I.11.00: Innovative systems for seismic resistance: The INNOSEIS Project

ABSTRACT Following the international trends, extensive research on seismic resistant structures has been carried out in Europe during the last decade, with the introduction of several systems with innovative steel‐based elements, as the result of European and national research projects. However, the...

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Veröffentlicht in:ce/papers 2017-09, Vol.1 (2-3), p.3375-3384
Hauptverfasser: Vayas, Ioannis, Vamvatsikos, Dimitrios, Thanopoulos, Pavlos
Format: Artikel
Sprache:eng
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Zusammenfassung:ABSTRACT Following the international trends, extensive research on seismic resistant structures has been carried out in Europe during the last decade, with the introduction of several systems with innovative steel‐based elements, as the result of European and national research projects. However, these systems have not claimed a fair share of the steel construction market, as provisions for their design have not been included in the Eurocodes and only a few designers are confident enough to employ them. The INNOSEIS project, which has received funding from the Research Fund for Coal and Steel (RFCS) with the participation of 11 partners, aims to deal with this shortcoming. In this paper, the valorisation actions for 12 such innovative anti‐seismic devices are presented. Information documents for all dissipative systems have been produced and combined in a single volume, translated in several European languages, for the dissemination to all partners of the construction sector such as architects, structural engineers, construction companies, steel producers and all potential decision makers of the construction sector. Criteria are proposed as to determine which of the systems are characterised as devices and are subject to CE marking in accordance with EN 15129, and which may be considered as innovative systems that require a code approval in EN 1998–1. For the latter, pre‐normative design recommendations are drafted that will allow them to receive the status of code‐approved systems. A reliability‐based methodological procedure to define values of behaviour factors (q‐factors) for building structures is proposed, which will be in turn applied to determine q‐factors for structural systems with the anticipated systems. A number of case studies with application examples of realistic steel buildings, in which the systems are employed, are presented. Dissemination of the project includes seminars and workshops in several European and Mediterranean countries, as well as the development of online, printed and electronic material, which is free for all people involved in the construction sector, in order to achieve the wide application of innovative seismic resistance systems in practical design.
ISSN:2509-7075
2509-7075
DOI:10.1002/cepa.392