Overview
Read this article from a comprehensive knowledge base, updated and supplemented with articles reviewed by scientific committees.
Read the articleAUTHORS
-
Juan-Jorge MARTINEZ-VEGA: Professor at Paul-Sabatier University (Toulouse)
-
André RIVIERE: Professor at the École nationale supérieure de mécanique et d'aérotechnique in Poitiers, France
INTRODUCTION
A perfectly elastic material, i.e. one that obeys Hooke's law and is subjected to cyclic stress, will vibrate, in the elastic domain, with no loss of energy except through possible friction with the atmosphere. In reality, materials do not behave so ideally, and their vibrations are damped faster than can be explained by the loss of energy due to external friction.
Internal friction is the property of solid materials subjected to cyclic stresses to absorb energy, transforming mechanical energy into heat. This effect manifests itself in the case of small deformations characteristic of the elastic domain.
The first techniques used to measure internal friction generally allowed measurements at fixed frequencies or in a restricted frequency range. Thus, a pendulum, usually inverted to avoid stress on the sample, allows measurements at frequencies in the hertz range; in this case, the internal friction is δ/π where δ is the logarithmic decrement of the free oscillations. Measurements in the kilohertz range are carried out on resonant blades or bars, this time with internal friction related to the width at 1/ e of the resonance peak. Finally, the attenuation of ultrasonic waves enables measurement in the megahertz range. With these techniques, it is therefore necessary to vary the measurement temperature to fully describe the anelastic behavior, assuming a frequency-temperature equivalence which, in fact, is rarely verified.
This is why it is preferable to be able to measure internal friction directly over a wide frequency range (5 or 6 decades), either with dynamic analyzers used mainly for polymer studies, or with very high natural frequency pendulums (200 Hz) used in sub-resonant forced vibration. In both cases, internal friction is directly related to the tangent of the phase shift angle between the applied stress and the resulting strain.
Internal friction can be associated with various mechanisms, among which we generally distinguish :
the relaxation process in the case of a viscoelastic material ;
mechanical hysteresis ;
resonance in a solid that can be considered as a viscous medium.
Internal friction due to hysteresis depends on vibration amplitude, unlike in the other two cases.
We shall limit ourselves here to internal friction by relaxation, the formalism of which we shall establish after defining the viscoelastic behavior; examples corresponding to various types of material will then be presented.
Exclusive to subscribers. 97% yet to be discovered!
You do not have access to this resource.
Click here to request your free trial access!
Already subscribed? Log in!
The Ultimate Scientific and Technical Reference
This article is included in
Friction, wear and lubrication
This offer includes:
Knowledge Base
Updated and enriched with articles validated by our scientific committees
Services
A set of exclusive tools to complement the resources
Practical Path
Operational and didactic, to guarantee the acquisition of transversal skills
Doc & Quiz
Interactive articles with quizzes, for constructive reading
Internal friction measurement
References
Exclusive to subscribers. 97% yet to be discovered!
You do not have access to this resource.
Click here to request your free trial access!
Already subscribed? Log in!
The Ultimate Scientific and Technical Reference