BEM and FEM results of displacements in a poroelastic column

Bettina Albers; Stavros A. Savidis; H. Ercan Taşan; Otto von Estorff; Malte Gehlken

Bettina Albers ; Stavros A. Savidis ; H. Ercan Taşan ; Otto von Estorff ; Malte Gehlken

International Journal of Applied Mathematics and Computer Science, Tome 22 (2012), p. 883-896 / Harvested from The Polish Digital Mathematics Library

Access to full text
Full (PDF)

Résumé

The dynamical investigation of two-component poroelastic media is important for practical applications. Analytic solution methods are often not available since they are too complicated for the complex governing sets of equations. For this reason, often some existing numerical methods are used. In this work results obtained with the finite element method are opposed to those obtained by Schanz using the boundary element method. Not only the influence of the number of elements and time steps on the simple example of a poroelastic column but also the impact of different values of the permeability coefficient is investigated.

Publié le : 2012-01-01

Zbl 1292.76046

EUDML-ID : urn:eudml:doc:244535

@article{bwmeta1.element.bwnjournal-article-amcv22z4p883bwm,
     author = {Bettina Albers and Stavros A. Savidis and H. Ercan Ta\c san and Otto von Estorff and Malte Gehlken},
     title = {BEM and FEM results of displacements in a poroelastic column},
     journal = {International Journal of Applied Mathematics and Computer Science},
     volume = {22},
     year = {2012},
     pages = {883-896},
     zbl = {1292.76046},
     language = {en},
     url = {http://dml.mathdoc.fr/item/bwmeta1.element.bwnjournal-article-amcv22z4p883bwm}
}

Bettina Albers; Stavros A. Savidis; H. Ercan Taşan; Otto von Estorff; Malte Gehlken. BEM and FEM results of displacements in a poroelastic column. International Journal of Applied Mathematics and Computer Science, Tome 22 (2012) pp. 883-896. http://gdmltest.u-ga.fr/item/bwmeta1.element.bwnjournal-article-amcv22z4p883bwm/

Bibliographie

[000] Albers, B. (2010). Modeling and Numerical Analysis of Wave Propagation in Saturated and Partially Saturated Porous Media, Postdoctoral thesis, Veröffentlichungen des Grundbauinstitutes der Technischen Universität Berlin, Vol. 48, Shaker, Aachen. | Zbl 1284.76334

[001] Allard, J.F. (1993). Propagation of Sound in Porous Media. Modelling Sound Absorbing Materials, Elsevier, Essex.

[002] Atalla, N., Hamdi, A.M. and Panneton, R. (2001). Enhanced weak integral formulation for mixed (u,p) poroelastic equations, Journal of the Acoustical Society of America 109(6): 3065-3068.

[003] Atalla, N., Panneton, R. and Debergue, P. (1998). A mixed pressure-displacement formulation for poroelastic materials, Journal of the Acoustical Society of America 104(3): 1444-1452.

[004] Biot, M.A. (1941). General theory of three dimensional consolidation, Journal of Applied Physics 12(2): 155-164. | Zbl 67.0837.01

[005] Biot, M.A. (1956). Theory of propagation of elastic waves in a fluid saturated porous solid, I: Low frequency range, II: Higher frequency range, Journal of the Acoustical Society of America 28(2): 168-191.

[006] Bonnet, G. (1987). Basic singular solutions for a poroelastic medium in the dynamic range, Journal of the Acoustical Society of America 82(5): 1758-1762.

[007] Cheng, A.H.-D., Badmus, T. and Beskos, D.E. (1991). Integral equations for dynamic poroelasticity in frequency domain with BEM solution, Journal of Engineering Mechanics (ASCE) 117(5): 1136-1157.

[008] de Boer, R. and Ehlers, W. (1986). Theorie der Mehrkomponentenkontinua mit Anwendung auf bodenmechanische Probleme, Teil I, Technical Report 40, Forschungsberichte aus dem Fachbereich Bauwesen der Universität-GH Essen, Essen.

[009] Dominguez, J. (1992). Boundary element approach for dynamic poroelastic problems, International Journal for Numerical Methods in Engineering 35(2): 307-324. | Zbl 0768.73084

[010] Eringen, A.C. and Suhubi, S.S. (1975). Elastodynamics, Vol. II, Academic Press, New York, NY. | Zbl 0344.73036

[011] Fischer, M. (2004). The Fast Multipole Boundary Element Method and its Application to Structure-Acoustic Field Interaction, Ph.D. thesis, Universität Stuttgart, Stuttgart.

[012] Goodman, M.A. and Cowin, S.C. (1972). A continuum theory of granular materials, Archive for Rational Mechanics and Analysis 44(4): 249-266. | Zbl 0243.76005

[013] Göransson, P. (1995). A weighted residual formulation of the acoustic wave propagation through a flexible porous material and comparison with a limp material model, Journal of Sound and Vibration 182(3): 479-494.

[014] Hild, P. (2011). A sign preserving mixed finite element approximation for contact problems, International Journal of Applied Mathematics and Computer Science 21(3): 487-498, DOI: 10.2478/v10006-011-0037-7. | Zbl 05999228

[015] Holler, S. (2006). Dynamisches Mehrphasenmodell mit hypoplastischer Materialformulierung der Feststoffphase, Ph.D. thesis, RWTH Aachen, Aachen.

