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Geotechnical and Geological Engineering

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27.03.2017 | Original paper

Critical Review of the Hypervib1 Model to Assess Pile Vibro-Drivability

verfasst von: Alain Holeyman, Valerie Whenham

Erschienen in: Geotechnical and Geological Engineering | Ausgabe 5/2017

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Abstract

The vibratory driving technique is used for driving piles, sheet piles, tubes and rods into the ground by imparting to the element a longitudinal periodic motion. The small amplitude vibrations induced by the equipment reduce the ground resistance which allows penetration under the action of a relatively small axial force. The technique offers an alternative to impact driving due to lower installation costs and reduced environmental disturbance (noise, vibration, etc.) especially in sensitive environments, such as industrial and urban sites or offshore wind farm sites. The vibratory technique is also preferred when the maximum stress levels imparted to the driven element are of concern. Despite the advantages of the vibratory driving technique, its application remains however mainly driven by pragmatic aspects. Within that context, the access to experience databases and full-scale field test results is of valuable interest. The aim of this paper is to review the Hypervib1 model developed by (Holeyman 1993) for assessing the vibratory drivability of piles and sheet piles, based on the analysis of such experimental results. New findings and developments brought to the model are discussed. Conclusions in terms of reliability of the method are finally drawn.

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Arnould P, Canou J, Gonin H, Guillaume D, Keller P, Legendre Y et al. (2005) Rocher-Lacoste F, Sieffert J-G, Vié D (2005) Guide Technique du Vibrofonçage 2005. Projet National Vibrofonçage 2000–2005

Azzouzi S (2003) Intrillen van stalen damwanden in niet-cohesieve gronden. GeoDelft NL &. Technische Universiteit Delft, Delft, p 2003

Barkan D (1963) Méthodes de vibration dans la construction. Dunod, Paris, p 302p

BBRI (1994) HIgh PERformance VIBratory pile drivers based on novel electromagnetic actuation systems and improved understanding of soil dynamics. Progress reports of the BRITE/EURAM research contract CT91-0561. Luxembourg, Office for official publications of the European Communities, 1994

Chow Y, Smith I (1984) A numerical model for the analysis of pile driveability. In: 2nd International conference on the application of stress wave theory on piles, Balkema, Rotterdam

Cudmani R, Sturm H (2006) An investigation of the tip resistance in granular and soft soils during static, alternating and dynamic penetration. In: International conference on vibratory pile driving and deep soil compaction, Paris, France

Dierssen G (1994) Ein bodenmechanisches Modell zur Beschreibung des Vibrations-rammens in körningen Böden., Doctoral Thesis, University of Karlsruhe, Germany

Fischer J, Sychla H, Bakker J, de Neef L, Stahlmann J (2013) A comparison between impact driven and vibratory driven steel piles in the German North Sea. In: Conference on Maritime Energy COME 2013, May 21–22, 2013, Hamburg, Germany

Gonin H (2006) Forces, deformations et vitesses particulaires en battage et en vibrofonçage. In: Proceedings of the international conference on vibratory pile driving and deep soil compaction, September 21–22, 2006. Paris, France

Grabe J, König F, Mahutka K-P (2006) Numerical modelling of pile jacking, driving and vibratory driving. Numerical Modelling of Construction Processes, Bochum, pp 235–246

Hemmen B, Bles T (2005) GeoBrain Funderingstechniek: Ervaringsdatabase voorspelt uitvoeringsrisico. Civiele Techniek 2:24–25

Holeyman A (1993) HIPERVIB1, An analytical model-based computer program to evaluate the penetration speed of vibratory driven sheet piles. Research report prepared for BBRI, June 1993

Holeyman A, Legrand C (1996) A method to predict the drivability of vibratory driven piles. Stress Wave’96, Orlando, September 1999, pp 1101–1112

Holeyman A, Whenham V (2008) Sheet pile vibro-driving: power pack-vibrator-sheet pile-soil interactions. In: Conference on the application of stress-wave theory to piles, Lisbon

Holeyman A, Vanden Berghe J-F, De Cock S (1999) Toe resistance during pile vibratory penetration. Geotech Eng For Transportation Infrastructure. Barends et al. (eds), Rotterdam

