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1998 | Buch

Foundations and equations of continuum mechanics Kapitel lesen Erstes Kapitel lesen

Vibrations of Elasto-Plastic Bodies

verfasst von: Prof. Dr. Vladimir Palmov

Verlag: Springer Berlin Heidelberg

Buchreihe : Foundations of Engineering Mechanics

Enthalten in: Professional Book Archive

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Über dieses Buch

Undeservedly little attention is paid in the vast literature on the theories of vibration and plasticity to the problem of steady-state vibrations in elastoplastic bodies. This problem, however, is of considerable interest and has many important applications. The problem of low-cyclic fatigue of metals, which is now in a well de­ veloped state is one such application. The investigations within this area are actually directed to collecting experimental facts about repeated cyclic loadings, cf. [47J. Theoretical investigations within this area usually con­ sider the hysteretic loops and the construction of models of plasticity theory which are applicable to the analysis of repeated loadings and the study of the simplest dynamic problems. Another area of application of the theory of the vibration of elastoplas­ tic bodies is the applied theory of amplitude-dependent internal damping. Another name for this theory is the theory of energy dissipation in vibrat­ ing bodies. In accordance with the point of view of Davidenkov "internal damping" in many metals, alloys and structural materials under consider­ able stress presents exactly the effect of micro plastic deformations. There­ fore, it may be described by the methods of plasticity theory. This point of view is no doubt fruitful for the theory of energy dissipation in vibrating bodies, as it allows one to write down the constitutive equations appropri­ ate both for vibrational analysis of three-dimensional stress states and an investigation of nonharmonic deformation. These problems are known to be important for the theory of internal damping.

Inhaltsverzeichnis

Frontmatter
1. Foundations and equations of continuum mechanics
Abstract
Real solids have discrete structure. Descriptions of the mechanics of such solids usually ignore this important physical property and adopt the so-called continuous medium approach, i.e. the medium is considered to be a continuous aggregate of material points in motion. The properties of the medium are assumed not to change even if an infinitesimally small piece is considered. Continuous medium is a useful abstraction which allows one to apply differential and integral calculus while studying the motion of deformable bodies.
Vladimir Palmov
2. Plasticity theory and internal friction in materials
Abstract
The vast majority of both experimental and theoretical papers on the amplitude-dependent internal friction in metals is devoted to the analysis of harmonic or near-harmonic deformation laws. The main problem encountered with the theoretical analysis of non-harmonic motions, which are present in various applications, is that there exist no analytic expressions for inelastic forces for arbitrary time-varying deformations. It is worth mentioning that existing expressions for this force, cf. [140] and [144], deal exclusively with a harmonic deformation law. However, it is unclear how these expressions should be modified to make them applicable for arbitrary deformation.
Vladimir Palmov
3. Three-dimensional cyclic deformations of elastoplastic materials
Abstract
In what follows, the equations for the Ishlinsky material are used in isothermal case. Consequently,
1.
The dilatation depends linearly on the mean normal stress
$$ \sigma {\text{ = }}\kappa \vartheta . $$
(3.1)
 
Vladimir Palmov
4. Single-frequency vibrations in elastoplastic bodies
Abstract
In what follows we offer an approach which is a direct application of the Galerkin method in the form of a single term approximation to the system of equations for an elastoplastic body with the subsequent use of the method of harmonic linearisation. The vibration mode of the elastic body is assumed to be given. This assumption is crucial and is generally accepted in the analysis of nonlinear systems with distributed parameters.
Vladimir Palmov
5. Random deformation of elastoplastic materials
Abstract
This and the following Chapters assume that the reader is familiar with the theory of random functions as described in [190].
Vladimir Palmov
6. Random vibrations of elastoplastic bodies
Abstract
Proceeding to the boundary-value problems of the theory of elastoplastic vibration, we make use of the variational equation of continuum mechanics, eq. (4.9)
$$\int\limits_V {\left[ {\rho \left( {\ddot u - K} \right) \cdot \delta u + \tau :\delta \varepsilon } \right]} dV - \mathop \smallint \limits_o p \cdot \delta udO = 0 $$
(6.1)
Vladimir Palmov
7. Propagation of vibration in a nonlinear dissipative medium
Abstract
A simple problem, namely the problem of longitudinal vibration in a homogeneous rod, will be studied in this chapter. Most attention will be given to the analysis of vibration in a semi-infinite rod loaded at one of its ends. A traditional method of nonlinear mechanics, namely a series expansion in terms of normal modes, which was used in Chapters 4 and 6 is not applicable here. The approach used in this chapter is based on the method of propagating waves which overcomes some difficulties caused mainly by the wave heterogeneity due to the energy dissipation in the rod’s material. The problem of the vibration of a very long rod excited by a high frequency load is a related problem. A peculiarity of this problem lies in the fact that distortion of the normal modes due to small dissipative forces cannot be ignored.
Vladimir Palmov
8. Propagation of vibration in media with complex structure
Abstract
The laws of vibration decay with distance from the source of vibration were investigated in the previous Chapter. The character of the decay turned out to be essentially dependent on the rheological properties of the material. There exists, however, another important factor which influences the decay character, which is the dynamical structure of the medium. The analysis of media with complex structure has attracted much attention. The simplest among the media with complex structure is the Cosserat medium, its modern description being given in [91] and [117]. The Mindlin medium with a microstructure, see [106], is more sophisticated. Of extreme complexity is the multipolar mechanics developed by Green and Rivlin [45].
Vladimir Palmov
Backmatter
Metadaten
Titel
Vibrations of Elasto-Plastic Bodies
verfasst von
Prof. Dr. Vladimir Palmov
Copyright-Jahr
1998
Verlag
Springer Berlin Heidelberg
Electronic ISBN
978-3-540-69636-0
Print ISBN
978-3-642-08352-5
DOI
https://doi.org/10.1007/978-3-540-69636-0