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Advances in understanding thermal ef...

Heinrich, G.

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Advances in understanding thermal effects in rubber = experiments, modelling, and practical relevance /

Record Type:	Electronic resources : Monograph/item
Title/Author:	Advances in understanding thermal effects in rubber/ edited by Gert Heinrich ... [et al.].
Reminder of title:	experiments, modelling, and practical relevance /
other author:	Heinrich, G.
Published:	Cham :Springer Nature Switzerland : : 2024.,
Description:	xii, 324 p. :ill. (some col.), digital ;24 cm.
[NT 15003449]:	Temperature effects of rubbers: a microscopical perspective -- Effects of temperature on uniaxial and multiaxial fatigue of natural rubber under relaxing and non-relaxing loadings -- Identification of the part of the hysteresis that is converted into heat -- Emissivity vs. rubber composition -- Heat development during Cut &Chip mechanism -- Heat build-up - numerical prediction -- Thermo-mechanical behavior of tread rubber during high-speed friction -- Influence of thermal ageing on HBU Heat during biaxial loading -- Dynamic viscoelasticity and hysteresis heating of filled rubber under cyclic deformation -- Including temperature effects in the theory and simulation of problems in rubber reinforcement -- Deformation-induced temperature changes in SBR and NR elastomers -- Modeling and characterization of heat transfer in interactive elastomer composites -- A review of thermal effects on elastomer durability.
Contained By:	Springer Nature eBook
Subject:	Rubber - Effect of temperature on. -
Online resource:	https://doi.org/10.1007/978-3-031-71056-8
ISBN:	9783031710568

Advances in understanding thermal effects in rubber = experiments, modelling, and practical relevance /
Advances in understanding thermal effects in rubberexperiments, modelling, and practical relevance /[electronic resource] :edited by Gert Heinrich ... [et al.]. - Cham :Springer Nature Switzerland :2024. - xii, 324 p. :ill. (some col.), digital ;24 cm. - Advances in polymer science,v. 2941436-5030 ;. - Advances in polymer science ;v. 294..

Temperature effects of rubbers: a microscopical perspective -- Effects of temperature on uniaxial and multiaxial fatigue of natural rubber under relaxing and non-relaxing loadings -- Identification of the part of the hysteresis that is converted into heat -- Emissivity vs. rubber composition -- Heat development during Cut &Chip mechanism -- Heat build-up - numerical prediction -- Thermo-mechanical behavior of tread rubber during high-speed friction -- Influence of thermal ageing on HBU Heat during biaxial loading -- Dynamic viscoelasticity and hysteresis heating of filled rubber under cyclic deformation -- Including temperature effects in the theory and simulation of problems in rubber reinforcement -- Deformation-induced temperature changes in SBR and NR elastomers -- Modeling and characterization of heat transfer in interactive elastomer composites -- A review of thermal effects on elastomer durability.

In the case of an ideal rubber, one often thinks of the linear dependence of the shear modulus on temperature as an expression of the typical entropy elasticity. However, temperature dependencies of typical technical rubber materials are known to be much more complicated. This has consequences for the practical behaviour of rubber-elastic components. One well-known instance of this is the dramatic Challenger disaster. The rubber used to seal the solid rocket booster joints with O-rings did not expand at temperatures of 0 °C or below, resulting in an opening in the solid rocket booster joint through which gas attempted to escape. The main physical reason for the heat generation processes is the hysteresis of rubber materials due to deformation and viscoelasticity. Most elastomers therefore change significantly over time when exposed to heat (and likewise light or oxygen (ozone)) These changes can have a dramatic effect on the life and properties of the elastomers. Heat development in a rubber occurs when it is subjected to a variety of compressive stresses in service. Heat evolution tests are commonly performed to estimate the quality of use and expected service life of various compounds or material options for end-product applications. New developments in recent years on test methods in this direction constitute an important part of the book. At the same time, corresponding simulation and modelling methods have been developed that contribute to a better understanding and enable the predictive simulation of self-heating and the kinetics of temperature fields in complex cyclically loaded rubber components. Specifically, finite-strain thermal viscoelastic damage models for predicting the cyclic thermomechanical response of rubber specimens under fatigue are also presented, and analytical models for heat diffusion in stressed rubbers.

ISBN: 9783031710568

Standard No.: 10.1007/978-3-031-71056-8doiSubjects--Topical Terms:

3723845
Rubber
--Effect of temperature on.

LC Class. No.: TA455.R8

Dewey Class. No.: 678.4

Advances in understanding thermal effects in rubber = experiments, modelling, and practical relevance /
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505 0 $a Temperature effects of rubbers: a microscopical perspective -- Effects of temperature on uniaxial and multiaxial fatigue of natural rubber under relaxing and non-relaxing loadings -- Identification of the part of the hysteresis that is converted into heat -- Emissivity vs. rubber composition -- Heat development during Cut &Chip mechanism -- Heat build-up - numerical prediction -- Thermo-mechanical behavior of tread rubber during high-speed friction -- Influence of thermal ageing on HBU Heat during biaxial loading -- Dynamic viscoelasticity and hysteresis heating of filled rubber under cyclic deformation -- Including temperature effects in the theory and simulation of problems in rubber reinforcement -- Deformation-induced temperature changes in SBR and NR elastomers -- Modeling and characterization of heat transfer in interactive elastomer composites -- A review of thermal effects on elastomer durability.
520 $a In the case of an ideal rubber, one often thinks of the linear dependence of the shear modulus on temperature as an expression of the typical entropy elasticity. However, temperature dependencies of typical technical rubber materials are known to be much more complicated. This has consequences for the practical behaviour of rubber-elastic components. One well-known instance of this is the dramatic Challenger disaster. The rubber used to seal the solid rocket booster joints with O-rings did not expand at temperatures of 0 °C or below, resulting in an opening in the solid rocket booster joint through which gas attempted to escape. The main physical reason for the heat generation processes is the hysteresis of rubber materials due to deformation and viscoelasticity. Most elastomers therefore change significantly over time when exposed to heat (and likewise light or oxygen (ozone)) These changes can have a dramatic effect on the life and properties of the elastomers. Heat development in a rubber occurs when it is subjected to a variety of compressive stresses in service. Heat evolution tests are commonly performed to estimate the quality of use and expected service life of various compounds or material options for end-product applications. New developments in recent years on test methods in this direction constitute an important part of the book. At the same time, corresponding simulation and modelling methods have been developed that contribute to a better understanding and enable the predictive simulation of self-heating and the kinetics of temperature fields in complex cyclically loaded rubber components. Specifically, finite-strain thermal viscoelastic damage models for predicting the cyclic thermomechanical response of rubber specimens under fatigue are also presented, and analytical models for heat diffusion in stressed rubbers.
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