Vibration-Based Tests and Results for the Evaluation of Infill Masonry Walls Influence on the Dynamic Behaviour of Buildings: A Review

Nicoletti, Vanni; Arezzo, Davide; Carbonari, Sandro; Gara, Fabrizio

doi:10.1007/s11831-022-09713-y

Cited by 16 publications

(6 citation statements)

References 109 publications

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“…En ASCE 41-13 [9] se define el término partición como aquel componente vertical que no soporta carga y que provee división de espacios. Al respecto, en nuestro medio existe la concepción de ignorar las particiones en la etapa de diseño; lo cual es conservador y simplifica los procedimientos de cálculo [10]. En este sentido, especialmente cuando se trata de particiones pesadas, se requieren detalles en los planos que garanticen la estabilidad de esta y que no contribuya a la rigidez lateral de la estructura ni a resistir fuerzas; debido que estos elementos tienen la capacidad de inducir acciones no consideradas en el diseño, como lo es la torsión adicional [11].…”

Section: Marco Teóricounclassified

Diagnóstico de estructuras basado en vibraciones a partir de una red local de acelerógrafos

2023

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La evaluación para establecer las necesidades de una estructura es bastante compleja y más si se requiere información que no está disponible. Por consiguiente, es necesario el análisis y estrategias experimentales; ya que las guías y normativas disponibles para la evaluación de estructuras existentes están limitadas al juicio ingenieril y particularidades de cada caso, lo cual hace que estas no puedan ser fácilmente definidas o estandarizadas. Por lo tanto, el objetivo de esta investigación se enfoca en validar la eficiencia del análisis de vibraciones, para diagnosticar problemas estructurales, comparado con metodologías tradicionales que incorporan el uso de técnicas no destructivas en una estructura operativa. Para tales efectos, se presenta el caso de estudio de una edificación residencial, donde se evaluó un sistema de paredes que han presentado de manera persistente agrietamientos; a pesar de que algunos de estos elementos fueron reemplazados completamente. Se efectuó un monitoreo de respuestas de vibraciones y la data se utilizó para elaborar modelos matemáticos, cuyos errores de ajuste sirvieron para el diseño de indicadores de daños que en conjunto con técnicas de Machine Learning, para el reconocimiento estadístico de patrones, se pudo caracterizar dinámicamente el sistema estudiado y diagnosticar que este no presentaba un desempeño anómalo que pudiera haber influenciado el comportamiento deficiente de los sistemas de mampostería.

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Section: Marco Teóricounclassified

Diagnóstico de estructuras basado en vibraciones a partir de una red local de acelerógrafos

2023

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“…[25][26][27][28]): (i) based only on the fracture of TRM for the out-of-plane bending [20], or (ii) taking into account also masonry crushing (e.g., Refs. [25,27,29]). An assessment of the structural performance is undertaken, usually along with a damage assessment applying non-destructive techniques such as ambient vibration testing [29][30][31][32][33].…”

Section: Introductionmentioning

confidence: 99%

“…[25,27,29]). An assessment of the structural performance is undertaken, usually along with a damage assessment applying non-destructive techniques such as ambient vibration testing [29][30][31][32][33].…”

Section: Introductionmentioning

confidence: 99%

Empirical Equations for Modelling Yarn–Mortar Debonding in TRM-Strengthened Masonry Walls Subjected to Out-of-Plane Loading

Kouris,

Triantafyllou,

Bournas

et al. 2023

Buildings

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The effectiveness of textile-reinforced mortar (TRM) strengthening of masonry walls largely depends on the bond between the constituent materials. Finite element analysis (FEA) can provide valuable insights on the effect of the parameters affecting the bond; however, detailed FEA is computationally intensive. To alleviate this, we develop novel empirical equations to estimate effective textile fibre properties, thus implicitly accounting for yarn and mortar debonding. As a result, 3D finite element simulations of strengthened wall specimens are simplified and accelerated. The proposed scheme is calibrated using load–displacement paths derived from experimental data, and the simulated failure modes are compared against the experimental ones demonstrating perfect agreement. A parametric analysis is conducted, exploring the impact of the mechanical ratio of TRM reinforcement and the axial wall load on the effectiveness of TRM strengthening. We demonstrate that low values of mechanical reinforcement, corresponding to natural fibres, give rise to an 8-fold increase in the capacity of unreinforced walls. The findings draw conclusions about the efficacy of TRM strengthening in masonry structures, and provide valuable insights for optimising TRM reinforcement, considering different fibre materials and axial loads in masonry structures.

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“…A comprehensive literature review about vibration-based methods for damage detection can be found in. [1][2][3] Among them, the response-based methods are the most adopted ones, even if they present some challenges in real building applications [4] related to the location and the extent of damage (detection of structural and/or non-structural damaged components), the sensitivity of the dynamic response to damage, the choice of damage indexes to be used, the sensor locations, etc. However, although this strategy is widely recognised to be of useful application, a relatively low number of works can be found dealing with applications on real or scaled structures.…”

Section: Introductionmentioning

confidence: 99%

“…In framed RC and steel buildings, infills are the most important non-structural elements that may affect the structural dynamic response [3,18] and the seismic performance, [19][20][21][22][23] sometimes leading to the development of undesirable effects, such as the activation of soft storey mechanisms or the shear failure of short unconfined columns. [24,25] Thus, not only damage to structural elements but also to non-structural components often reflects in changes on the dynamic behaviour of infilled structures, as proved by some authors that investigated the dynamic response of infilled buildings after damage produced by earthquakes all around the world.…”

Section: Introductionmentioning

confidence: 99%

Detection of infill wall damage due to earthquakes from vibration data

Nicoletti

Arezzo

Carbonari

et al. 2022

Earthq Engng Struct Dyn

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Vibration‐based methodologies are nowadays gaining increasing application for the structural health monitoring and damage detection on buildings, especially damage due to earthquakes. A fast and efficient damage recognition on structural and non‐structural components can support the decision‐making process after exceptional events and may contribute to reduce troubles due to the inoccupancy of buildings. The paper offers insights on the usefulness of vibration data for the damage detection in infilled frame structures starting from the tracking of the stiffness and modal properties of an infilled laboratory steel‐concrete composite mock‐up subjected to vibration‐based tests. The mock‐up has been object of an extensive experimental campaign that involved both quasi‐static cyclic and dynamic tests characterized by different level of excitation provided to the structure. Cyclic load tests are performed to simulate the effects of earthquakes by progressively increasing the imposed displacement to the cracking and then to the failure of infills. The dynamic tests are executed at the various steps to capture the effects of the infill damage on the global dynamic response triggered by excitations of different amplitudes. Results of dynamic and quasi‐static tests are used to correlate the infill damage with the mechanical properties and the modal parameters of the mock‐up, as well as with the vibration amplitude, providing information about the damage expected during low and moderate seismic events as a function of the registered dynamic response of the building by structural health monitoring systems.

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Vibration-Based Tests and Results for the Evaluation of Infill Masonry Walls Influence on the Dynamic Behaviour of Buildings: A Review

Cited by 16 publications

References 109 publications

Diagnóstico de estructuras basado en vibraciones a partir de una red local de acelerógrafos

Diagnóstico de estructuras basado en vibraciones a partir de una red local de acelerógrafos

Empirical Equations for Modelling Yarn–Mortar Debonding in TRM-Strengthened Masonry Walls Subjected to Out-of-Plane Loading

Detection of infill wall damage due to earthquakes from vibration data

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