On the modelling of coupled hydro-mechanical behaviour of interfaces for offshore foundations

Cerfontaine, Benjamin; Collin, Frédéric

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On the modelling of coupled hydro-mechanical behaviour of interfaces for offshore foundations

Cerfontaine, Benjamin; Collin, Frédéric

2017 • In Rasmussen, Amalie (Ed.) Marine Engineering: Emerging Developments and Global Challenges

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Keywords :

Finite element; Interface

Disciplines :

Civil engineering

Author, co-author :

Cerfontaine, Benjamin ; Université de Liège > Département ArGEnCo > Géomécanique et géologie de l'ingénieur

Collin, Frédéric ; Université de Liège > Département ArGEnCo > Géotechnique

Language :

English

Title :

On the modelling of coupled hydro-mechanical behaviour of interfaces for offshore foundations

Publication date :

July 2017

Main work title :

Marine Engineering: Emerging Developments and Global Challenges

Editor :

Rasmussen, Amalie

Publisher :

Nova

Collection name :

Oceanography and Ocean Engineering

Available on ORBi :

since 07 August 2017

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Bibliography

Achmus, M., Akdag, C. T., and Thieken, K. (2013). Load-bearing behavior of suction bucket foundations in sand. Applied Ocean Research, 43: 157-165.
Achmus, M. and Thieken, K. (2010). On the behavior of piles in noncohesive soil under combined horizontal and vertical loading. Acta Geotechnica, 5(3): 199-210.
Alonso, E., Zandarín, M., and Olivella, S. (2013). Joints in unsaturated rocks: Thermo-hydro-mechanical formulation and constitutive behaviour. Journal of Rock Mechanics and Geotechnical Engineering, 5(3): 200-213.
Andersen, K., Jostad, H., and Dyvik, R. (2008). Penetration resistance of offshore skirted foundations and anchors in dense sand. Journal of Geotechnical and Geoenvironmental Engineering, 134(June 2001): 106-116.
Barber, J. and Ciavarella, M. (2000). Contact mechanics. International Journal of Solids and Structures, 37(1): 29-43.
Barenblatt, G. (1959). The formation of equilibrium cracks during brittle fracture. General ideas and hypotheses. Axially-symmetric cracks. Journal of AppliedMathematics and Mechanics, 23(3): 622-636.
Barnichon, J. (1998). Finite element modelling in structural and petroleum geology. PhD thesis, University of Liege, Belgium.
Beer, G. (1985). An isoparametric joint/interface element for finite element analysis. International Journal for Numerical Methods in Engineering, 21: 585-600.
Belgacem, F., Hild, P., and Laborde, P. (1998). The mortar finite element method for contact problems. Mathematical and Computer Modelling, 28(4): 263-271.
Belytschko, T. and Neal, M. (1991). Contact impact by the pinball algorithm with penalty and lagrangian methods. International Journal for Numerical Methods in Engineering, 31: 547-572.
Berkowitz, B., Bear, J., and Braester, C. (1988). Continuum models for contaminant transport in fractured porous formations. Water Resources Research, 24(8): 1225-1236.
Bienen, B., Dührkop, J., Grabe, J., Randolph, M., and White, D. (2012). Response of Piles with Wings to Monotonic and Cyclic Lateral Loading in Sand. Journal of Geotechnical and Geoenvironmental Engineering, 138(3): 364-375.
Borja, R. (2013). Plasticity: Modeling & Computation.
Boussinesq, J. (1868). Mémoire sur l'influence des frottements dans les mouvements réguliers des fluides. [Memorandum on the influence of friction in regular movements of fluids]. Journal de Mathématiques Pures et Appliquées.
Bransby, M. F.and Yun, G.-J. (2009). The undrained capacity of skirted strip foundations under combined loading. Géotechnique, 59(2): 115-125.
Byrne, B. and Houlsby,G. (2002). Experimental investigationsof response of suction caissons to transient vertical loading. Journal of the Geotechnical and Geoenvironmental Engineering, 128(11): 926-939.
