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11 results on '"Sangirardi, M."'

2. An integrated approach to the structural assessment of historic buildings: The case of St. Angelo Church in Anagni

Author

Avelino, R. M., Oliveri, C., Donval, E., Fugger, R., Lai, M., Lasorella, M., Saretta, Y., Weichbrodt, A., and Sangirardi, M.

Subjects
Safety Assessment, Architectural Heritage, Equilibrium, Architectural Heritage, Safety Assessment, Masonry, Equilibrium, Limit analysis Patrimonio architettonico, Verifiche di sicurezza, Muratura, Equilibrio, Analisi limite, Limit analysis Patrimonio architettonico, Equilibrio, Verifiche di sicurezza, Muratura, Masonry, Analisi limite
Published
2022

7. Coupled three-dimensional analysis of the progressive tunnelling-induced damage to masonry buildings: is it always worth it?

Author

Marialuigia Sangirardi, Angelo Amorosi, Amorosi, A., and Sangirardi, M.

Subjects
Deformation (mechanics), Process (engineering), business.industry, 3D analysis, media_common.quotation_subject, Excavation, Building and Construction, Structural engineering, Masonry, Geotechnical Engineering and Engineering Geology, Tunnelling, Simple (abstract algebra), FE simulations, FE simulation, Tunnelling, FE simulations, Soil-structure interaction, 3D analysis, Masonry, Damage estimation, Point (geometry), Facade, Soil-structure interaction, 3D analysi, Eccentricity (behavior), Damage estimation, business, Geology, media_common
Abstract

The development of urban mobility implies the construction of tunnels, often interacting with valuable masonry structures. It is thus necessary to develop rational and reliable procedures to estimate the potential excavation-induced damage, which imply the analysis of the related soil-structure interaction problem. Classical approaches to soil-structure interaction are often characterised by relatively simple schematisations for either one or both components of the problem, as, for example, springs for the soil or equivalent plates for the structure. Such simplified assumptions prove to be appropriate for conventional soil-foundation cases, while show all their limitations when tackling more complex problems, as those involving the excavation in the vicinity or beneath masonry structures. In such cases, the need for reliable prediction of the potential damage induced by construction activities on surface structures justifies the adoption of more advanced numerical approaches, based on realistic constitutive assumptions for both soil and masonry, together with an accurate modelling schematisation of the excavation process. This is what proposed in this paper, where a 3D Finite Element approach is adopted to realistically model the multidimensional and progressive nature of the excavation process, the strongly non-linear soil behaviour and the non-linear anisotropic response that characterises masonry structures, here included accounting for their 3D geometrical characteristics. All the analyses are carried out with reference to a sample masonry building founded on strip footings, interacting with a shallow tunnel in a typical London soil profile, already examined in the literature. Different configurations of the structure, considering the sole facade or the whole building, are examined. Also, different relative positions of the tunnel and the structure, in terms of skew angle and eccentricity, are considered. In all the analyses, the excavation is simulated either reproducing the whole three-dimensional advancement of the tunnel or through a simplified single-step analysis. A critical review of the deformation regimes and related plastic points patterns resulting from the different analyses point out in which cases it is necessary to accurately model the 3D tunnel advancement to detect the transient effects governing the onset of structural damage.

Published
2021

8. Settlement induced crack pattern prediction through the jointed masonry model

Author

Marialuigia Sangirardi, Marialaura Malena, Gianmarco de Felice, Sangirardi, M., Malena, M., and de Felice, G.

