Abstract
The retaining walls in coral sand sites are inevitably threatened by earthquakes. A series of shaking table tests were carried out to study the seismic stability of gravity retaining walls with coral sand backfill. Parallel tests with quartz sand were performed to compare and discuss the special dynamic properties of coral sand sites. The results show that the acceleration difference between the retaining wall and the coral sand backfill is 76%–92% that of the quartz sand, which corresponds to the larger liquefaction resistance of coral sand compared with the quartz sand. However, the horizontal displacement of the retaining walls with coral sand backfill reaches 79% of its own width under 0.4g vibration intensity. The risk of instability and damage of the retaining walls with coral sand backfill under strong earthquakes needs attention.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Abu Taiyab, M., Alam, M.J. and Abedin, M.Z., 2014. Dynamic soil-structure interaction of a gravity quay wall and the effect of densification in liquefiable sites, International Journal of Geomechanics, 14(1), 20–33.
Adampira, M., Derakhshandi, M. and Ghalandarzadeh, A., 2021. Experimental study on seismic response characteristics of liquefiable soil layers, Journal of Earthquake Engineering, 25(7), 1287–1315.
Anastasopoulos, I., Loli, M., Antoniou, M., Knappett, J. and Brennan, A., 2015. Centrifuge testing of multi-block quay walls, SECED 2015 Conference: Earthquake Risk and Engineering towards a Resilient World, Cambridge, UK.
Arablouei, A., Gharabaghi, A.R.M., Ghalandarzadeh, A., Abedi, K. and Ishibashi, I., 2011. Effects of seawater—structure—soil interaction on seismic performance of caisson-type quay wall, Computers & Structures, 89(23–24), 2439–2459.
Baziar, M.H., Sanaie, M., Amirabadi, O.E., Khoshniazpirkoohi, A. and Azizkandi, A.S., 2020. Mitigation of hunchbacked gravity quay wall displacement due to dynamic loading using shaking table tests, Ocean Engineering, 216, 108056.
Brandes, H.G., 2011. Simple shear behavior of calcareous and quartz sands, Geotechnical and Geological Engineering, 29(1), 113–126.
Calabrese, A. and Lai, C.G., 2016. Sensitivity analysis of the seismic response of gravity quay walls to perturbations of input parameters, Soil Dynamics and Earthquake Engineering, 82, 55–62.
Chen, G.X., Ma, W.J., Qin, Y., Zhao, K. and Yang, J., 2021. Liquefaction susceptibility of saturated coral sand subjected to various patterns of principal stress rotation, Journal of Geotechnical and Geoenvironmental Engineering, 147(9), 04021093.
Chen, S., Chen, G.X., Qi, C.Z., Du, X.L. and Wang, Z.H., 2015. A shaking table-based experimental study of seismic response of three-arch type’s underground subway station in liquefiable ground, Rock and Soil Mechanics, 36(7), 1899–1914. (in Chinese)
Choudhury, D. and Ahmad, S.M., 2007. Stability of waterfront retaining wall subjected to pseudo-static earthquake forces, Ocean Engineering, 34(14–15), 1947–1954.
Dakoulas, P., Vazouras, P., Kallioglou, P. and Gazetas, G., 2018. Effective-stress seismic analysis of a gravity multi-block quay wall, Soil Dynamics and Earthquake Engineering, 115, 378–393.
Durante, M.G., Di Sarno, L., Mylonakis, G., Taylor, C.A. and Simonelli, A.L., 2016. Soil—pile—structure interaction: experimental outcomes from shaking table tests, Earthquake Engineering & Structural Dynamics, 45(7), 1041–1061.
Ebeido, A., Elgamal, A., Tokimatsu, K. and Abe, A., 2019. Pile and pile-group response to liquefaction-induced lateral spreading in four large-scale shake-table experiments, Journal of Geotechnical and Geoenvironmental Engineering, 145(10), 04019080.
Ghalandarzadeh, A., Rahimi, S. and Kavand, A., 2020. Dynamic pore water pressure of submerged backfill on caisson quay walls: 1 g shake table tests, Soil Dynamics and Earthquake Engineering, 132, 106091.
Guo, Y., Luan, M.T., Shi, D.D., Xu, C.S., He, Y. and Li, M.G., 2005. Experimental study on effect of initial stress condition on dynamic behavior and deformation parameters of loose sands, Rock and Soil Mechanics, 26(8), 1195–1200. (in Chinese)
Hyodd, M., Hyde, A.F.L. and Aramaki, N., 1998. Liquefaction of crushable soils, Géotechnique, 48(4), 527–543.
Iai, S., 2019. Evaluation of performance of port structures during earthquakes, Soil Dynamics and Earthquake Engineering, 126, 105192.
