Model for the propagation of a stationary reaction front in a viscoelastic medium = Модель распространения стационарного фронта превращения в вязкоупругой среде / A. G. Knyazeva, E. A. Dyukarev

Уровень набора: Combustion, Explosion, and Shock WavesОсновной Автор-лицо: Knyazeva, A. G., Russian physicist, Professor of Tomsk Polytechnic University, doctor of physico-mathematical Sciences, 1962-, Anna GeorgievnaАльтернативный автор-лицо: Dyukarev, E. A.Язык: английский.Страна: Россия.Резюме или реферат: A coupled thermomechanical model for the propagation of a stationary chemical-reaction wave in a condensed medium is developed. Stresses and strains that arise during the reaction as a result of thermal and “concentration” expansion of the material are related by Maxwell’s equations for a viscoelastic medium. The expression for the heat flux is written as a generalized Fourier law with finite relaxation time for the heat flux. It is shown that deformation of the material in the reaction zone can lead to an apparent change in the activation energy, heat effect, and other characteristics of the system. This model allows for the existence of two different — subsonic and supersonic — regimes of propagation of the front, as well as the model in which the stress- and strain-tensor components are related by a generalized Hooke’s law..Примечания о наличии в документе библиографии/указателя: [References: p. 460-461 (25 tit.)].Аудитория: .Тематика: электронный ресурс | труды учёных ТПУ Ресурсы он-лайн:Щелкните здесь для доступа в онлайн
Тэги из этой библиотеки: Нет тэгов из этой библиотеки для этого заглавия. Авторизуйтесь, чтобы добавить теги.
Оценка
    Средний рейтинг: 0.0 (0 голосов)
Нет реальных экземпляров для этой записи

Title screen

[References: p. 460-461 (25 tit.)]

A coupled thermomechanical model for the propagation of a stationary chemical-reaction wave in a condensed medium is developed. Stresses and strains that arise during the reaction as a result of thermal and “concentration” expansion of the material are related by Maxwell’s equations for a viscoelastic medium. The expression for the heat flux is written as a generalized Fourier law with finite relaxation time for the heat flux. It is shown that deformation of the material in the reaction zone can lead to an apparent change in the activation energy, heat effect, and other characteristics of the system. This model allows for the existence of two different — subsonic and supersonic — regimes of propagation of the front, as well as the model in which the stress- and strain-tensor components are related by a generalized Hooke’s law.

Для данного заглавия нет комментариев.

оставить комментарий.