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2004 | Buch

Some historical notes on the statistical dynamics of turbulence Kapitel lesen Erstes Kapitel lesen

The Statistical Dynamics of Turbulence

verfasst von: Dr. Jovan Jovanović

Verlag: Springer Berlin Heidelberg

Enthalten in: Professional Book Archive

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Über dieses Buch

This short but complicated book is very demanding of any reader. The scope and style employed preserve the nature of its subject: the turbulence phe­ nomena in gas and liquid flows which are believed to occur at sufficiently high Reynolds numbers. Since at first glance the field of interest is chaotic, time-dependent and three-dimensional, spread over a wide range of scales, sta­ tistical treatment is convenient rather than a description of fine details which are not of importance in the first place. When coupled to the basic conserva­ tion laws of fluid flow, such treatment, however, leads to an unclosed system of equations: a consequence termed, in the scientific community, the closure problem. This is the central and still unresolved issue of turbulence which emphasizes its chief peculiarity: our inability to do reliable predictions even on the global flow behavior. The book attempts to cope with this difficult task by introducing promising mathematical tools which permit an insight into the basic mechanisms involved. The prime objective is to shed enough light, but not necessarily the entire truth, on the turbulence closure problem. For many applications it is sufficient to know the direction in which to go and what to do in order to arrive at a fast and practical solution at minimum cost. The book is not written for easy and attractive reading.

Inhaltsverzeichnis

Frontmatter
1. Some historical notes on the statistical dynamics of turbulence
Abstract
Turbulence is a complex phenomenon that originates from local instabilities which are further amplified owing to non-linearity of the basic equations that govern fluid flow. For the latter reason, application of statistical techniques to basic hydrodynamic equations leads to a closure problem. This was demonstrated by Reynolds [1], who introduced turbulence decomposition into the mean motion and random fluctuations in the equations of fluid flow in an attempt to determine the criterion for the onset of transition and self-maintenance of the turbulence in round tubes.
Jovan Jovanović
2. Dynamic equations for moments
Abstract
Since the time when Osborne Reynolds [1] began his life of adventure in investigating the dynamics of turbulence, it has been postulated that the Navier-Stokes and continuity equations hold for the instantaneous values in turbulent flow:
$$\frac{{\partial U_i }} {{\partial t}} + U_k \frac{{\partial U_i }} {{\partial x_k }} = - \frac{1} {\varrho }\frac{{\partial P}} {{\partial x_i }} + v\frac{{\partial ^2 U_i }} {{\partial x_k \partial x_k }},i,k = 1,2,3$$
(2.1)
$$\frac{{\partial U_i }} {{\partial x_i }} = 0.$$
(2.2)
We may ignore speculations presented in the literature about the validity of this fundamental postulate; there exists firm evidence accumulated from experimental observations and numerical simulations which justify the validity of the Navier-Stokes equations for application to instantaneous motions in turbulent flow.
Jovan Jovanović
3. Dynamics of the turbulent dissipation rate
Abstract
In this chapter, we consider closure of the terms which are related to the dissipation of turbulence:
$$ \in ij = v\overline {\frac{{\partial u_i }} {{\partial x_k }}\frac{{\partial u_j }} {{\partial x_k }}}$$
(3.1)
that appear in (2.29). The procedure for treating the dissipation correlations is based on the application of the two-point correlation technique that was originally developed by Chou [9] and subsequently refined by Kolovandin and Vatutin [58] and Jovanović, Ye and Durst [48].
Jovan Jovanović
4. Velocity-pressure gradient correlations
Abstract
In the previous chapter we presented the statistical analysis of the correlations which contribute to the dissipation of the turbulence energy. To gain more insight into the dynamics of turbulence, however, one needs to consider also the velocity-pressure gradient correlations:
$$\Pi _{ij} = - \frac{1} {\varrho }[\overline {u_j \frac{{\partial p}} {{\partial x_i }}} + \overline {u_i \frac{{\partial p}} {{\partial x_j }}]} .$$
(4.1)
Jovan Jovanović
5. Turbulent transport
Abstract
In this chapter we will analyze turbulent transport:
$$T_{ij} = - \frac{{\partial \overline {u_i u_j u_k } }} {{\partial x_k }},$$
(5.1)
the last unclosed terms in the dynamic equations for the second-order moments \(\overline {u_i u_j }\). These terms reflect the influence of flow inhomogeneity and are of third order in fluctuating velocity.
Jovan Jovanović
Backmatter
Metadaten
Titel
The Statistical Dynamics of Turbulence
verfasst von
Dr. Jovan Jovanović
Copyright-Jahr
2004
Verlag
Springer Berlin Heidelberg
Electronic ISBN
978-3-662-10411-8
Print ISBN
978-3-642-05793-9
DOI
https://doi.org/10.1007/978-3-662-10411-8