Physical model test and numerical simulation for the interaction analysis between tunnel and masonry arch bridge

Si-Yi Huang; Li-Yuan Tong; Ming-Fei Zhang; Tao Qiu; Xiao-Dong Li; Jia-Jia Wan

doi:10.1016/j.undsp.2025.07.006

Underground Space ›› 2026, Vol. 26 ›› Issue (1) :106 -125. DOI: 10.1016/j.undsp.2025.07.006

Research article

research-article

Physical model test and numerical simulation for the interaction analysis between tunnel and masonry arch bridge

Author information +

History +

PDF (6058KB)

Abstract

Masonry arch bridges serve as essential transport infrastructure and are often protected as cultural heritage sites. While most studies emphasize their response to vertical loading, limited attention has been given to their behavior under the influence of nearby tunnel excavation. This study investigates the interaction between tunnel-induced ground movement and masonry arch bridges through physical model tests and numerical simulations. Two typical arch bridge types are examined to assess deformation patterns caused by tunneling. A coupled discrete element and finite difference method is proposed to simulate soil-structure interactions, and the model is validated against experimental results. The results highlight that the arch span has a major impact on soil behavior. Larger spans lead to wider settlement zones and more uniform stress distribution but increase structural vulnerability. Semi-circular arches develop tensile strain at the crown and compressive strain at the foot under tunneling. Meanwhile, the joint displacements follow a three-dimensional Gaussian distribution, influenced by tunnel volume loss and burial depth, especially in circular arches. Increasing Young’s modulus and joint shear stiffness of masonry arch bridges through technical means, such as grouting, is helpful to reduce deformation and cracking. These findings support risk assessment and design improvements for masonry bridges in tunneling environments.

Keywords

Physical model test / Numerical simulation / Masonry arch bridge / Soil-structure interaction / DEM-FDM

Cite this article

Download citation ▾

Si-Yi Huang, Li-Yuan Tong, Ming-Fei Zhang, Tao Qiu, Xiao-Dong Li, Jia-Jia Wan. Physical model test and numerical simulation for the interaction analysis between tunnel and masonry arch bridge. Underground Space, 2026, 26(1): 106-125 DOI:10.1016/j.undsp.2025.07.006

登录浏览全文

4963

注册一个新账户忘记密码

Data availability

The data that support the findings of this study are available from the corresponding author upon reasonable request.

CRediT authorship contribution statement

Si-yi Huang: Writing - review & editing, Writing - original draft, Software, Methodology, Data curation. Li-yuan Tong: Writing - review & editing, Project administration, Funding acquisition. Ming-fei Zhang: Project administration, Funding acquisition. Tao Qiu: Writing - review & editing, Methodology. Xiao-dong Li: Project administration. Jia-jia Wan: Project administration, Funding acquisition.

Declaration of competing interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Acknowledgement

The authors would like to acknowledge the financial support from the National Natural Science Foundation of China (Grant Nos. 52178384 and 52478388).

References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Amorosi, A., Boldini, D., De Felice, G., Malena, M., & Sebastianelli, M. (2014). Tunnelling-induced deformation and damage on historical masonry structures. Géotechnique, 64 (2), 118-130.

[2]	Augusthus-Nelson, L., & Swift, G. (2020). Experimental investigation of the residual behaviour of damaged masonry arch structures. Structures, 27, 2500-2512.

[3]	Augusthus-Nelson, L., Swift, G., Melbourne, C., Smith, C., & Gilbert, M. (2018). Large-scale physical modelling of soil-filled masonry arch bridges. International Journal of Physical Modelling in Geotechnics, 18 (2), 81-94.

[4]	Bilotta, E., Paolillo, A., Russo, G., & Aversa, S. (2017). Displacements induced by tunnelling under a historical building. Tunnelling and Underground Space Technology, 61, 221-232.

[5]	Borlenghi, P., Saisi, A., & Gentile, C. (2023). ND testing and establishing models of a multi-span masonry arch bridge. Journal of Civil Structural Health Monitoring, 13 (8), 1595-1611.

[6]	Boscardin, M. D., & Cording, E. J. (1989). Building response to excavation-induced settlement. Journal of Geotechnical Engineering, 115 (1), 1-21.

[7]	Broere, W. (2016). Urban underground space: Solving the problems of today’s cities. Tunnelling and Underground Space Technology, 55, 245-248.

[8]	Chen, H. M., Yu, H. S., & Smith, M. J. (2016). Physical model tests and numerical simulation for assessing the stability of brick-lined tunnels. Tunnelling and Underground Space Technology, 53, 109-119.

[9]	Chiu, Y. C., Wang, T. T., & Huang, T. H. (2014). Investigating continual damage of a nineteenth century masonry tunnel. Proceedings of the Institution of Civil Engineers-Forensic Engineering, 167 (3), 109-118.

[10]	Conde, B., Ramos, L. F., Oliveira, D. V., Riveiro, B., & 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, 148, 621-638.

[11]	Cui, J., & Nelson, J. D. (2019). Underground transport: An overview. Tunnelling and Underground Space Technology, 87, 122-126.

[12]	Dai, H., Sun, Y., Rong, Y., Yu, J., Wu, J., & Zhang, Y. (2024). Study on soil pressure of loose soil in cohesive soil tunnel considering soil arch effect. Frontiers in Earth Science, 12, 1361227.

[13]	Forgács, T., Sarhosis, V., & Bagi, K. (2018). Influence of construction method on the load bearing capacity of skew masonry arches. Engineering Structures, 168, 612-627.