Subjects
business.industry, Constitutive equation, Structural engineering, Masonry, Classification of discontinuities, Mohr–Coulomb theory, Homogenization (chemistry), Numerical modelling, Cohesion (geology), Anisotropy, business, Rock mass classification, Geology, Interlocking
Abstract

Failure mechanisms and crack patterns characterizing the nonlinear response of masonry under both vertical and horizontal load conditions are strongly affected by its intrinsic anisotropic behaviour. Moreover, in case of ancient masonry walls, typically constituted by high strength units (stone blocks or bricks) and weak mortar, texture is one of the key elements that determine failure morphological features. Some analogies between this material and fissured rocks can therefore be envisaged: the discontinuities of a rock mass and their orientation drive failure similarly to mortar joints in masonry walls and in both cases cohesion and friction characterize the response along these weakness planes. However, peculiar features such as interlocking due to staggered head joints and the periodic nature of masonry need to be considered and make its constitutive response more complex. In this research work the in-plane and the out-of-plane behaviour of masonry walls are analysed. The adopted constitutive model has been formulated stemming from a pre-existing one, originally conceived to simulate the behaviour of jointed rock layers, and has been implemented in the commercial code PLAXIS 3D. It is a three-dimensional model based on the identification of preferential orientation of failure planes, on which a Mohr Coulomb failure criterion holds in conjunction with a tensile stress cut-off. Elastic properties are derived from a relatively simple homogenization procedure and geometrical characteristics of blocks as well as the effect of staggered arrangement of head joints are accounted for. Some case-studies for different geometrical configurations are analysed. Results are compared with both experimental evidences and the numerical outcomes obtained resorting to a different constitutive model in which masonry is described as a homogenized anisotropic medium. The proposed model is also adopted for the simulation of a real-scale static soil-structure interaction problem, aiming at highlighting the capability of the model to describe the macroscopic behaviour in terms of collapse mechanism and collapse multiplier. In spite of its simplicity, the proposed approach is able to account for the role of texture with low computational cost and a relatively limited number of mechanical parameters.

Published
2020

9. A coupled structural and geotechnical assessment of the effects of a landslide on an ancient monastery in Central Italy

Author

Gianmarco de Felice, Angelo Amorosi, Marialuigia Sangirardi, Sangirardi, M., Amorosi, A., and de Felice, G.

Subjects
Finite-element modelling, business.industry, Finite element approach, Constitutive equation, 0211 other engineering and technologies, 020101 civil engineering, Landslide, 02 engineering and technology, Masonry, Finite element method, 0201 civil engineering, 021105 building & construction, Geotechnical engineering, Interaction problem, Landslides, business, Geology, Civil and Structural Engineering
Abstract

Every year landslides occur all over the world as a consequence of specific ground conditions, geomorphological, physical or man-made processes. Such phenomena, often triggered by heavy rainfalls or earthquakes, can affect buildings and infrastructures, causing economic and life losses. This work investigates the effects of a landslide, occurred on the 26th of November 2018, on the Monastry of Santa Scolastica in Subiaco (Rome), one of the most ancient and well-preserved examples of medieval architecture in Central Italy. The evolution of the damage pattern observed on the structure is discussed and related to its different causes, aiming at evaluating if possible worsening effects should or not be ascribed to the occurred landslide or to possible future similar events. The study relies on an accurate geometrical description of both the slope and the building, made possible by advanced survey tools. Most of the analyses used to simulate the history of the events occurred to the Monastry were performed by a three-dimensional non-linear finite element model. Elastic-perfectly plastic constitutive assumptions were adopted for the soil, while the structure was modelled by a three-dimensional anisotropic elastic-perfectly plastic constitutive model, specifically conceived for masonry, accounting for block dimensions and staggering joints effects. Finite element approach has proven to be very effective in the analysis of such a coupled interaction problem, leading to a realistic representation of the interplay between the soil displacements and their effects within the structure. The safety conditions of the structure could then be assessed, and the causes of the damage pattern identified, showing that the slope movement did not worsen the pre-existing damage conditions, which should instead be ascribed to the original soil-structure interaction phenomena occurred when an extension of the original structure had been built.

Published
2020

10. Discrete and continuous approaches for the failure analysis of masonry structures subjected to settlements

Author

Patrizia Trovalusci, Marialuigia Sangirardi, Marco Pingaro, Emanuele Reccia, G. de Felice, Marco Pepe, Pepe, M., Sangirardi, M., Reccia, E., Pingaro, M., Trovalusci, P., and de Felice, G.