Jinguuji, M. and Toprak, S., 2017. A case study of liquefaction risk analysis based on the thickness and depth of the liquefaction layer using CPT and electric resistivity data in the Hinode area, Itako City, Ibaraki Prefecture, Japan, Exploration Geophysics, 48(1), 28–36.
Kim, S.R., Jang, I.S., Chung, C.K. and Kim, M.M., 2005. Evaluation of seismic displacements of quay walls, Soil Dynamics and Earthquake Engineering, 25(6), 451–459.
Koutsourelakis, S., Prévost, J.H. and Deodatis, G., 2002. Risk assessment of an interacting structure—soil system due to liquefaction, Earthquake Engineering & Structural Dynamics, 31(4), 851–879.
Lee, C.J., 2005. Centrifuge modeling of the behavior of caisson-type quay walls during earthquakes, Soil Dynamics and Earthquake Engineering, 25(2), 117–131.
Lee, M.G., Ha, J.G., Manandhar, S., Park, H.J. and Kim, D.S., 2019. Evaluation of performance-based seismic coefficient for gravity-type quay wall via centrifuge tests, Soil Dynamics and Earthquake Engineering, 123, 292–303.
Li, L.C., Liu, X., Liu, H., Wu, W.B., Lehane, B.M., Jiang, G.S. and Xu, M.J., 2022. Experimental and numerical study on the static lateral performance of monopile and hybrid pile foundation, Ocean Engineering, 255, 111461.
Liang, K., He, Y. and Chen, G.X., 2020. Experimental study of dynamic shear modulus and damping ratio characteristics of coral sand from Nansha Islands, Rock and Soil Mechanics, 41(1), 23–31, 38. (in Chinese)
Liu, C.H., Tang, L., Ling, X.Z., Deng, L.J., Su, L. and Zhang, X.Y., 2017. Investigation of liquefaction-induced lateral load on pile group behind quay wall, Soil Dynamics and Earthquake Engineering, 102, 56–64.
Liu, H.X., Zhang, J.M., Zhang, X.D. and Wang, R., 2020. Seismic performance of block-type quay walls with liquefiable calcareous sand backfill, Soil Dynamics and Earthquake Engineering, 132, 106092.
Ma, W.J., Chen, G.X. and Wu, Q., 2019. Experimental study on liquefaction characteristics of saturated coral sand in nansha islands under cyclic loading, Proceedings of the 17th European Conference on Soil Mechanics and Geotechnical Engineering, Reykjavik.
Ma, W.J., Qin, Y., Zhao, K. and Chen, G.X., 2022. Comparisons on liquefaction behavior of saturated coral sand and quartz sand under principal stress rotation, Marine Georesources & Geotechnology, 40(2), 235–247.
Madabhushi, S.P.G., Saito, K. and Booth, E.D., 2013. EEFIT mission to Haiti following the 12th January 2010 earthquake, Bulletin of Earthquake Engineering, 11(1), 35–68.
Meymand, P.J., 1998. Shaking Table Scale Model Tests of Nonlinear Soil-Pile-Superstructure Interaction in Soft Clay, Ph.D. Thesis, University of California, Berkeley.
Montoya-Noguera, S. and Lopez-Caballero, F., 2016. Effect of coupling excess pore pressure and deformation on nonlinear seismic soil response, Acta Geotechnica, 11(1), 191–207.
Peng, Y., Liu, H.L., Li, C., Ding, X.M., Deng, X. and Wang, C.Y., 2021. The detailed particle breakage around the pile in coral sand, Acta Geotechnica, 16(6), 1971–1981.
Rasouli, R., Towhata, I. and Hayashida, T., 2015. Mitigation of seismic settlement of light surface structures by installation of sheet-pile walls around the foundation, Soil Dynamics and Earthquake Engineering, 72, 108–118.
Sandoval, E.A. and Pando, M.A., 2012. Experimental assessment of the liquefaction resistance of calcareous biogenous sands, Earth Sciences Research Journal, 16(1), 55–63.
Su, L., Zhou, L.L., Zhang, X.Y. and Ling, X.Z., 2022. Experimental and numerical modeling on liquefaction resistance of geotextile reinforced sand, Soil Dynamics and Earthquake Engineering, 159, 107345.
Tanaka, Y., 2000. The 1995 Great Hanshin Earthquake and liquefaction damages at reclaimed lands in Kobe Port, International Journal of Offshore and Polar Engineering, 10(1), 64–72.
Tasiopoulou, P., Gerolymos, N. and Gazetas, G., 2014. Seismic effective stress analysis of gravity block type quay walls: Application to piraeus port, Proceedings of the 2nd European Conference on Earthquake Engineering and Seismology, Istanbul.
