论文信息 - Mixed finite element methods for elastic rods of arbitrary geometry

Mixed finite element methods for elastic rods of arbitrary geometry

SummaryThe boundary-value problem for rods having arbitrary geometry, and subjected to arbitrary loading, is studied within the context of the small-strain theory. The basic assumptions underlying the rod kinematics are those corresponding to the Timoshenko hypotheses in the plane rectilinear case: that is, plane sections normal to the line of centroids in the undeformed state remain plane, but not necessarily normal. The problem is formulated in both the standard and mixed variational forms, and after establishing the existence and uniqueness of solutions to these equivalent problems, the corresponding discrete problems are studied. Finite element approximations of the mixed problem are shown to be stable and convergent. It is shown that the equivalence between the mixed problem and the standard problem with selective reduced integration holds only for the case of rods having constant curvature and torsion, though. The results of numerical experiments are presented; these confirm the convergent behaviour of the mixed problem.

B. D. Reddy | B. Reddy | K. Arunakirinathar | K. Arunakirinathar

[1] D. Arnold. Discretization by finite elements of a model parameter dependent problem , 1981 .

[2] F. Brezzi. On the existence, uniqueness and approximation of saddle-point problems arising from lagrangian multipliers , 1974 .

[3] Thomas J. R. Hughes,et al. Stability, convergence, and accuracy of a new finite element method for the circular arch problem , 1987 .

[4] B. Dayanand Reddy. Functional Analysis and Boundary Value Problems: An Introductory Treatment , 1986 .

[5] B. D. Reddy,et al. Convergence of mixed finite element approximations for the shallow arch problem , 1988 .

[6] Michel Fortin,et al. Mixed and Hybrid Finite Element Methods , 2011, Springer Series in Computational Mathematics.

[7] B. D. Reddy,et al. Mixed finite element methods for the circular arch problem , 1992 .

[8] Vivette Girault,et al. Finite Element Methods for Navier-Stokes Equations - Theory and Algorithms , 1986, Springer Series in Computational Mathematics.

[9] F. Kikuchi. Accuracy of some finite element models for arch problems , 1982 .

[10] J. C. Simo,et al. A finite strain beam formulation. The three-dimensional dynamic problem. Part I , 1985 .

[11] K. Rektorys. Variational Methods in Mathematics, Science and Engineering , 1977 .