Authors: Dana Madalina Pohrib, Elena Irina Ciobanu

Abstract:

In compaction works, the most often used codes and standards are those for road embankments and refer to a maximum filling height of 3.00m. When filling a height greater than 3.00m, such codes are no longer valid and thus their application may lead to technical difficulties in the process of compaction and to the achievement of a sufficient degree of compaction. For this reason, in the case of controlled fillings with heights greater than 3.00m it is necessary to formulate and apply a number of special techniques, which can be determined by performing a full scale test. This paper presents the results of the studies and full scale tests conducted for the stabilization of a ravine with vertical banks and a depth of about 12.00m. The fillings will support a heavy traffic road connecting the two parts of a village in Vaslui County, Romania. After analyzing two comparative intervention solutions, the variant of a controlled filling bordered by a monolith concrete retaining wall was chosen. The results obtained by the authors highlighted the need to insert a geogrid reinforcement at every 2.00m for creating a 12.00m thick compacted fill.

Keywords: Compaction, dynamic probing, stability, soil stratification.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1337223

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References:

[1] AND nr. 530, "Instructiuni privind controlul calitatii terasamentelor rutiere (romanian design standard)”, Compania Nationala de Autostrazi si Drumuri Nationale din Romania, pp. 30-39
[2] C159-1989, „Instrucțiuni tehnice pentru cercetarea terenului de fundare prin metoda penetrării cu con, penetrare statică, penetrare dinamică, vibropenetrare (romanian design standard)”, Ministerul Constructiilor Industriale, 1989
[3] C176-1984, "Instrucțiuni tehnice pentru cercetarea terenului de fundare prin penetrare dinamică cu con (romanian design standard)” Ministerul Constructiilor Industriale, 1984
[4] GE 026/1997, „Ghid pentru execuția compactarii in plan orizontal si inclinat a terasamentelor (romanian design standard)”, Ministerul Lucrarilor Publice si Amenajarii Teritoriului, 1997
[5] GP 093/2006, „Ghid privind proiectarea structurilor de pamant armate cu materiale geosintetice si metalice (romanian design standard)”, Ministerul Transporturilor, Constructiilor si Turismului, 2006
[6] Jean-Louis Briaud, "Compaction innovations and control based on soil modulus”, 2010, student presentation
[7] NP 075/2002, „Normativ pentru utilizarea materialelor geosintetice la lucrarile de constructii (romanian design standard)”, Ministerul Lucrarilor Publice, Transporturilor si Locuintei, 2002
[8] Stanciu, A.,Lungu, I. „Fundatii • Fizica si mecanica pamanturilor”, Editura Tehnica, Bucuresti, 2006, pp. 1134-1140
[9] SR EN 1997/1, „Proiectarea geotehnica. Partea 1: Reguli generale(romanian design standard)”, ASRO, 2006
[10] SR EN 1997/2, „Proiectarea geotehnica. Partea 2: Investigarea si incercarea terenului (romanian design standard)”, ASRO, 2008
[11] SR EN ISO 22476 –2 , „Cercetari si incercari geotehnice. Incercari pe teren. Partea 2 : Incercarea de penetrare dinamica (romanian design standard)”, ASRO, 2006
[12] STAS 1913/13-1983, „Determinarea caracteristicilor de compactare. Incercarea Proctor (romanian design standard)”, 1983
[13] S.S. Gue&S.S. Liew, "Fill compaction and its consequences of non-compliance”, Conference Technology CONTEC-2001, Kota Kinabalu, Sabah, 11-13 Octomber 2001