Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Eine Plattform für die Wissenschaft: Bauingenieurwesen, Architektur und Urbanistik
Stress Domains, Relaxation, and Creep
Abstract In this section we consider creep and other slow (thermally induced) relaxation processes which occur at low sliding velocity [11.1]. We first argue that the lubrication film at low sliding velocities has a granular structure, with pinned adsorbate domains accompanied by elastic stress domains in the block and substrate. At zero temperature, the stress domains form a “critical” state, with a continuous distribution P(σ) of local surface stresses σ extending to the critical stress σ a, necessary for fluidization of the pinned adsorbate structure. During sliding adsorbate domains will fluidize and re-freeze. During the time for which an adsorbate domain remains in a fluidized state, the local elastic stresses built up in the elastic bodies during “stick” will be released, partly by emission of elastic wave pulses (sound waves) and partly by shearing the lubrication fluid. The role of temperature-activated processes (relaxation and creep) will be studied and correlated with experimental observations. In particular, the model explains in a natural manner the logarithmic time dependence observed for various relaxation processes; this time dependence follows from the existence of a sharp step-like cut-off at σ = σ a in the distribution P(σ) of surface stresses.
Stress Domains, Relaxation, and Creep
Abstract In this section we consider creep and other slow (thermally induced) relaxation processes which occur at low sliding velocity [11.1]. We first argue that the lubrication film at low sliding velocities has a granular structure, with pinned adsorbate domains accompanied by elastic stress domains in the block and substrate. At zero temperature, the stress domains form a “critical” state, with a continuous distribution P(σ) of local surface stresses σ extending to the critical stress σ a, necessary for fluidization of the pinned adsorbate structure. During sliding adsorbate domains will fluidize and re-freeze. During the time for which an adsorbate domain remains in a fluidized state, the local elastic stresses built up in the elastic bodies during “stick” will be released, partly by emission of elastic wave pulses (sound waves) and partly by shearing the lubrication fluid. The role of temperature-activated processes (relaxation and creep) will be studied and correlated with experimental observations. In particular, the model explains in a natural manner the logarithmic time dependence observed for various relaxation processes; this time dependence follows from the existence of a sharp step-like cut-off at σ = σ a in the distribution P(σ) of surface stresses.
Stress Domains, Relaxation, and Creep
Dr. Persson, Bo N. J. (Autor:in)
Second Edition
01.01.2000
31 pages
Aufsatz/Kapitel (Buch)
Elektronische Ressource
Englisch
Creep, Stress Relaxation, and Rate Effects in Sand
| British Library Conference Proceedings | 2009
Creep and stress relaxation of geotextile-reinforced soils
| Tema Archiv | 1998
Creep relaxation in the presence of residual stress
| British Library Online Contents | 2015
Generalized Creep and Stress Relaxation Model for Clays
| British Library Online Contents | 1992
Creep relaxation in the presence of residual stress
| British Library Online Contents | 2015