Study of the static and seismic performance of a geogrid reinforced soil wall as bridge abutment in Concepción

Authors

  • Maribell González Municipalidad de Llanquihue, Chile
  • Felipe A. Villalobos Universidad Católica de la Santísima Concepción, Chile image/svg+xml
  • Alejandro Méndez EMIN Sistemas Geotécnicos
  • Pablo Carrillo EMIN Sistemas Geotécnicos

DOI:

https://doi.org/10.4067/s0718-28132018000200041%20

Keywords:

Geogrid, Reinforced soil wall, Static and seismic stability, Internal and external stability

Abstract

The 27th February 2010 earthquake in central and south of Chile was a very strong test for recently constructed geosynthetics reinforced soil wall solutions as bridge abutments. This 8.8 moment magnitude subduction earthquake caused severe damage to several traditional reinforced concrete walls for bridge abutments. However, no significant damage was found in relatively new geosynthetics reinforced solutions. For that reason, it is important to review the design and construction employed in these projects. To this end, a representative case located close to the epicentre is described and studied. Moreover, information is provided regarding the foundation soils, design and construction sequence of the geosynthetics reinforcement used for bridge abutments. The foundation soils were poor, corresponding mainly to marine and fluvial deposits close to the stream and mouth of the Andalién River. The analysis covers the verification of static and seismic external and internal stability. In addition, global static and seismic analyses are carried out. The methods used for the analyses are limit equilibrium and pseudostatic following recommendations of the FHWA. Results show that the design was adequate to cope with such a strong seismic event in terms of external and internal stability. Nevertheless, it was found that the inclusion of piles prevented a global seismic failure of the geogrid reinforced soil walls as bridge abutment. Final comments and remarks are presented related to design and construction which may explain the favorable performance of geosynthetics reinforced structures under this strong subduction earthquake.

References

Abu-Hejleh, N., Wang, T. and Zornberg, J.G. (2000). Performance of geosynthetic-reinforced walls supporting bridge and approaching roadway structures. In Advances in Transportation and Geoenvironmental Systems Using Geosynthetics, ASCE, 218-243.

ASTM D6637 (2015). Standard test method for determining tensile properties of geogrids by the single or multi-rib tensile method. West Conshohocken, PA, USA.

Boroschek, R.L., Soto, P. and Leon, R. (2010). Maule Region Earthquake, 27 February 2010, Mw 8.8. National Accelerometer Net renadic.cl, Report 10/08, University of Chile.

BS 8006 (2010). Code of practice for strengthened/reinforced soil and other fills. British Standard Institution, Milton Keynes, UK.

Buckle, I., Hube, M., Chen, G., Yen, W.H. and Arias, J. (2012). Structural performance of bridges in the offshore Maule earthquake of 27 February 2010. Earthquake Spectra 28(1), 533-552.

Das, B.M. (2012). Retaining walls. Handbook of Geosynthetic Engineering. Geosynthetics and their applications. Edited by Shukla, S.K. Second edition. Thomas Telford.

FHWA (2011). Postearthquake reconnaissance report on transportation infrastructure impact of the February 27, 2010, offshore Maule Earthquake in Chile. Federal Highway Administration USA. Publication No. FHWA-HRT-11-030.

FHWA (2009). Design and construction of mechanically stabilized earth walls and reinforced soil slopes. Federal Highway Administration USA. Publication No. FHWA-NHI-10-024.

FHWA (2001). Mechanically stabilized earth walls and reinforced soil slopes design and construction guidelines. Federal Highway Administration USA. Publication No. FHWA-HRT-00-043.

Galindo, A. (2014). Actualidad del diseño de muros de suelo reforzado, análisis comparativo entre FHWA NHI-10-024 (EEUU), BS8006 (Gran Bretaña) y EBGEO 2010 (Alemania). Ingeniería Civil 175, 115-124.

Geo5 (2015). MSE wall. Verification of mechanically stabilized earth walls and segmental retaining walls reinforced by geogrids. Fine civil engineering software. Praha, Czech Republic.

GGU Stability (2015). Slope stability analysis and analysis of soil nailing and reinforced earth walls. GGU GmbH, CivilServe.

González, M.D. (2015). Design and construction of retaining structures reinforced by geogrids for bridge abutments. Civil Engineer degree project, Catholic University of Concepción, Chile (in Spanish).

Helwany, S.M., Wu, J.T. and Froessl, B. (2003). GRS bridge abutments—an effective means to alleviate bridge approach settlement. Geotextiles and Geomembranes 21(3), 177-196.

Hube, M., Santa María, H. and Villalobos, F. (2010). Preliminary analysis of the seismic response of bridges during the Chilean 27 February 2010 earthquake. Obras y Proyectos 8, 48-57.

Jacobs, F., Ruiken, A. and Ziegler, M. (2016). Investigation of kinematic behavior and earth pressure development of geogrid reinforced soil walls. Transportation Geotechnics 8, 57-68.

Koseki, J., Koda, M., Matsuo, S., Takasaki, H. and Fujiwara, T. (2012). Damage to railway earth structures and foundations caused by the 2011 off the Pacific Coast of Tohoku Earthquake. Soils and Foundations 52(5), 872-889.

Ledezma, C., Hutchinson, T., Ashford, S.A., Moss, R., Arduino, P., Bray, J.D., Olson, S., Hashash, Y.M., Verdugo, R., Frost, D. and Kayen, R. (2012). Effects of ground failure on bridges, roads, and railroads. Earthquake Spectra 28(1), 119-143.

Ruiz-Tagle, L. and Villalobos, F. (2011a). Experimental study of the lateral earth pressure on retaining structures in soils reinforced with geogrids. Revista Ingeniería de Construcción 26(3), 299-320.

Ruiz-Tagle, L. and Villalobos, F. (2011b). Estudio experimental y numérico del desplazamiento y rotación de suelo reforzado con geomallas bajo empuje activo. Obras y Proyectos 9, 59-65.

Soubra, A.H. (1999). Upper-bound solutions for bearing capacity of foundations. Journal of Geotechnical and Geoenviromental Engineering 125, No. 1, 59-68.

Tatsuoka, F., Koseki, J., Tateyama, M., Munaf, Y. and Horii, K. (1998). Seismic stability against high seismic loads of geosyntheticreinforced soil retaining structures. 6th International Conference on Geosynthetics, Atlanta, USA, R.K. Rowe ed., vol. 1, 103-142.

Tatsuoka, F., Tateyama, M. and Koseki, J. (1996). Performance of soil retaining walls for railway embankments. Soils and Foundations 36, 311-324.

Verdugo, R., Villalobos, F., Yasuda, S., Konagai, K., Sugano, T., Okamura, M., Tobita, T. and Torres, A. (2010). Description and analysis of geotechnical aspects associated to the large 2010 Chile earthquake. Obras y Proyectos 8, 25-36.

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Published

2018-12-01

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Issue

No. 24 (2018)

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Articles

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How to Cite

Study of the static and seismic performance of a geogrid reinforced soil wall as bridge abutment in Concepción. (2018). Obras Y Proyectos, 24, 41-52. https://doi.org/10.4067/s0718-28132018000200041 (Original work published 2021)