Back to Search Start Over

Experimental and analytical evaluation of the in-plane behaviour of as-built and strengthened traditional wooden floors

Authors :
Mirra, M. (author)
Ravenshorst, G.J.P. (author)
van de Kuilen, J.W.G. (author)
Mirra, M. (author)
Ravenshorst, G.J.P. (author)
van de Kuilen, J.W.G. (author)
Publication Year :
2020

Abstract

Traditional timber floors cannot normally withstand horizontal seismic loads without large deformations. This may lead to a corresponding out-of-plane collapse of masonry walls in existing buildings. This situation is even more critical in the Netherlands, around the city of Groningen, where human-induced earthquakes started to take place. Since no seismic events have been experienced until recently, none of the existing buildings was designed with seismic events in mind, with no exception for the timber floors: therefore, it was necessary to characterize their in-plane response. To obtain representative results, firstly floor and roof samples were extracted from existing buildings. The relevant material properties were determined, together with the plank-joist connections behaviour. Replicas were then built with new material and tested to confirm the similarity in response compared to extracted samples. Based on these results, full-scale replicated diaphragms were constructed, and tested quasi-static reversed-cyclic in their plane, either parallel or perpendicular to the joists. Besides characterizing as-built diaphragms, a simple strengthening technique with plywood panels was applied as well, improving their in-plane response in terms of strength, stiffness and energy dissipation, as test results confirm. This study is concluded with an analytical characterization of the diaphragms’ in-plane response, for as-built and strengthened configurations.<br />Bio-based Structures & Materials

Details

Database :
OAIster
Notes :
English
Publication Type :
Electronic Resource
Accession number :
edsoai.on1149838110
Document Type :
Electronic Resource
Full Text :
https://doi.org/10.1016.j.engstruct.2020.110432