A mortar-finite element formulation for frictional contact problems

This paper presents two algorithms for solving the discrete, quasi-static, small-displacement, linear elastic, contact problem with Coulomb friction. The algorithms are adoptions of a Newton method for solving B-di erentiable equations and an interior point method for solving smooth, constrained equ

In this paper, an advanced analytical model and finite element formulations including local bending moment effects for the Friction Pendulum System (FPS) are presented. Some important findings in these investigations reveal that local bending moments which result from the movements of the isolator,

A new formulation for solving elastoplastic frictional contact problems by the boundary element method using non-conforming discretization is presented. The initial strain approach, together with the von Mises yield criterion is adopted. Two di erent methods are developed for the evaluation of the c

In this paper, the energy and momentum conserving algorithmic paradigm is extended to encompass a phenomenon featuring physical dissipation: dynamic frictional contact. Whereas in other works dealing with conservative systems the chief aim is often the maintenance of numerical stability in the non-l

A ®nite element formulation for solving transient multidimensional phase-change problems considering advective eects is presented. This temperature-based formulation includes the de®nition of a phase-change function able to deal with classical isothermal and non-isothermal phase-change cases. Moreov

An analogy with rigid plasticity is used to develop a constitutive framework for quasi-static frictional contact between ÿnitely deforming solids. Within this setting, a Lagrange multiplier method is used to impose a sharp distinction between stick and slip. The scope of the multipliers is limited b