Byrne, B. W. and Houlsby, G. T. (2003). Foundations for offshore wind turbines. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 361(1813): 2909-2930.
Cerfontaine, B., Collin, F., and Charlier, R. (2016). Numerical modelling of transient cyclic vertical loading of suction caissons in sand. Geotechnique, 66(2): 1-16.
Cerfontaine, B., Dieudonné, A., Radu, J., Collin, F., and Charlier, R. (2015). 3D zero-thickness coupled interface finite element: Formulation and application. Computers and Geotechnics, 69: 124-140.
Charlier, R. and Cescotto, S. (1988). Modélisation du phénomène de contact unilatéral avec frottement dans un contexte de grandes déformations. [Modeling the phenomenon of unilateral contact with friction in a context of large deformations.] Journal de Mécanique Théorique et Appliquée, 7(Suppl. 1).
Coulomb, C. (1821). Théorie des machines simples.[Theory of simple machines]. Bachelier.
Cox, J., O'Loughlin, C., Cassidy, M., Bhattacharya, S., Gaudin, C., and Diping, B. (2014). Centrifuge study on the cyclic performance of caissons in sand. International Journal of PhysicalModelling in Geotechnics, 14(4): 99-115.
Cuéllar, P., Mira, P., Pastor, M., Fernández Merodo, J., Baeßler, M., and Rücker, W. (2014). A numerical model for the transient analysis of offshore foundations under cyclic loading. Computers and Geotechnics, 59: 75-86.
Curnier, A. (1984). A theory of friction. International Journal of Solids and Structures, 20(7): 637-647.
Day, R. and Potts, D. (1994). Zero thickness interface elements - numerical stability and application. International Journal for Numerical and Analytical Methods in Geomechanics, 18: 689-708.
DeJong, J., White, D., and Randoph, M. (2006). Microscale observation and modeling of soil structure interface behavior using particle image velocimetry. Soils and Foundations, 46(1): 15-28.
Desai, C., Drumm, E. C., and Zaman, M. (1985). Cyclic Testing and Modelling of Interfaces. Journal of Geotechnical Engineering - ASCE, I(6):793-815.
Desai, C., Zaman, M., Lightner, J., and Siriwardane, H. (1984). Thin-layer element for interfaces and joints. International Journal for Numerical and Analytical Methods in Geomechanics, 8(1): 19-43.
Dieudonne, A., Cerfontaine, B., Collin, F., and Charlier, R. (2015). Hydromechanical modelling of shaft sealing for co2 storage. Engineering Geology.
Dowson, D. (1998). History of tribology. Longman London, second edition.
Dugdale, D. S. (1960). Yielding of steel sheets containing slits. J. Mech. Phys. Solids, 8: 100-104.
Euler, L. (1750). Sur le frottement des corps solides. [On the friction of solid bodies.] Memoires de l'academie des sciences de Berlin.
Fischer, K. and Wriggers, P. (2006). Mortar based frictional contact formulation for higher order interpolations using the moving friction cone. Computer methods in applied mechanics and engineering, 195(37): 5020-5036.
Gao, Y., Qiu, Y., Li, B., Li, D., Sha, C., and Zheng, X. (2013). Experimental studies on the anti-uplift behavior of the suction caissons in sand. Applied Ocean Research, 43: 37-45.
Gens, A., Carol, I., and Alonso, E. (1988). An interface element formulation for the analysis of soil reinforcement interaction. Computers and Geotechnics, 7: 133-151.
Gens, A., Carol, I., and Alonso, E. (1990). A constitutive model for rock joints formulation and numerical implementations. Computers and Geotechnics, 9: 3-20.
Goodman, L., Lee, C., and Walker, F. (1961). The feasibility of vacuum anchorage in soil. Géotechnique, 11(4): 356-359.
Goodman, R., Taylor, R., and Brekke, T. (1968). A model for the mechanics of jointed rock. Journal of the Soil Mechanics and Foundations Division, 94.
Gourvenec, S. (2008). Effect of embedment on the undrained capacity of shallowfoundations under general loading. Géotechnique, 58(3): 177-185.
Gourvenec, S., Acosta-Martinez, H., and Randolph, M. (2009). Experimental study of uplift resistance of shallow skirted foundations in clay under transient and sustained concentric loading. Géotechnique, 59(6): 525-537.
