×

The global behavior of elastoplastic and viscoelastic materials with hysteresis-type state equations. (English) Zbl 0907.35131

Summary: A one-dimensional model is derived in order to study how the elasticity (internal elastic energy) of viscoelastic and elastoplastic materials, such as biopolymers (muscles and grain flour dough) or metals, changes due to the action of external forces. For such materials, the model takes the form of an initial-boundary value problem, corresponding to Newton’s second law, which is coupled to an auxiliary (stress-strain) state equation which characterizes the nature of the interaction between the material and the external forces. In the oscillatory loading of muscles and the mixing of grain flour, as well as of the fatiguing of metals, the state equation must model how the stress depends on the earlier history of the strain as well as describe how the material gains or loses elastic energy due to the action of the loading. One is thereby led to model the auxiliary stress-strain relationship as a constitutive relationship involving a Duhem-Madelung hysteresis operator.
As well as discussing the formulation of such models along with the properties of Duhem-Madelung hysteresis operators, this paper examines the existence and uniqueness for the solutions of such coupled systems. In addition, some global estimates are derived for these solutions, and their asymptotic behavior, as the time increases, is studied under the assumption that a part of the internal (elastic) energy dissipates during the interaction and, hence, the associated Duhem-Madelung hysteron has negative spin.

MSC:

35Q80 Applications of PDE in areas other than physics (MSC2000)
76A10 Viscoelastic fluids
74Hxx Dynamical problems in solid mechanics
49J20 Existence theories for optimal control problems involving partial differential equations
47J05 Equations involving nonlinear operators (general)
74C10 Small-strain, rate-dependent theories of plasticity (including theories of viscoplasticity)
PDFBibTeX XMLCite
Full Text: DOI