Your search keyword '"Cyclic experimental test"' showing total 2 results

1. Experimental assessment and numerical modelling of exterior non-conforming beam-column joints with plain bars

Author

Gerardo M. Verderame, Maria Teresa De Risi, De Risi, Maria Teresa, and Verderame, Gerardo Mario

Subjects

Slippage of reinforcement, 021110 strategic, defence & security studies, Engineering, business.industry, 0211 other engineering and technologies, 020101 civil engineering, Unreinforced RC joint, 02 engineering and technology, Structural engineering, Dissipation, Reinforced concrete, Cyclic experimental test, Poor quality, 0201 civil engineering, Deformation mechanism, Hook-ended plain bar, Numerical modelling, Joint panel shear behaviour, Beam column, Reinforcement, business, Failure mode and effects analysis, Beam (structure), Civil and Structural Engineering

Abstract

The seismic performance of existing Reinforced Concrete (RC) frames is significantly influenced by the behaviour of beam-column intersections, especially in non-conforming buildings with poor structural details and completely unreinforced joints. In literature, a very limited number of studies deals with specimens reinforced with plain hook-ended longitudinal bars, widespread in Italian and Mediterranean building stock, or with the analysis of local aspects, such as the experimental evaluation of joint shear strains. The almost totality of the models proposed in literature for simulating the cyclic behaviour of RC joints was developed and calibrated by means of tests performed on elements with deformed bars, and, thus, these models may be not adequate for elements with hook-ended plain bars, especially due to the peculiarities in terms of failure mode and interaction mechanisms between concrete and steel. This study analyses the experimental cyclic behaviour of four full-scale exterior unreinforced RC beam-column joints with plain reinforcing bars in beams and columns, which differ for joint aspect ratio and beam longitudinal reinforcement ratio. First, experimental global and local responses of such tests – including energy dissipation capacity and observed damage evolution – are analysed. The main deformation mechanisms ascribable to the joint – namely rotation at the interface between beam/columns and joint, and shear deformation of the joint panel – are experimentally evaluated to provide a realistic support for the numerical modelling of this typology of beam-column joints. Then main joint shear strength models existing in codes and literature are compared with the experimental results. Finally, the numerical modelling of the specimens is carried out under monotonic loading to reproduce the envelope of the experimental responses. The joint panel constitutive parameters are defined to reproduce the experimental joint shear stress-strain relationships. Additionally, modelling of bond-slip is particularly taken into account due to the poor quality of steel-concrete interaction in the specific case of plain reinforcing bars.

Published

2017

2. Experimental tests on Crescent Shaped Braces hysteretic devices

Author

Luca Pieraccini, Tomaso Trombetti, Antoine Dib, Stefano Silvestri, Michele Palermo, Palermo, Michele, Pieraccini, Luca, Dib, Antoine, Silvestri, Stefano, and Trombetti, Tomaso

Subjects

Work (thermodynamics), Engineering, business.industry, Diagonal, 0211 other engineering and technologies, Energy dissipation capacity, 020101 civil engineering, 02 engineering and technology, Structural engineering, Crescent Shaped Brace, Dissipation, Cyclic experimental test, 0201 civil engineering, Seismic analysis, Buckling, 021105 building & construction, business, Ductility, Ductility capacity, Civil and Structural Engineering

Abstract

Crescent Shaped Braces, CSBs, are steel hysteretic devices which, thanks to their geometrical configuration, are characterized by an enhanced seismic behavior that makes them a promising alternative to conventional diagonal steel braces and other seismic devices such as Buckling Resisting Braces and Scorpions. The present work reports the results of the first experimental campaign devoted to assess the cyclic experimental behavior of CSBs. The main goals of the experimental campaign are: (i) to verify/compare the effectiveness of design formulas for the seismic design of CSB introduced by the authors in a previous research work and the predictions of a simplified non-linear model in terms of force-displacement envelop response; (ii) to assess the experimental non-linear cyclic behavior in terms of ductility capacity, energy dissipation capacity, failures.

Published

2017