Teparaksa, J. and Koseki, J., 2018. Effect of past history on liquefaction resistance of level ground in shaking table test, Géotechnique Letters, 8(4), 256–261.
Vahdani, S., Pyke, R. and Siriprusanen, U., 1994. Liquefaction of calcareous sands and lateral spreading experienced in Guam as a result of the 1993 Guam earthquake, Proceedings of the 5th U.S.-Japan Workshop on Earthquake Resistant Design of Lifeline Facilities and Countermeasures Against Soil Liquefaction, Buffalo.
Wang, J.B., Fan, P.X., Wang, M.Y., Dong, L., Ma, L. and Gao, L., 2020. Experimental study of one-dimensional compression creep in crushed dry coral sand, Canadian Geotechnical Journal, 57(12), 1854–1869.
Wang, X.Z., Weng, Y.L., Wei, H.Z., Meng, Q.S. and Hu, M.J., 2019. Particle obstruction and crushing of dredged calcareous soil in the Nansha Islands, South China Sea, Engineering Geology, 261, 105274.
Wu, Q., Ding, X.M., Chen, Z.X. and Zhang, Y.L., 2022c. Shaking Table Tests on Seismic Responses of Pile-soil-superstructure in Coral Sand, Journal of Earthquake Engineering, 26(7), 3461–3487.
Wu, Q., Ding, X.M. and Zhang, Y.L., 2022a. Microfabric evolution of coral sand foundations during seismic liquefaction using 3D images, Soil Dynamics and Earthquake Engineering, 162, 107445.
Wu, Q., Ding, X.M., Zhang, Y.L. and Chen, Z.X., 2020b. Comparative study on seismic response of pile group foundation in coral sand and Fujian Sand, Journal of Marine Science and Engineering, 8(3), 189.
Wu, Q., Ding, X.M., Zhang, Y.L., Chen, Z.X. and Zhang, Y., 2021. Numerical simulations on seismic response of soil-pile-superstructure in coral sand, Ocean Engineering, 239, 109808.
Wu, W.B., Liu, H., Yang, X.Y., Jiang, G.S., El Naggar, M.H., Mei, G. X. and Liang, R.Z., 2020a. New method to calculate apparent phase velocity of open-ended pipe pile, Canadian Geotechnical Journal, 57(1), 127–138.
Wu, W.B., Yang, Z.J., Liu, X., Zhang, Y.P., Liu, H., El Naggar, M.H., Xu, M.J. and Mei, G.X., 2022b. Horizontal dynamic response of pile in unsaturated soil considering its construction disturbance effect, Ocean Engineering, 245, 110483.
Yang, C.W., Zhang, J.J., Qu, H.L., Bi, J.W. and Liu, F.C., 2015. Seismic earth pressures of retaining wall from large shaking table tests, Advances in Materials Science and Engineering, 2015, 836503.
Zhang, Y.P., El Naggar, M.H., Wu, W.B., Wang, Z.Q., Yang, X.Y. and Jiang, G.S., 2022a. Dynamic torsional impedance of large-diameter pipe pile for offshore engineering: 3D analytical solution, Applied Mathematical Modelling, 111, 664–680.
Zhang, Y.P., Wang, Z.Q., El Naggar, M.H., Wu, W.B., Wang, L.X. and Jiang, G.S., 2022b. Three-dimensional wave propagation in a solid pile during torsional low strain integrity test, International Journal for Numerical and Analytical Methods in Geomechanics, 46(12), 2398–2411.
Zhang, Z.Y., Wei, H.Y. and Qin, X., 2017. Experimental study on damping characteristics of soil-structure interaction system based on shaking table test, Soil Dynamics and Earthquake Engineering, 98, 183–190.
Zhou, X.Z., Chen, Y.M., Li, W.W. and Liu, H.L., 2019. Monotonic and cyclic behaviors of loose anisotropically consolidated calcareous sand in torsional shear tests, Marine Georesources & Geotechnology, 37(4), 438–451.
Funding
This work was financially supported by the National Natural Science Foundation of China (Grant Nos. 41831282 and 51878103), the Fundamental Research Funds for the Central Universities (Grant No. 2021CDJQY-042) and Chongqing Talents Program (Grant No. cstc2021ycjh-bgzxm0051).
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Zhang, Yl., Wang, Cl., Ding, Xm. et al. Dynamic Behavior of Gravity Retaining Walls with Coral Sand Backfill Under Earthquakes: Shaking Table Tests. China Ocean Eng 36, 839–848 (2022). https://doi.org/10.1007/s13344-022-0074-z
Received:
Revised:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s13344-022-0074-z