Guiducci, C., Pellegrino, A., Radu, J.-P., Collin, F., and Charlier, R. (2002). Numerical modeling of hydro-mechanical fracture behavior. In Numerical models in Geomechanics, pages 293-299.
Habraken, A., Cescotto, S., and Banning, Q. (1998). Contact between deformable solids: The fully coupled approach. Mathematical and Computer modelling, 28(4): 153-169.
Hallquist, J., Goudreau, G., and Benson, D. (1985). Sliding interfaces with contact-impact in large-scale lagrangian computations. Computer Methods in Applied Mechanics and Engineering, 51(1): 107-137.
Hartmann, S., Oliver, J.,Weyler, R., Cante, J., and Hernández, J. (2009). A contact domain method for large deformation frictional contact problems. part 2: numerical aspects. Computer Methods in Applied Mechanics and Engineering, 198(33): 2607-2631.
Hertz, H. (1881). Ueber die Ber ührung fester elastischer Körper. [On the touch of firm elastic bodies.] Journal f ür die reine und angewandte Mathematik, 92: 156-171.
Ho, T., Jardine, R., and Anh-Minh, N. (2011). Large-displacement interface shear between steel and granular media. Géotechnique, 61(3): 221-234.
[Houlsby, 2016] Houlsby, G. (2016). Interactions in offshore foundation design. Géotechnique.
[Houlsby and Byrne, 2005] Houlsby, G. and Byrne, B. (2005). Design procedures for installation of suction caissons in sand. In Proceedings of ICE, Geotechnical Engineering, number July, pages 135-144.
Houlsby, G., Ibsen, L., and Byrne, B. (2005a). Suction Caissons for Wind Turbines. International Symposium on Frontiers in Offshore Geotechnics, (September):75-93.
Houlsby, G., Kelly, R., and Byrne, B. (2005b). The tensile capacity of suction caissons in sand under rapid loading. In Frontiers in offshore geotechnics, number 1, pages 405-410.
Houlsby, G., Kelly, R., Huxtable, J., and Byrne, B. (2006). Field trials of suction caissons in sand for offshore wind turbine foundations. Géotechnique, 56(1): 3-10.
Hu, L. and Pu, J. (2004). Testing andModeling of Soil-Structure Interface. Journal of Geotechnical and Geoenvironmental Engineering, 130(8): 851-860.
Ibsen, L. B., Larsen, K. a., and Barari, a. (2014). Calibration of Failure Criteria for Bucket Foundations on Drained Sand under General Loading. Journal of Geotechnical and Geoenvironmental Engineering, 140(7).
Iskander, M., El-Gharbawy, S., and Olson, R. (2002). Performance of suction caissons in sand and clay. Canadian Geotechnical Journal, 39(3): 576-584.
Jha, B. and Juanes, R. (2014). Coupled multiphase flow and poromechanics: A computational model of pore pressure effects on fault slip and earthquake triggering. Water Resources Research, 50: 3376-3808.
Johnson, K. (1992). Contact mechanics. New-York: Cambridge University Press.
Kelly, R., Houlsby, G., and Byrne, B. (2006a). A comparison of field and laboratory tests of caisson foundations in sand and clay. Géotechnique 56(9): 617-626.
Kelly, R. B., Houlsby, G. T., and Byrne, B. W. (2006b). Transient vertical loading of model suction caissons in a pressure chamber. Géotechnique 56(10): 665-675.
Klarbring, A. and Björkman, G. (1988). A mathematical programming approach to contact problems with friction and varying contact surface. Computers & Structures, 30(5): 1185-1198.
Kourkoulis, R., Lekkakus, P., Gelagoti, F., and Kaynia, A. (2014). Suction caisson foundations for offshore wind turbines subjected to wave and earthquake loading: effect of soil-foundation interface. Géotechnique, 64(3): 171-185.
Lehane, B., Elkhatib, S., and Terzaghi, S. (2014). Extraction of suction caissons in sand. Géotechnique, 64(9): 735-739.
Lewis, R. and Schrefler, B. (1998). The finite element method in the static and dynamic deformation and consolidation of porous media. JohnWiley.
Li, C., Bars, P., and Laloui, L. (2014). Coupled approach to assess caprock deformation caused by co2 injection. In Geotechnical Special Publication, pages 651-657.
