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The aim of the present book is to give, in a single volume, an
introduction to the fields of transition, turbulence and combustion
modelling of compressible flows and to provide the physical
background for today's modelling approaches in these fields. The
basic equations for compressible flows are presented (Ch. 1). The
fundamental aspects of hydrodynamical instability are discussed
(Ch. 2). along with transition prediction methods in industrial
applications (Ch. 3). Turbulence modelling approaches ranging from
single-point models (Ch. 4, 5) to large-eddy simulation techniques
(Ch. 6), direct numerical simulations (Ch. 7) and turbulence
combustion modelling (Ch. 8) are covered. The book addresses
engineers and researchers, in industry or academia, who are
entering into the fields of transition, turbulence or combustion
modelling research or who need to apply turbulence or transition
prediction methods in their work.
The aim of this book is to give, within a single volume, an
introduction to the fields of turbulence modelling and
transition-to-turbulence prediction, and to provide the physical
background for today's modelling approaches in these problem areas
as well as giving a flavour of advanced use of prediction methods.
Turbulence modelling approaches, ranging from single-point models
based on the eddy-viscosity concept and the Reynolds stress
transport equations (Chapters 3,4,5), to large-eddy simulation
(LES) techniques (Ch. 7), are covered. The foundations of
hydrodynamical stability and transition are presented (Ch. 2) along
with transition prediction methods based on single-point closures
(Ch. 6), LES techniques (Ch. 7) and the parabolized stability
equations (Ch. 8). The book addresses engineers and researchers, in
industry or academia, who are entering into the fields of
turbulence or transition modelling research or need to apply
turbulence or transition prediction methods in their work.
This single-volume work gives an introduction to the fields of
transition, turbulence, and combustion modeling of compressible
flows and provides the physical background for today's modeling
approaches in these fields. It presents basic equations and
discusses fundamental aspects of hydrodynamical instability.
The aim of this book is to give, within a single volume, an
introduction to the fields of turbulence modelling and
transition-to-turbulence prediction, and to provide the physical
background for today's modelling approaches in these problem areas
as well as giving a flavour of advanced use of prediction methods.
Turbulence modelling approaches, ranging from single-point models
based on the eddy-viscosity concept and the Reynolds stress
transport equations (Chapters 3,4,5), to large-eddy simulation
(LES) techniques (Ch. 7), are covered. The foundations of
hydrodynamical stability and transition are presented (Ch. 2) along
with transition prediction methods based on single-point closures
(Ch. 6), LES techniques (Ch. 7) and the parabolized stability
equations (Ch. 8). The book addresses engineers and researchers, in
industry or academia, who are entering into the fields of
turbulence or transition modelling research or need to apply
turbulence or transition prediction methods in their work.
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