INVESTIGATION OF INNER SHEAR RESISTANCE OF GEOGRIDS BUILT UNDER GRANULAR PROTECTION LAYERS AND RAILWAY BALLAST

Sz. Fischer

doi:10.15802/stp2015/53169

Authors

Sz. Fischer Széchenyi István University Faculty of Architecture, Hungary https://orcid.org/0000-0001-7298-9960

DOI:

https://doi.org/10.15802/stp2015/53169

Keywords:

railway ballast, geogrid reinforcement, granular protection layers, multi-level shear box tests, inner shear resistance

Abstract

Purpose. Using adequate granular materials and layer structures in the railway super- and substructure is able to stabilise railway track geometry. For this purpose special behaviour of above materials has to be determined, e.g. inner shear resistance. Inner shear resistance of granular media with and without geogrid reinforcement in different depths is not known yet. Methodology. The author developed a special laboratory method to measure and define inner shear resistance of granular materials, it is called «multi-level shear box test». This method is adequate to determine inner shear resistance (pushing force) vs. depth (distance from the «zero» surface). Two different granular materials: andesite railway ballast (31.5/63 mm) and andesite railway protection layer material (0/56 mm), and seven different types of geogrids (GG1…GG7) were used during the tests. Findings. Values of inner shear resistance functions of andesite railway ballast without geogrid reinforcement and reinforced with different types of geogrids and andesite granular protection layer in function of the vertical distance from the geogrid plane were determined with multi-layer shear box tests when the material aggregation is uncompacted and compacted. Only the compacted sample was tested in case of the 0/56 mm protection layer. Cubic polynomial regression functions fitted on the mean values of the measurements are described graphically. Determination coefficients with values of R²>0.97 were resulted in all the cases of regression functions. Based on the polynomial regression functions fitted on the mean values of the test results, three increasing factors were determined in function of the distance measured from the geogrid. Increasing factor «A», «B» and «D». Originality. Multi-level shear box test, developed by the author, is certified unequivocally adequate for determining inner shear resistance of reinforced and unreinforced granular materials, e.g. railway ballast, protection layer. Practical value. The paper formulated the requirements of using geogrid-reinforced railway ballast and protection layer material to stabilise railway track geometry, e.g. dewatering, draining, separation, minimum ballast depth, and suggested geogrid types from investigated ones.

Author Biography

Sz. Fischer, Széchenyi István University Faculty of Architecture

Dep. «Transport Infrastructure», Civil- and Transport Engineering, Egyetemtér, 1, Győr, Hungary, 9026, tel. + 36 (96) 613 544

References

Fischer Sz., Széchenyi I.E. A vasúti zúzottkő ágyazat alá beépített georácsok vágánygeometriát stabilizáló hatásának vizsgálata (in Hungarian). PhD thesis. Civil Engineering. Győr, 2012. 148 p. doi: 10.13140/RG.2.1.4958.9921.

Horvát F., Major Z. Átmeneti szakasz kialakítása ágyazatragasztással, eltérő függőleges merevségű pályaszakaszok csatlakozásánál (in Hungarian). Sínek Világa, 2013, no. 2, pp. 6-12.

Horvát F., Fischer Sz., Major Z. Evaluation of railway track geometry stabilisation effect of geogrid layers under ballast on the basis of laboratory multi-level shear box tests. Acta Technica Jaurinensis, 2013, no. 2, pp. 21-44.

Horvát F., Fischer Sz., Major Z. Geoműanyagokkal erősített vasúti zúzottkő ágyazat újszerű vizsgálata többszintes nyíróládában (in Hungarian). Sínek Világa, 2012, no. 6, pp. 18-24.

Indraratna B., Shahin M.A., Salim W. Stabilisation of granular media and formation soil using geosynthetics with special reference to railway engineering. Proc. of the Institution of Civil Engineers–Ground Improvement, 2007, vol. 11, issue 1, pp. 27-44. doi: 10.1680/grim.2007.11.1.27.

Kharlan V.I., Kurhan D.M., Bondarenko I.O. The rational train speed choice problem with the help of mathematical modeling of the railway section exploitation process (in Ukrainan). Visnyk Dnipropetrovskoho natsionalnoho universytetu zaliznychnoho transportu imeni akademika V. Lazariana [Bulletin of Dnipropetrovsk National University of Railway Transport named after Academician V. Lazaryan], 2007, issue 18, pp. 71-74.

Kurhan D.M. Determination of dynamic loads from the wheel on the rail for high-speed trains (in Ukrainan). Nauka ta prohres transportu. Visnyk Dnipropetrovskoho natsionalnoho universytetu zaliznychnoho transportu – Science and Transport Progress. Bulletin of Dnipropetrovsk National University of Railway Transport, 2015, no. 3 (57), pp. 118-128. doi: 10.15802/stp2015/46069.

Kurhan M.B., Markova O.S. The time trains losses on sections of speed limits (in Ukrainian). Visnyk Dnipropetrovskoho natsionalnoho universytetu zaliznychnoho transportu imeni akademika V. Lazariana [Bulletin of Dnipropetrovsk National University of Railway Transport named after Academician V. Lazaryan], 2007, issue 18, pp. 54-61.

Nimbalkar S., Neville T., Indraratna B. Performance assessment of reinforced ballasted rail track. Proc. of the Institution of Civil Engineers–Ground Improvement, 2014, vol. 167, issue 1, pp. 24-34. doi: 10.1680/grim.13.00018.

Raymond G.P. Reinforced ballast behaviour subjected to repeated load. Geotextiles and Geomembranes, 2002, vol. 20, issue 1, pp. 39-61. doi: 10.1016/S0266-1144(01)00024-3.

Raymond G., Ismail I. The effect of geogrid reinforcement on unbound aggregates. Geotextiles and Geomembranes, 2003, vol. 21, issue 6, pp. 355-380. doi: 10.1016/S0266-1144(03)00044-X.

Sharpe P., Brough M.J., Dixon J. Geogrid Trials at Coppull Moor on the West Coast Main Line. Proc. of 1st Int. Conf. on Railway Foundations–RailFound06 (11.09-13.09. 2006), Birmingham, University of Birmingham Publ., 2006, pp. 367-375.

Shin E.C., Kim D.H., Das B.M. Geogrid-reinforced railroad bed settlement due to cyclic load. Geotechnical and Geological Engineering, 2002, no. 3, pp. 261-271. doi: 10.1023/A:1016040414725.

Indraratna B., Shahin M., Ruijikiatkamjorn C., Christie D. Stabilisation of ballasted rail tracks and underlying soft formation soils with geosynthetic grids and drains. Proc. of GeoShanghai Int. Conference «Ground Modification and Seismic Mitigation (06.06-08.06.2006)», 2006, pp. 143-152. doi: 10.1061/40864(196)20.

Stahl, M. Interaktion Geogitter-Boden «Numerische Simulation und experimentelle Analyse» (in German). Ph.D. thesis. Civil Engineering. Freiberg, 2011, 166 p.

Szabó J. Tests experiences in small radius curves of continuously welded rail tracks. Periodica Polytechnica: Civil Engineering, 2011, no. 2, pp. 177-189. doi: 10.3311/pp.ci.2011-2.10.