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Masonry arches represent the most important structural components of masonry arch bridges. Their response is strongly affected by material nonlinearity which is associated with the masonry texture. For this reason, the use of mesoscale models, where units and mortar joints are individually represented, enables accurate response predictions under different loading conditions. However, these detailed models can be very computationally demanding and unsuitable for practical assessments of large structures. In this regard, the use of macro-models, based on simplified homogenised continuum representations for masonry, can be preferable as it leads to a drastic reduction of the computational burden. On the other hand, the latter modelling approach requires accurate calibration of the model parameters to correctly allow for masonry bond. In the present paper, a simplified macro-modelling strategy, particularly suitable for nonlinear analysis of multi-ring brick-masonry arches, is proposed and validated. A numerical calibration procedure, based on genetic algorithms, is used to evaluate the macro-model parameters from the results of meso-scale “virtual” tests. The proposed macroscale description and the calibration procedure are applied to simulate the nonlinear behaviour up to collapse of two multi-ring arches previously tested in laboratory and then to predict the response of masonry arches interacting with backfill material. The numerical results confirm the ability of the proposed modelling strategy for masonry arches to predict the actual nonlinear response and complex failure mechanisms, also induced by ring separation, with a reduced computational cost compared to detailed mesoscale models.
[1] Fanning, P. J., Boothby, T. E., and Roberts, B. J. Longitudinal and transverse effects in masonry arch assessment. Constr. Build. Mat. (2001) 15(1):51-60.
[2] Moreira, V. N., Fernandes, J., Matos, J. C., Oliveira, D.V. Reliability-based assessment of existing masonry arch railway bridges. Constr. Build. Mat. (2016) 115, 544-554.
[3] Sarhosis, V., De Santis, S., and De Felice, G. A review of experimental investigations and assessment methods for masonry arch bridges. Structure and Infrastructure Engineering (2016) 12(11):1439-1464.
[4] Melbourne, C. and Gilbert, M. 1995. The behaviour of multi-ring brickwork arch bridges. Structural Engineer (1995) 73(3):39–47.
[5] Gilbert, M., Casapulla, C., and Ahmed, H.M. 2006. Limit analysis of masonry block structures with non-associative frictional joints using linear programming. Computers and Structures (2006) 84:873-887.
[6] Cavicchi, A., and Gambarotta, L. Collapse analysis of masonry bridges taking into account arch–fill interaction. Engineering Structures, (2005) 27(4):605-615.
[7] Smith, C., and Gilbert, M. Application of discontinuity layout optimization to plane plasticity problems. Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences (2007) 463(2086):2461-2484.
[8] Conde, B., Ramos, L. F., Oliveira, D. V., Riveiro, B., and Solla, M. (2017). Structural assessment of masonry arch bridges by combination of non-destructive testing techniques and three-dimensional numerical modelling: Application to Vilanova bridge. Engineering Structures (2017) 148:621-638.
[9] Pelà, L., Aprile, A., and Benedetti, A. Comparison of seismic assessment procedures for masonry arch bridges. Construction and Building Materials, (2013) 38:381-394.
[10] Milani, G., and Lourenço, P. B. 3D non-linear behavior of masonry arch bridges. Computers & Structures (2012) 110:133-150.
[11] Caddemi, S., Caliò, I., Cannizzaro, F., D’Urso, D., Occhipinti, G., Pantò, B., ... and Zurlo, R. A ‘Parsimonious’ 3D Discrete Macro-Element method for masonry arch bridges. Proceeding of 10th IMC Conference, Milan (Italy), 9-11 July (2018)
[12] Cannizzaro, F., Pantò, B., Caddemi, S., and Caliò, I. A Discrete Macro-Element Method (DMEM) for the nonlinear structural assessment of masonry arches. Engineering Structures (2018) 168:243-256.
[13] Pantò, B., Cannizzaro, F., Caddemi, S., Caliò, I., Chácara, C., and Lourenço, P.B. Nonlinear modelling of curved masonry structures after seismic retrofit through FRP reinforcing. Buildings (2017) 7(3), 79.
[14] Pulatsu, B., Erdogmus, E., and Lourenço, P. B. Comparison of in-plane and out-of-plane failure modes of masonry arch bridges using discontinuum analysis. Engineering Structures, (2019) 178:24-36.
[15] Sarhosis, V., Forgács, T., Lemos, J.V. A discrete approach for modelling backfill material in masonry arch bridges. Computers & Structures (2019) 224,106108.
[16] Zhang, Y., Macorini, L. and Izzuddin, B. A. Mesoscale partitioned analysis of brick-masonry arches. Engineering Structures (2016) 124:142-166.
[17] Tubaldi, E., Macorini, L. and Izzuddin, B. A. Three-dimensional mesoscale modelling of multi-span masonry arch bridges subjected to scour. Eng.Struct. (2018) 165: 486-500.
[18] Macorini, L. and Izzuddin, B. A. A non‐linear interface element for 3D mesoscale analysis of brick‐masonry structures. International Journal for numerical methods in Engineering, (2011) 85(12):1584-1608.
[19] Chisari C, Macorini L, Izzuddin BA, 2020. Multiscale model calibration by inverse analysis for nonlinear simulation of masonry structures under earthquake loading. International Journal for Multiscale Computational Engineering, DOI: 10.1615/IntJMultCompEng.2020031740.
[20] Minga, E., Macorini, L. and Izzuddin, B. A. A 3D mesoscale damage-plasticity approach for masonry structures under cyclic loading. Meccanica (2018) 53(7):1591-611.
[21] Deb, K., Pratap, A., Agarwal, S. and Meyarivan, T., A Fast and Elitist Multiobjective Genetic Algorithm: NSGA-II. IEEE Trans. on Evolut. Comput. (2002) 6(2):182-197
[22] Chisari, C., Amadio, C., TOSCA: a Tool for Optimisation in Structural and Civil engineering Analyses. Int. Journal of Advanced Structural Eng. (2018) 10(4):401-419.
[23] Izzuddin, B. A., Nonlinear dynamic analysis of framed structures, PhD, Imperial College London, 1991.
[24] Melbourne, C., Wang, J., Tomor, A., Holm, G., Smith, M., Bengtsson, P. E., Bien, J., Kaminski, T., Rawa, P., Casas, J. R., Roca, P. & Molins, C. (2007) Masonry Arch Bridges Background document D4.7. Sustainable Bridges. Report number: Deliverable D4.7.
Published on 29/11/21
Submitted on 29/11/21
Volume Numerical modeling and structural analysis, 2021
DOI: 10.23967/sahc.2021.008
Licence: CC BY-NC-SA license
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