Cyclic testing of unreinforced masonry walls in two‐way bending

Arêde

et al. 2015

Bull Earthquake Eng

Stone masonry is one of the oldest and most worldwide used building techniques. Nevertheless, the structural response of masonry structures is complex and the effective knowledge about their mechanical behaviour is still limited. This fact is particularly notorious when dealing with the description of their out-of-plane behaviour under horizontal loadings, as is the case of the earthquake action. In this context, this paper describes an experimental program, conducted in laboratory environment, aiming at characterizing the out-of-plane behaviour of traditional unreinforced stone masonry walls. In the scope of this campaign, six full-scale sacco stone masonry specimens were fully characterised regarding their most important mechanic, geometric and dynamic features and were tested resorting to two different loading techniques under three distinct vertical pre-compression states; three of the specimens were subjected to an out-of-plane surface load by means of a system of airbags and the remaining were subjected to an out-of-plane horizontal line-load at the top. From the experiments it was possible to observe that both test setups were able to globally mobilize the out-of-plane response of the walls, which 123Bull Earthquake Eng (2015) 13:2667-2692 DOI 10.1007 presented substantial displacement capacity, with ratios of ultimate displacement to the wall thickness ranging between 26 and 45 %, as well as good energy dissipation capacity. Finally, very interesting results were also obtained from a simple analytical model used herein to compute a set of experimental-based ratios, namely between the maximum stability displacement and the wall thickness for which a mean value of about 60 % was found.

Section: Results and Data Interpretation 41 Experimental Evidencesmentioning

confidence: 92%

Section: Scope and Motivationmentioning

confidence: 99%

Experimental characterization of the out-of-plane performance of regular stone masonry walls, including test setups and axial load influence

Ferreira

Arêde

et al. 2015

Bull Earthquake Eng

Proceedings of the 6th International Conference on Computational Methods in Structural Dynamics and Earthquake Engineering (COM

“…Experimental tests aimed at assessing the OOP behaviour of URM infills and the effects of IP displacement demand on the OOP capacity were performed by different authors ( [7][8][9][10][11][12][13][14][15], among others). In a companion paper [21], the Authors of this study collected in a database the values of secant stiffness and lateral force registered for the above test specimens at first macro-cracking and peak load, as well as the value, if provided, of their ultimate OOP displacement.…”

Section: Empirical-based Urm Infill Model Accounting For Ip-oop Intermentioning

confidence: 99%

“…Based on experimental evidences (Angel et al [8], Guidi et al [14], Calvi and Bolognini [13], Griffith and Vaculik [12]), a plastic post-peak behaviour is assumed and the collapse OOP displacement is assumed equal to 3.7 times the predicted displacement at peak load.…”

Section: Empirical-based Urm Infill Model Accounting For Ip-oop Intermentioning

confidence: 99%

“…OOP acceleration can produce infills' collapse by their overturning, which is a great risk for life safety as well as an obstacle to escape/rescue operations during seismic emergency [2]: in this sense, the OOP collapse of infill walls is associable to the attainment of the Life Safety Limit State (LS). A great number of experimental and analytical works concerning the IP behaviour of URM infills is available in literature ( [3][4][5][6], among many others) and some analytical and experimental works have been proposed about their OOP behaviour, especially in recent years ( [7][8][9][10][11][12][13][14][15], among others), and concerning the IP-OOP interaction phenomena, i.e., the effects of IP actions on the OOP behaviour and vice versa. For instance, several authors showed through analytical and experimental studies how the IP displacement demand affects the OOP response of infills in terms of capacity and demand acting on them.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Empirical-Based Infill Model Accounting for in-Plane/Out-of-Plane Interaction Applied for the Seismic Assessment of Ec8-Designed Rc Frames

Ricci¹,

Domenico²,

Verderame³

2017

In situ cyclic tests on existing stone masonry walls and strengthening solutions

Arêde

Earthq Engng Struct Dyn

et al. 2010

The present work reports on an in situ experimental test campaign carried out on abandoned traditional masonry houses after the 9th July 1998 earthquake that seriously hit the Faial island of Azores. For the testing purposes, an experimental test setup was developed based on a self-equilibrated scheme, which is herein described reporting on the advantages and drawbacks of this in situ test setup.Five specimens were tested aiming at characterizing the out-of-plane behavior of stone masonry walls and strengthening solutions recommended for post-earthquake interventions. A detailed comparison between solutions' efficiency is presented including a cost vs benefit analysis.In order to assess the efficiency of the developed test setup for other applications on stone masonry walls, an in-plane test on an existing URM panel is also presented. Several related issues are discussed, namely the advantages of dealing with the real boundary conditions and the capacity of providing valuable information of the response, as well as a detailed analysis of the obtained results.The authors believe that this work provides an increase in knowledge on the seismic behavior of the existing masonry constructions, resulting from the development of an in situ test setup and the efficiency quantification of strengthening solutions. Therefore, the work is thought to positively contribute for the preservation of architectural heritage and for its seismic vulnerability reduction.