Li, D., Zhang, Y., Feng, L., and Gao, Y. (2015). Capacity of modified suction caissons in marine sand under static horizontal loading. Ocean Engineering, 102: 1-16.
Liu, H. and Ling, H. (2008). Constitutive description of interface behavior including cyclic loading and particle breakage within the framework of critical state soil mechanics. International Journal for Numerical and Analytical Methods in Geomechanics, 32(January): 189-213.
Liu, H., Song, E., and Ling, H. (2006). Constitutive modeling of soilstructure interface through the concept of critical state soil mechanics. Mechanics Research Communications, 33: 515-531.
McClelland, B. et al. (1956). Soil modulus for laterally loaded piles. Journal of the Soil Mechanics and Foundations division, 82(4): 1-22.
Mi, Y., Crisfield, M., Davies, G., and Hellweg, H. (1998). Progressive delamination using interface elements. Journal of composite materials, 32(14): 1246-1272.
Mortara, G., Boulon, M., and Ghionna, V. (2002). A 2-d constitutive model for cyclic interface behaviour. International journal for numerical and analytical methods in geomechanics, 26(11): 1071-1096.
Newton, I. (1686). Philosophiae naturalis principia mathematica.
Ng, K. and Small, J. (1997). Behavior of joints and interfaces subjected to water pressure. Computers and Geotechnics, 20(1): 71-93.
Oliver, J., Hartmann, S., Cante, J.,Weyler, R., and Hernández, J. (2009). A contact domain method for large deformation frictional contact problems. part 1: theoretical basis. Computer Methods in Applied Mechanics and Engineering, 198(33): 2591-2606.
Olsson, R. and Barton, N. (2001). An improved model for hydromechanical coupling during shearing of rock joints. International Journal of Rock Mechanics and Mining Sciences, 38(3): 317-329.
Oron, A. and Berkowitz, B. (1998). Flowin rock fractures: The local cubic law assumption reexamined. Water Resources Research, 34(11): 2811-2825.
Pande, G. and Sharma, K. (1979). On joint/interface elements and associated problems of numerical ill-conditioning. International Journal for Numerical and AnalyticalMethods in Geomechanics, 3(3): 293-300.
Puso, M. and Laursen, T. (2004). A mortar segment-to-segment contact method for large deformation solid mechanics. Computer Methods in Applied Mechanics and Engineering, 193(6): 601-629.
Reese, L. and Van Impe, W. (2010). Single piles and pile groups under lateral loading. CRC Press, second edition.
Rojek, J. and Telega, J. (2001). Contact problems with friction, adhesion and wear in orthopaedic biomechanics. Part 1 - general developments. Journal of the theoretical and applied mechanics, 39(2001).
Rutqvist, J., Birkholzer, J., and Tsang, C.-F. (2008). Coupled reservoir- geomechanical analysis of the potential for tensile and shear failure associated with co2 injection in multilayered reservoir-caprock systems. International Journal of Rock Mechanics andMining Sciences, 45(2): 132-143.
Segall, P. (1989). Earthquakes triggered by fluid extraction. Geology, 17(10): 942-946.
Segura, J. and Carol, I. (2004). On zero-thickness interface elements for diffusion problems. International journal for numerical and analytical methods in geomechanics, 28(9): 947-962.
Segura, J. and Carol, I. (2008a). Coupled hmanalysis using zero-thickness interface elements with double nodes. part i: Theoretical model. International Journal for Numerical and Analytical Methods in Geomechanics 32(18): 2083-2101.
Segura, J. and Carol, I. (2008b). Coupled hmanalysis using zero-thickness interface elements with double nodes. part ii: Verification and application. International Journal for Numerical and Analytical Methods in Geomechanics 32(18): 2103-2123.
Senders, M. (2008). Suction caissons in sand as tripod foundations for offshore wind turbines. PhD thesis, University of western Australia.
Senders, M. and Randolph, M. (2009). CPT-Based method for the installation of suction caissons in sand. Journal of Geotechnical and Geoenvironmental Engineering, 135(January): 14-25.
