Abstract
This paper reports the outcomes of a series of shaking table tests performed at the EQUALS lab of Bristol University in the framework of the project entitled “ASESGRAM”, carried out within the Transnational Access Activities of the SERIES Project. The experimental test campaign was devoted to the evaluation of the effective behaviour of flat-bottom silos filled with grain under dynamic excitation, and to the experimental verification of the results obtained in previous analytical research work by the authors (Silvestri et al., Bull Earthq Eng 10:1535–1560, 2012). This analytical counterpart starts from the basic assumptions of Eurocode 8 (EN 1998–4, Eurocode 8. Design of structures for earthquake resistance, Part 4: silos, tanks and pipelines, CEN, 2006) excluding the calculation of horizontal shear forces among consecutive grains. This difference leads to a new physically-based evaluation of the effective mass of the grain, which horizontally pushes on the silo walls. The analyses are developed by simulating the earthquake ground motion with time constant vertical and horizontal accelerations and are carried out by means of simple dynamic equilibrium equations that take into consideration the specific mutual actions developed in the ensiled grain. The findings indicate that in case of squat silos (characterized by low, but usual, height/diameter slenderness ratios), the portion of the grain mass that interacts with the silo walls turns out to be noticeably lower than the total mass of the grain in the silo and the effective mass adopted by Eurocode 8 (EN 1998–4, Eurocode 8. Design of structures for earthquake resistance, Part 4: silos, tanks and pipelines, CEN, 2006). Different series of tests have been performed with different heights of the ensiled material to simulate a more or less squat silo. In the tests, the ensiled material consisted of Ballotini Glass. In this paper, the silo specimen and the test instrumentation are described, and the test program and the results are presented. Strong qualitative indications are obtained, which basically confirm that the wall-grain friction coefficient plays an important role in the actions at the base of the silo walls.
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References
CEN (2004) EN 1991-4: Eurocode 1. Basis of design and action on structures. Part 4: actions in silos and tanks. CEN, Brussels
CEN (2006) EN 1998-4: Eurocode 8. Design of structures for earthquake resistance, Part 4: silos, tanks and pipelines. CEN, Brussels
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Acknowledgements
The research leading to these results received founding from the European Community’s Seventh Framework Programme [FP7/2007–2013] for access to the Bristol Laboratory of Civil Engineering (EQUALS) under grant agreement n 227887. The authors thank Prof. Colin Taylor and Dr. Matt Dietz of the Bristol Laboratory of Civil Engineering (EQUALS). Also, the authors acknowledge the University of Alicante for the partial financial support by the grant n ACIE12-04.
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Foti, D. et al. (2015). Analysis of the Dynamic Behaviour of Squat Silos Containing Grain-like Material Subjected to Shaking Table Tests—ASESGRAM Final Report. In: Taucer, F., Apostolska, R. (eds) Experimental Research in Earthquake Engineering. Geotechnical, Geological and Earthquake Engineering, vol 35. Springer, Cham. https://doi.org/10.1007/978-3-319-10136-1_27
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DOI: https://doi.org/10.1007/978-3-319-10136-1_27
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