### Abstract

Lingua originale | English |
---|---|

pagine (da-a) | 2265-2281 |

Numero di pagine | 17 |

Rivista | Bulletin of Earthquake Engineering |

Volume | 13 |

Stato di pubblicazione | Published - 2015 |

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### All Science Journal Classification (ASJC) codes

- Civil and Structural Engineering
- Building and Construction
- Geotechnical Engineering and Engineering Geology
- Geophysics

### Cita questo

**Evaluation of infilled frames: an updated in-plane-stiffness macro-model considering the effects of vertical loads.** / Cavaleri, Liborio; Campione, Giuseppe; Amato, Giuseppina.

Risultato della ricerca: Article

*Bulletin of Earthquake Engineering*, vol. 13, pagg. 2265-2281.

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TY - JOUR

T1 - Evaluation of infilled frames: an updated in-plane-stiffness macro-model considering the effects of vertical loads

AU - Cavaleri, Liborio

AU - Campione, Giuseppe

AU - Amato, Giuseppina

PY - 2015

Y1 - 2015

N2 - The influence of masonry infills on the in-plane behaviour of RC framed structures is a central topic in the seismic evaluation and retrofitting of existing buildings. Many models in the literature use an equivalent strut member in order to represent the infill but, among the parameters influencing the equivalent strut behaviour, the effect of vertical loads acting on the frames is recognized but not quantified. Nevertheless a vertical load causes a non-negligible variation in the in-plane behaviour of infilled frames by influencing the effective volume of the infill. This results in a change in the stiffness and strength of the system. This paper presents an equivalent diagonal pin-jointed strut model taking into account the stiffening effect of vertical loads on the infill in the initial state. The in-plane stiffness of a range of infilled frames was evaluated using a finite element model of the frame-infill system and the cross-section of the strut equivalent to the infill was obtained for different levels of vertical loading by imposing the equivalence between the frame containing the infill and the frame containing the diagonal strut. In this way a law for identifying the equivalent strut width depending on the geometrical and mechanical characteristics of the infilled frame was generalized to consider the influence of vertical loads for use in the practical applications. The strategy presented, limited to the initial stiffness of infilled frames, is preparatory to the definition of complete non-linear cyclic laws for the equivalent strut.

AB - The influence of masonry infills on the in-plane behaviour of RC framed structures is a central topic in the seismic evaluation and retrofitting of existing buildings. Many models in the literature use an equivalent strut member in order to represent the infill but, among the parameters influencing the equivalent strut behaviour, the effect of vertical loads acting on the frames is recognized but not quantified. Nevertheless a vertical load causes a non-negligible variation in the in-plane behaviour of infilled frames by influencing the effective volume of the infill. This results in a change in the stiffness and strength of the system. This paper presents an equivalent diagonal pin-jointed strut model taking into account the stiffening effect of vertical loads on the infill in the initial state. The in-plane stiffness of a range of infilled frames was evaluated using a finite element model of the frame-infill system and the cross-section of the strut equivalent to the infill was obtained for different levels of vertical loading by imposing the equivalence between the frame containing the infill and the frame containing the diagonal strut. In this way a law for identifying the equivalent strut width depending on the geometrical and mechanical characteristics of the infilled frame was generalized to consider the influence of vertical loads for use in the practical applications. The strategy presented, limited to the initial stiffness of infilled frames, is preparatory to the definition of complete non-linear cyclic laws for the equivalent strut.

UR - http://hdl.handle.net/10447/238260

UR - http://www.kluweronline.com/issn/1570-761X/

M3 - Article

VL - 13

SP - 2265

EP - 2281

JO - Bulletin of Earthquake Engineering

JF - Bulletin of Earthquake Engineering

SN - 1570-761X

ER -