[14]	Gibbings, J. C. (2011). Dimensional analysis. Springer Science & Business Media.

[15]	Gong, C., Ding, W., & Xie, D. (2020). Twin EPB tunneling-induced deformation and assessment of a historical masonry building on Shanghai soft clay. Tunnelling and Underground Space Technology, 98, 103300.

[16]	Liang, R., Xia, T., Hong, Y., & Yu, F. (2016). Effects of above-crossing tunnelling on the existing shield tunnels. Tunnelling and Underground Space Technology, 58, 159-176.

[17]	Lin, D., Zhou, Z., Weng, M., Broere, W., & Cui, J. (2024). Metro systems: Construction, operation and impacts. Tunnelling and Underground Space Technology, 143, 105373.

[18]	Liu, B., Sarhosis, V., Booth, A. D., & Gilbert, M. (2024). The 3D response of a large-scale masonry arch bridge-Part II: Performance at failure. Engineering Structures, 313, 118308.

[19]	Mann, W., & Müller, H. (1982). Failure of shear-stressed masonry: An enlarged theory, tests and application to shear walls. Proceedings of the British Ceramic Society, 30, 223-235.

[20]	Milani, G., & Lourenço, P. B. (2012). 3D non-linear behavior of masonry arch bridges. Computers & Structures, 110, 133-150.

[21]	Ng, C. W. W., Lu, H., & Peng, S. Y. (2013). Three-dimensional centrifuge modelling of the effects of twin tunnelling on an existing pile. Tunnelling and Underground Space Technology, 35, 189-199.

[22]	Pulatsu, B., Erdogmus, E., & Lourenço, P. B. (2019). Simulation of masonry arch bridges using 3D discrete element modeling. In Structural Analysis of Historical Constructions:An Interdisciplinary Approach (pp.871-880). Cham: Springer International Publishing.

[23]	Ritter, S., Giardina, G., DeJong, M. J., & Mair, R. J. (2017). Influence of building characteristics on tunnelling-induced ground movements. Géotechnique, 67 (10), 926-937.

[24]	Sarhosis, V., De Santis, S., & de Felice, G. (2016). A review of experimental investigations and assessment methods for masonry arch bridges. Structure and Infrastructure Engineering, 12 (11), 1439-1464.

[25]	Sarhosis, V., Forgács, T., & Lemos, J. V. (2019). Modelling backfill in masonry arch bridges:a DEM approach. In International Conference on Arch Bridges (pp. 178-184). Cham: Springer International Publishing.

[26]	Sarhosis, V., Liu, B., & Gilbert, M. (2024). The 3d response of a large-scale masonry arch bridge-part I: Performance under low and medium loading levels. Engineering Structures, 316, 118496.

[27]	Schanz, T. (1999). Formulation and verification of the Hardening-Soil Model. In RBJ Brinkgreve, Beyond 2000 in Computational Geotechnics (pp. 281-290).

[28]	Sirivachiraporn, A., & Phienwej, N. (2012). Ground movements in EPB shield tunneling of Bangkok subway project and impacts on adjacent buildings. Tunnelling and Underground Space Technology, 30, 10-24.

[29]	Stamhuis, E., & Thielicke, W. (2014). PIVlab-towards user-friendly, affordable and accurate digital particle image velocimetry in MATLAB. Journal of Open Research Software, 2 (1), 30.

[30]	Sun, Z., Zhang, D., Li, A., Lu, S., Tai, Q., & Chu, Z. (2022). Model test and numerical analysis for the face failure mechanism of large cross-section tunnels under different ground conditions. Tunnelling and Underground Space Technology, 130, 104735.

[31]	Tran, V. H., Vincens, E., Morel, J. C., Dedecker, F., & Le, H. H. (2014). 2D-DEM modelling of the formwork removal of a rubble stone masonry bridge. Engineering Structures, 75, 448-456.

[32]	Wang, H., Leung, C. F., Yu, J., & Huang, M. (2020). Axial response of short pile due to tunnelling-induced soil movement in soft clay. International Journal of Physical Modelling in Geotechnics, 20 (2), 71-82.

[33]	Wang, M., Dong, Y., Yu, L., Fang, L., Wang, X., & Liu, D. (2019). Experimental and numerical researches of precast segment under radial dislocation conditions. Tunnelling and Underground Space Technology, 92, 103055.

[34]	Xu, J., Franza, A., Marshall, A. M., & Losacco, N. (2021a). Role of footing embedment on tunnel-foundation interaction. Journal of Geotechnical and Geoenvironmental Engineering, 147 (9), 06021009.

[35]	Xu, J., Franza, A., Marshall, A. M., Losacco, N., & Boldini, D. (2021b). Tunnel-framed building interaction: Comparison between raft and separate footing foundations. Géotechnique, 71 (7), 631-644.

[36]	Xu, J., Gui, J., & Sheil, B. (2024). A numerical investigation of the role of basements on tunnel-frame interaction in sandy soil. Computers and Geotechnics, 169, 106197.

[37]	Yang, J., & Gu, X. Q. (2013). Shear stiffness of granular material at small strains: Does it depend on grain size? Géotechnique, 63 (2), 165-179.

[38]	Yiu, W. N., Burd, H. J., & Martin, C. M. (2017). Finite-element modelling for the assessment of tunnel-induced damage to a masonry building. Géotechnique, 67 (9), 780-794.

[39]	Zhang, X., Qin, H., Xu, Y., Qu, H., & Chen, C. (2024). Performance of an operational shield tunnel due to construction of a large cross-sectional straight-walled arch tunnel above-crossing. Alexandria Engineering Journal, 108, 863-877.