Symmetric coupling of multi-zone curved Galerkin boundary elements with finite elements in elasticity

Ganguly, S.; Layton, Jeffrey; Balakrishna, C.

doi:10.1002/(sici)1097-0207(20000620)48:5<633::aid-nme874>3.0.co;2-k

Cited by 27 publications

(14 citation statements)

References 30 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…However, as an alternative a coupling of an FE shell model with the so-called symmetric Galerkin boundary-element method (SGBEM) may be applied [33]. An extensive review of the developments regarding the SGBEM can be found in the work by Ganguly et al [34,35].…”

Section: Coupling Of Fe and Be Regionsmentioning

confidence: 99%

Impedance of flexible suction caissons

Liingaard

Andersen

Ibsen

2007

Earthq Engng Struct Dyn

View full text Add to dashboard Cite

SUMMARYThe dynamic response of offshore wind turbines is affected by the properties of the foundation and the subsoil. The aim of this paper is to evaluate the dynamic soil-structure interaction of suction caissons for offshore wind turbines. The investigations include evaluation of the vertical and coupled sliding-rocking vibrations, influence of the foundation geometry and examination on the properties of the surrounding soil. The soil is simplified as a homogenous linear viscoelastic material and the dynamic stiffness of the suction caisson is expressed in terms of dimensionless frequency-dependent coefficients corresponding to different degrees of freedom. The dynamic stiffness coefficients for the skirted foundation are evaluated using a three-dimensional coupled boundary element/finite element model. Comparisons with known analytical and numerical solutions indicate that the static and dynamic behaviours of the foundation are predicted accurately using the applied model. The analysis has been carried out for different combinations of the skirt length, Poisson's ratio of the subsoil and the ratio of the soil stiffness to the skirt stiffness.

show abstract

Section: Coupling Of Fe and Be Regionsmentioning

confidence: 99%

Impedance of flexible suction caissons

Liingaard

Andersen

Ibsen

2007

Earthq Engng Struct Dyn

View full text Add to dashboard Cite

show abstract

“…Indeed, FE method is appropriate for structural analysis, whereas BE method is well-suited to linear elastic problems involving unbounded domains. Nevertheless, the coupling of FE and collocation BE method may involve problems concerning the lack of symmetry of the coefficient matrix in BE formulations and difficulties in the imposition of interface conditions; an extensive overview is given in [5]. The first difficulty can be removed by adopting Symmetric Galerkin BEM-FEM coupling procedures, see e.g.…”

mentioning

confidence: 99%

Static analysis of Timoshenko beam resting on elastic half-plane based on the coupling of locking-free finite elements and boundary integral

Tullini

Tralli

2009

Comput Mech

View full text Add to dashboard Cite

Making use of a mixed variational formulation including the Green function of the soil and assuming as independent fields both the structure displacements and the contact pressure, a finite element model is derived for the static analysis of a foundation beam resting on elastic half-plane. Timoshenko beam model is adopted to describe structural foundations with low slenderness and to impose displacement compatibility between beam and half-plane without requiring the continuity of the first order derivative of the surface displacements enforced by Euler-Bernoulli beam. Numerical results are obtained by using locking-free Hermite polynomials for the Timoshenko beam and constant reaction over the soil. Foundation beams loaded by many load configurations illustrate accuracy and convergence properties of the proposed formulation. Moreover, the different behaviour of the Euler-Bernoulli and Timoshenko beam models is thoroughly discussed. Rectangular pipe loaded by a force in the upper beam exemplifies the straightforward coupling of the foundation finite element with a structure described by usual finite elements

show abstract

“…/j.ijsolstr.2006 The first type essentially treats the subdomain BEM as a macro-finite element (super-element). The displacement-traction equations governing the boundary element subdomain are transformed into displacement-force equations and assembled with those of the finite element method (Wearing and Sheikh, 1988;Ganguly et al, 2000;Aour, 1997;Aour et al, 2005). Conversely, the BEM approach treats the FE subdomain Rice's integral [K] stiffness matrix K I stress intensity factor for mode I N number of boundary elements N i (n) shape functions n i unit direction normal r distance between the field point and the source point R distance from the crack-tip S integration contour for evaluation of J-integral {t n } vector containing the nodal tractions t x , t y traction components in the x-and y-directions, respectively T superscript indicating transpose of a matrix {u n } vector containing the nodal displacements U strain energy density u, v displacement components in the x-and y-directions, respectively u i (x f ), u i (x s ) displacements at field and source points, respectively W work done by external loads x, y…”

Section: Introductionmentioning

confidence: 99%

A coupled FEM/BEM approach and its accuracy for solving crack problems in fracture mechanics

Aour

Rahmani

Naït-Abdelaziz

2007

International Journal of Solids and Structures

View full text Add to dashboard Cite

The finite element (FEM) and the boundary element methods (BEM) are well known powerful numerical techniques for solving a wide range of problems in applied science and engineering. Each method has its own advantages and disadvantages, so that it is desirable to develop a combined finite element/boundary element method approach, which makes use of their advantages and reduces their disadvantages. Several coupling techniques are proposed in the literature, but until now the incompatibility of the basic variables remains a problem to be solved. To overcome this problem, a special super-element using boundary elements based on the usual finite element technique of total potential energy minimization has been developed in this paper. The application of the most commonly used approaches in finite element method namely quarterpoint elements and J-integrals techniques were examined using the proposed coupling FEM-BEM. The accuracy and efficiency of the proposed approach have been assessed for the evaluation of stress intensity factors (SIF). It was found that the FEM-BEM coupling technique gives more accurate values of the stress intensity factors with fewer degrees of freedom.

show abstract

Symmetric coupling of multi-zone curved Galerkin boundary elements with finite elements in elasticity

Cited by 27 publications

References 30 publications

Impedance of flexible suction caissons

Impedance of flexible suction caissons

Static analysis of Timoshenko beam resting on elastic half-plane based on the coupling of locking-free finite elements and boundary integral

A coupled FEM/BEM approach and its accuracy for solving crack problems in fracture mechanics

Contact Info

Product

Resources

About