Jardine R, Chow F, Overy R, Standing J (2005) ICP design methods for driven piles in sands and clays. Thomas Telford, LondonCrossRef

Jonker G (1987) Vibratory pile driving hammers for oil installation and soil improvement projects. In: Proceedings of nineteenth annual offshore technology conference, Dallas, Texas, OTC 5422, pp. 549–560

Le Thiet T (2005) Etude du processus de vibrofonçage d’inclusions cylindriques en chambre d’étalonnage. Application aux pieux. Thèse de doctorat présentée à l’Ecole Nationale des Ponts et Chaussées

LeBlanc Thilsted C, Kallehave D, Skov Gretlund J (2013) Vibro-driving of monopiles—experience from Anholt offshore wind farm. In: Proceedings EWEA Offshore

Legrand C, Van Rompaey D, Menten J (1993) A comparison of different sheet-pile installation methods. Internal research report of BBRI

Mahutka K-P, Grabe J (2006) Numerical prediction of settlements and vibrations due to vibratory pile driving using a continuum model. In: International conference on vibratory pile driving and deep soil compaction, Paris, France, pp 243–252

Mens A, van Tol F, Koelewijn A (2008) Optimizing foundation engineering, validating models against experience using artificial intelligence. In: The 12th international conference of international association for computer methods and advances in geomechanics (IACMAG). Goa, India

Mens A, Korf M, van Tol F (2012) Validating and improving models for vibratory installation of steel sheet piles with field observations. Geotech Geol Eng 30:1085–1095CrossRef

Middendorp P, van Dorp R (2012) Van Mini- tot Giga- palen. Geotechniek, Funderingsdag 2012 Special, pp. 30–33

O’Neill M, Vipulanandan C, Wong D (1990) Laboratory modeling of vibro-driven piles. J Geotech Eng 116(8):1190–1209CrossRef

Rausche F, Beim J (2012) Analyzing and interpreting dynamic measurements taken during vibratory pile driving

Sieffert J-G (2004) Essais de Merville—Interprétation et Modélisation. Projet National «Vibrofonçage», Ministère de l’équipement, des transports et du logement

Sieffert J-G (2006) Analyse et prévision de la pénétrabilité à l’aide du logiciel Braxuus. In: International conference on vibratory pile driving and deep soil compaction, September 21–22. Paris, France

Smith I, To P (1988) Numerical studies of vibratory pile driving. Int J Numer Anal Methods Geomech 12:513–531CrossRef

Tara D, Middendorp P, Verbeek G (2014) Modeling and observations of pile installation using vibro hammers in Fraser River Delta Soils. In: 22nd Vancouver geotechnical society symposium, Foreshore Engineering, June 23, 2014

van Baars S (2004) Design of sheet pile installation by vibration. Geotech Geol Eng 22(3):391–400CrossRef

Vanden Berghe J-F (2001) Sand strength degradation within the framework of pile vibratory driving. Doctoral thesis, Université Catholique de Louvain, Belgium 2001

Viking K (2002) Vibratory driveability—a field study of vibratory driven sheet piles in non-cohesive soils. Stokholm, Sweden: Ph.D. thesis

Whenham V, Holeyman A (2012) Load transfers during vibratory driving. Geotech Geol Eng 30(5):1119–1135CrossRef

Whenham V, Huybrechts N, Legrand C, Bourdouxhe M-P, Schmitt A (2006) Energy consumption during sheet piles vibro-driving: experimental results. In: International conference on vibratory pile driving and deep soil compaction, September 21–22. Paris, France

Whenham V, Areias L, Rocher-Lacoste F, Vie D, Bourdouxhe M-P, Holeyman A (2009) Full scale sheet pile vibro-driving. In: Proceedings of the 17th international conference on soil mechanics & geotechnical engineering alexandria, Egypt 5–9 October 2009

Titel: Critical Review of the Hypervib1 Model to Assess Pile Vibro-Drivability
verfasst von: Alain Holeyman
Valerie Whenham
Publikationsdatum: 27.03.2017
Verlag: Springer International Publishing
Erschienen in: Geotechnical and Geological Engineering / Ausgabe 5/2017
Print ISSN: 0960-3182
Elektronische ISSN: 1573-1529
DOI: https://doi.org/10.1007/s10706-017-0218-8

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