.Y. Mab (2005), Friction stir welding and processing. Materials Science and Engineering R 50 (2005) 1–78. Elsevier. doi: 10. 1016/j. mser. 2005. 07. 001. ISSN: 0921-5093.

Google Scholar

[8] G. Iovane, A. Ricci (2014).

Google Scholar

[9] CNR DT 208 (2011): Istruzioni per la Progettazione, l'Esecuzione ed il Controllo di Strutture di Alluminio (Design, Construction and test of aluminium structures, in Italian).

Google Scholar

[10] C.G. Rhodes, M.W. Mahoney, W.H. Bingel, R.A. Spurlingand, C.C. Bampton (1997), Effects of friction stir welding on microstructure of 7075 aluminium. Scripta Materalia 36(1): 69–75.

DOI: 10.1016/s1359-6462(96)00344-2

Google Scholar