Senpere, D. and Auvergne, G. (1982). Suction anchor piles-a proven alternative to driving or drilling. In Offshore Technology Conference, page 483. Offshore Technology Conference.
Shahrour, I. and Rezaie, F. (1997). An elastoplastic constitutive relation for the soil-structure interface under cyclic loading. Computers and Geotechnics, 21(1): 21-39.
Sharma, K. and Desai, C. (1993). Analysis and implementation of thinlayer element for interfaces and joints. Journal of EngineeringMechanics, 118(12): 2442-2462.
Sheng, D., Wriggers, P., and Sloan, S. (2006). Improved numerical algorithms for frictional contact in pile penetration analysis. Computers and Geotechnics, 33(6-7): 341-354.
Stutz, H. and Masin, D. (2016). Hypoplastic Interface models for finegrained soils. International Journal for Numerical and AnalyticalMethods in Geomechanics, 32.
Terzaghi, K. (1925). Erdbaumechanik auf BodenphysikalischerGrundlage [Soil Mechanics based on Soil Physics].
Thieken, K., Achmus, M., and Schröder, C. (2014). On the behavior of suction buckets in sand under tensile loads. Computers and Geotechnics, 60: 88-100.
Tjelta, T., Aas, P., Hermstad, J., and Andenaes, E. (1990). The skirt piled gullfaks c platform installation. In Offshore Technology Conference.
Tran, M. (2005). Installation of Suction Caissons in Dense Sand and the Influence of Silt and Cemented Layers. PhD thesis, The university of Sydney.
Tsang, Y. and Witherspoon, P. (1981). Hydromechanical behavior of a deformable rock fracture subject to normal stress. Journal of Geophysical Research: Solid Earth, 86(B10):9287-9298.
Wang, S. and Nakamachi, E. (1997). The inside-outside contact search algorithm for finite element analysis. International Journal for Numerical Methods in Engineering, 40(December): 5-16.
Wang, X. and Wang, L. (2006). Continuous interface elements subject to large shear deformations. International Journal of Geomechanics, 6(April): 97-107.
Weißenfels, C. and Wriggers, P. (2015). A contact layer element for large deformations. ComputationalMechanics, 55(5): 873-885.
White, D. and Lehane, B. (2004). Friction fatigue on displacement piles in sand. Géotechnique, 54(10): 645-658.
Witherspoon, P., Wang, J., Iwai, K., and Gale, J. (1980). Validity of cubic law for fluid flow in a deformable rock fracture. Water Resources Research, 16(6): 1016-1024.
Wriggers, P. (2006). Computational contact mechanics. Wiley: Chichester, second edition.
Wriggers, P., Krstulovic-Opara, L., and Korelc, J. (2001). Smooth c1- interpolations for two-dimensional frictional contact problems. International Journal for NumericalMethods in Engineering, 51(12): 1469-1495.
Wriggers, P., Schröder, J., and Schwarz, A. (2013). A finite element method for contact using a third medium. Computational Mechanics, 52(4): 837-847.
Wriggers, P. and Zavarise, G. (2004). Encyclopedia of Computational Mechanics, volume 2: Solids and Structures, chapter 6: Computational Contact Mechanics.
Xu, X. P. and Needleman, A. (1994). Numerical simulation of fast crack growth in brittle solids. Journal of the mechanics and physics of solids, 42(9): 1397-1434.
Zandarin, M., Alonso, E., and Olivella, S. (2013). A constitutive law for rock joints considering the effects of suction and roughness on strength parameters. International Journal of Rock Mechanics and Mining Sciences, 60: 333-344.
Zhong, Z. and Mackerle, J. (1992). Static Contact Problems - A review. Engineering computations, 9: 3-37.
Zhu, B., Byrne, B., and Houlsby, G. (2013). Long-Term Lateral Cyclic Response of Suction Caisson Foundations in Sand. Journal of Geotechnical and Geoenvironmental Engineering, 139(January): 73-83.
Zienkiewicz, O. C. and Taylor, R. L. (2000). Finite Element Method: Volume 1, Fifth Edition. Butterworth-Heinemann.
Zoback, M. and Gorelick, S. (2012). Earthquake triggering and largescale geologic storage of carbon dioxide. Proceedings of the National Academy of Sciences.