Non-linear simulation of shaking-table tests on 3- and 7-storey X-Lam timber buildings

Abstract This paper presents an advanced FE modelling of cross-laminated (X-Lam) timber buildings for non-linear dynamic analyses. The model has been used to reproduce the experimental results of the shaking table tests carried out in Japan within the SOFIE project on the 3- and 7-storey full-scale timber buildings. The X-Lam timber panels have been schematized with linear-elastic shell elements, whereas all metal connectors (hold-downs, angle brackets, screws) have been described with 3-DOFs non-linear hysteretic springs. The hysteretic law has a trilinear backbone curve, and is characterised by pinching, post-peak softening, strength and stiffness degradation. The approximating hysteretic laws of the springs have been calibrated on the experimental cyclic tests carried out on each single metal connector. Additional features of the model are the possibilities to account for friction at the interface between upper and lower X-Lam panels, and for a strength domain between shear and tensile force in the metal connectors. Due to the lack of experimental results, these variables have been identified via parametric study so as to reduce the difference between the numerical prediction and the experimental result of X-Lam single walls loaded with cyclic horizontal load. The experimental–numerical comparisons of the shaking table tests demonstrate the capacity of the model to capture the seismic responses of both buildings with errors within 20% in relative acceleration and 7% in roof displacement. Friction has been found to significantly affect the seismic response as it reduces the peak top displacement up to 31%.

[1]  M. Fragiacomo,et al.  Cyclic behavior of typical screwed connections for cross-laminated (CLT) structures , 2015, European Journal of Wood and Wood Products.

[2]  Jorge M. Branco,et al.  Lateral resistance of log timber walls subjected to horizontal loads , 2010 .

[3]  Kazuyuki Matsumoto,et al.  Full-Scale Tests and Numerical Analysis of Low-Rise CLT Structures under Lateral Loading , 2016 .

[4]  Massimo Fragiacomo,et al.  Seismic Analysis of Cross-Laminated Multistory Timber Buildings Using Code-Prescribed Methods: Influence of Panel Size, Connection Ductility, and Schematization , 2016 .

[5]  Naohito Kawai,et al.  SOFIE project – 3D shaking table test on a seven‐storey full‐scale cross‐laminated timber building , 2013 .

[6]  J. Hummel,et al.  CLT Wall Elements Under Cyclic Loading - Details for Anchorage and Connection , 2013 .

[7]  Frank McKenna,et al.  OpenSees: A Framework for Earthquake Engineering Simulation , 2011, Computing in Science & Engineering.

[8]  Marjan Popovski,et al.  Performance of a 2-Story CLT House Subjected to Lateral Loads , 2016 .

[9]  Claudio Amadio,et al.  A component approach for the hysteretic behaviour of connections in cross‐laminated wooden structures , 2013 .

[10]  Claudio Amadio,et al.  Experimental Study and Numerical Investigation of Blockhaus Shear Walls Subjected to In-Plane Seismic Loads , 2015 .

[11]  Ario Ceccotti,et al.  New Technologies for Construction of Medium-Rise Buildings in Seismic Regions: The XLAM Case , 2008 .

[12]  Ario Ceccotti,et al.  Cyclic behaviour of typical metal connectors for cross-laminated (CLT) structures , 2015 .

[13]  Bruno Dujic,et al.  Full-Scale Shaking-Table Tests of XLam Panel Systems and Numerical Verification: Specimen 1 , 2013 .

[14]  John W. van de Lindt,et al.  Overview of a Project to Quantify Seismic Performance Factors for Cross Laminated Timber Structures in the United States , 2014 .

[15]  Bořek Patzák,et al.  OOFEM — an Object-oriented Simulation Tool for Advanced Modeling of Materials and Structures , 2012 .

[16]  PeiShiling,et al.  Analytical study on seismic force modification factors for cross-laminated timber buildings , 2013 .

[17]  Gerhard Schickhofer,et al.  Experimental tests on cross-laminated timber joints and walls , 2015 .

[18]  M. Fragiacomo,et al.  “Seismic design of multi-storey CLT buildings according to Eurocode 8.” , 2013 .

[19]  Massimo Fragiacomo,et al.  Elastic and ductile design of multi-storey crosslam massive wooden buildings under seismic actions , 2011 .