[016] Kelder, O. and Smeulders, D.M.J. (1997). Observation of the Biot slow wave in water-saturated Nivelsteiner sandstone, Geophysics 62(6): 1794-1796.

[017] Kogut, J. and Ciurej, H. (2010). A vehicle-track-soil dynamic interaction problem in sequential and parallel formulation, International Journal of Applied Mathematics and Computer Science 20(2): 295-303, DOI: 10.2478/v10006-010-0022-6. | Zbl 1196.93019

[018] Korsawe, J. and Starke, G. (2005). A least-squares mixed finite element method for Biot's consolidation problem in porous media, SIAM Journal on Numerical Analysis 43(1): 318-339. | Zbl 1086.76041

[019] Korsawe, J., Starke, G., Wang, W. and Kolditz, O. (2006). Finite element analysis of poro-elastic consolidation in porous media: Standard and mixed approaches, Computer Methods in Applied Mechanics and Engineering 195(9-12): 1096-1115. | Zbl 1177.76199

[020] Lewis, R.W. and Schrefler, B.A. (1998). The Finite Element Method in the Static and Dynamic Deformation and Consolidation of Porous Media, Wiley, Chichester. | Zbl 0935.74004

[021] Naumann, K. (2004). Implementierung eines Finiten Elementes in das FEM-Programmsystem ANSYS zur gekoppelten Fluid-Struktur Berechnung poröser Medien, Master's thesis, TU Berlin, Berlin.

[022] Panneton, R. and Atalla, N. (1997). An efficient finite element scheme for solving the threedimensional poroelasticity problem in acoustics, Journal of the Acoustical Society of America 101(6): 3287-3298.

[023] Plona, T. J. (1980). Observation of a second bulk compressional wave in a porous medium at ultrasonic frequencies, Applied Physics Letters 36(4): 259-261.

[024] Rackwitz, F., Naumann, K. and Savidis, S.A. (2005). Implementierung eines Finiten Elements zur Konsolidationsberechnung mit ANSYS, 23rd CADFEM Users' Meeting 2005, Bonn, Germany, (on CD-ROM/DVD).

[025] Savidis, S.A., Albers, B., Taşan, H.E. and Savvidis, G. (2011). Finite-Elemente-Berechnungen quasistatischer und dynamischer Probleme mit einem poroelastischen Zweikomponentenmodell, Bauingenieur 5: 241-249.

[026] Savvidis, G. (2009). Implementierung eines Finiten Elements in das FEM-Programmsystem ANSYS zur gekoppelten Fluid-Struktur Berechnung von wassergesättigten Böden, Master's thesis, TU Berlin, Berlin.

[027] Schanz, M. (2001). Application of 3d time domain boundary element formulation to wave propagation in poroelastic solids, Engineering Analysis with Boundary Elements 25(4-5): 363-376. | Zbl 1015.74074

[028] Schanz, M. and Cheng, A.H.-D. (2000). Transient wave propagation in a one-dimensional poroelastic column, Acta Mechanica 145(1-4): 1-18. | Zbl 0987.74039

[029] Schrefler, B.A. and Scotta, R. (2001). A fully coupled dynamic model for two-phase fluid flow in deformable porous media, Computer Methods in Applied Mechanics and Engineering 190(24-25): 3223-3246. | Zbl 0977.74019

[030] Taşan, H.E. (2012). Zur Dimensionierung der MonopileGründungen von Offshore-Windenergieanlagen, Ph.D. thesis, Veröffentlichungen des Grundbauinstitutes der Technischen Universität Berlin, Vol. 52, Aachen.

[031] Taşan, H.E., Rackwitz, F. and Savidis, S.A. (2010). Behaviour of cyclic laterally loaded diameter monopiles in saturated sand, Proceedings of the 7th European Conference of Numerical Methods in Geotechnical Engineering, Trondheim, Norway, pp. 889-894.

[032] von Estorff, O. and Hagen, C. (2006). Iterative coupling of FEM and BEM in 3D transient elastodynamics, Engineering Analysis with Boundary Elements 30(7): 611-622. | Zbl 1195.74202

[033] von Terzaghi, K. (1936). The shearing resistance of saturated soils and the angle between the planes of shear, 1st International Conference on Soil Mechanics and Foundation Engineering, Cambridge, MA, USA, Vol. 1, pp. 54-56.

[034] Wilmanski, K. (1996). Porous media at finite strains-The new model with the balance equation for porosity, Archives of Mechanics 48(4): 591-628. | Zbl 0864.73007

[035] Zienkiewicz, O.C., Chan, A.H.C., Pastor, M., Schrefler, B.A. and Shiomi, T. (1999). Computational Geomechanics with Special Reference to Earthquake Engineering, John Wiley & Sons, West Sussex. | Zbl 0932.74003

[036] Zienkiewicz, O.C. and Shiomi, T. (1984). Dynamic behaviour of saturated porous media: The generalized Biot formulation and its numerical solution, International Journal for Numerical and Analytical Methods in Geomechanics 8(1): 71-96. | Zbl 0526.73099