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This paper investigates the capability of advanced numerical modelling techniques to simulate experimental observations as damage or deformations in complex masonry structures. The case of the church of St. Bassiano in Pizzighettone, Cremona Italy is chosen. A multidisciplinary research was set up to collect data as geometric survey with Lidar technology, measurement of axial force in the iron tie rods of the nave, and a monitoring system for crack widths. The data was used as an input to develop and validate a finite element model to study the structural damage and the evolution of the building in time. The finite element model features a three-dimensional geometry, which is created in part automatically, taking advantage of a parametric model for ribbed masonry vaults, proposed recently by the authors. The FE model results in close adherence with the real building structure, due to the accuracy of the collected data. The simulation model features a continuum plastic damage model to take into consideration the masonry constitutive behaviour. The results show how the system response is closely related to the structural evolution in time, associated with the dismantling of the chapels on the south side and the addition of the iron tie rods in the nave. The numerical simulations highlight also the important effect of the soil settlements in the present crack pattern. The information obtained using this approach will allow to understand the active mechanisms in the building and to optimise the technical interventions in critical parts of the structure.
[1] H. Stovel, Origins and influence of the Nara document on authenticity, APT Bulletin 39 (2/3) (2008)
[2] S. Saloustros, L. Pelà, P. Roca, J. Portal, Numerical analysis of structural damage in the church of the Poblet Monastery, Engineering Failure Analysis 48 (2015) 41-61,
[3] P. Roca, M. Cervera, G. Gariup, L. Pela’, Structural Analysis of Masonry Historical Constructions. Classical and Advanced Approaches, Archives of Computational Methods in Engineering 17 (3) (2010) 299-325, doi:https://doi.org/10.1007/s11831-010-9046-1.
[4] H. Macher, T. Landes, P. Grussenmeyer, From Point Clouds to Building Information Models: 3D Semi-Automatic Reconstruction of Indoors of Existing Buildings, Applied Sciences 7 (10) (2017) 1030
[5] G. Angjeliu, G. Cardani, D. Coronelli, A parametric model for ribbed masonry vaults, Automation in Construction 105 (2019) 102785, doi:https://doi.org/10.1016/j.autcon.2019.03.006.
[6] S. Havemann, D.W. Fellner, Generative mesh modeling, University of Braunschweig-Institute of Technology, 2005.
[7] G. Angjeliu, D. Coronelli, G. Cardani, Challenges in Modelling Complex Geometry in Historical Buildings for Numerical Simulations, Proc. The 18th International Conference on Geometry and Graphics, Vol. 809, Springer, Milan, Italy, 2019, pp. 1218-1230
[8] A. Taliercio, L. Binda, The Basilica of San Vitale in Ravenna: Investigation on the current structural faults and their mid-term evolution, Journal of Cultural Heritage 8 (2) (2007) 99-118,
[9] P. Roca, M. Cervera, L. Pelà, R. Clemente, M. Chiumenti, Continuum FE models for the analysis of Mallorca Cathedral, Engineering Structures 46 (2013) 653-670,
[10] G. Angjeliu, D. Coronelli, G. Cardani, T. Boothby, Structural assessment of iron tie rods based on numerical modelling and experimental observations in Milan Cathedral, Engineering Structures 206 (2020) 109690, doi:https://doi.org/10.1016/j.engstruct.2019.109690.
[11] P. Glira, N. Pfeifer, C. Briese, C. Ressl, A Correspondence Framework for ALS Strip Adjustments based on Variants of the ICP Algorithm, Photogrammetrie - Fernerkundung - Geoinformation 2015 (4) (2015) 275-289, doi:10.1127/pfg/2015/0270.
[12] G. Cardani, G.E. Massetti, When the strengthening of historic masonry buildings should be carried out in different phases: the structural reinforcement and monitoring of the Lombard-Romanesque church of Saint Bassiano, in Pizzighettone (CR), Italy, Proc. PROHITEC'17-3rd International Conference on Protection of Historical Constructions, IST Press, Lisbon, 2017, pp. 1-12, isbn:9898481587.
[13] G. Cardani, R. Pizzoli, The town walls of Pizzighettone: A fortified settlement crossed by a river, through six centuries of history, Sustainable Mediterranean Construction (1) (2019),
[14] G. Angjeliu, G. Cardani, D. Coronelli, Digital Modelling and Analysis of Masonry Vaults, ISPRS - International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences XLII-2/W11 (2019) 83-89, doi:https://doi.org/10.5194/isprs-archives-XLII-2-W11-83-2019.
[15] Hibbitt, Karlsson, Sorensen, ABAQUS Manual, Dassault Systèmes, 2016.
[16] J.H. Lee, G.L. Fenves, Plastic-damage model for cyclic loading of concrete structures, Journal of Engineering Mechanics-Asce 124 (8) (1998) 892-900,
[17] C.S. Ministero delle Infrastrutture d dei Trasporti, Circolare 2 febbraio 2009, n. 617-Istruzioni per l’applicazione delle “Nuove norme tecniche per le costruzioni” di cui al DM 14 gennaio 2008, Gazzetta Ufficiale, 2009.
[18] G. Cardani, D. Coronelli, G. Angjeliu, Damage observation and settlement mechanisms in the naves of the Cathedral of Milan, Proc. Structural Analysis of Historical Constructions (SAHC) Leuven, Belgium, 2016
Published on 30/11/21
Submitted on 30/11/21
Volume Numerical modeling and structural analysis, 2021
DOI: 10.23967/sahc.2021.035
Licence: CC BY-NC-SA license
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