Subjects
Dilatant, Computer science, Geography, Planning and Development, Constitutive equation, Kinematics, Physics::Geophysics, lcsh:HT165.5-169.9, Dry contact, Discrete system, rigid blocks, rigid block, masonry structure, settlements, business.industry, Building and Construction, Structural engineering, lcsh:City planning, Masonry, limit analysi, Finite element method, FEM/DEM, finite element, limit analysis, masonry structures, Urban Studies, Limit analysis, lcsh:TA1-2040, lcsh:Engineering (General). Civil engineering (General), business
Abstract

Numerical modeling of masonry structures is nowadays still an active research field, and this is partly due to a number of open issues related to preservation and restoration of historical constructions and the availability of computational tools that have become more and more refined. This work focuses on the analysis of settlement-induced failure patterns characterizing the in-plane response of two-dimensional dry-joints masonry panels, which differ in terms of texture, geometry, and settlement configuration. Brick-block masonry, interpreted as a jointed assembly of prismatic particles in dry contact, can be modeled as a discrete system of rigid blocks interacting through contact surfaces with no tensile strength and finite friction, modeled as zero thickness elasto-plastic Mohr-Coulomb interfaces. Different approaches and numerical models have been adopted herein: Limit Analysis (LA), a discrete model DEM, and a continuous Finite Element Model (FEM). Limit Analysis is able to provide fast and reliable results in terms of collapse multiplier and relative kinematics. In this work, a standard LA procedure was coded through Linearized Mathematical Programming to take into account sliding mechanisms through dilatant joints. Discrete models are particularly suitable to study historical masonry materials, where rigid bodies interact between contact and friction. Here, a combined Finite/Discrete Element approach (FEM/DEM) is adopted. Finally, analyses are conducted through the Finite Element approach, resorting to a continuum anisotropic elastic perfectly plastic constitutive model. Some selected case studies have been investigated and found to have adopted the above mentioned models, and numerical results have been interpreted to highlight the capability of the approaches to predict failure patterns for various geometrical features of the structure and settlement configurations.

Published
2020

11. Numerical modelling of the experimental response of SRG systems

Author

Marialuigia Sangirardi, Marialaura Malena, Gianmarco de Felice, Francesca Roscini, Marialaura Malena, Marialuigia Sangirardi, Francesca Roscini, Gianmarco de Felice, Malena, M., Sangirardi, M., Roscini, F., and de Felice, G.

Subjects
Materials science, Mechanical Engineering, 0211 other engineering and technologies, Clamping-grip setup, 02 engineering and technology, 021001 nanoscience & nanotechnology, Mechanics of Materials, Numerical modelling, 021105 building & construction, General Materials Science, Uniaxial tensile behaviour, SRG, 0210 nano-technology, Clevis-grip setup
Abstract

Modern repairing and retrofitting methods for existing structures make use of composite materials, consisting of high strength textiles and a matrix, which can be either polymeric or inorganic. These kinds of techniques have been largely applied to masonry structures, since they significantly improve structural performance with a small increase of weight and a minimum invasiveness. However, the application of organic gluing agents on masonry has revealed some well-known drawbacks, which are almost all overcome resorting to inorganic matrixes, namely cement or lime mortars. An entire class of composites is thus identified as TRM (Textile Reinforced Mortars) or FRCM (Fibre Reinforced Cementitious Matrices). Among them, Steel Reinforced Grout (SRG) are characterized by Ultra High Tensile Strength Steel (UHTSS) cords embedded in mortar matrix and their use to improve the structural performance of existing historical masonry buildings is becoming more and more diffused. Qualification tests and acceptance criteria for SRG have just been defined. Nonetheless, numerical simulation of current available test procedures is mandatory to identify peculiar aspects of the response that at a following stage become an integral part of large scale models, when entire reinforced structures or portions need to be analysed. To this end, this work presents the numerical modelling of two different direct tensile tests on SRG systems: the Clamping-grip setup (RILEM Technical Committee 232-TDT 2016) and the Clevis-grip setup (ICC-ES AC434 2016). Numerical models able to replicate experimental tests and catch fundamental differences in their failure mechanisms are present

Published
2019

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