Gas turbines : internal flow systems modeling
Author(s)
Bibliographic Information
Gas turbines : internal flow systems modeling
(Cambridge aerospace series, 44)
Cambridge University Press, 2018
- : hard
Available at 5 libraries
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Note
Includes bibliographical references and index
Description and Table of Contents
Description
This long-awaited, physics-first and design-oriented text describes and explains the underlying flow and heat transfer theory of secondary air systems. An applications-oriented focus throughout the book provides the reader with robust solution techniques, state-of-the-art three-dimensional computational fluid dynamics (CFD) methodologies, and examples of compressible flow network modeling. It clearly explains elusive concepts of windage, non-isentropic generalized vortex, Ekman boundary layer, rotor disk pumping, and centrifugally-driven buoyant convection associated with gas turbine secondary flow systems featuring rotation. The book employs physics-based, design-oriented methodology to compute windage and swirl distributions in a complex rotor cavity formed by surfaces with arbitrary rotation, counter-rotation, and no rotation. This text will be a valuable tool for aircraft engine and industrial gas turbine design engineers as well as graduate students enrolled in advanced special topics courses.
Table of Contents
- 1. Overview of gas turbines for propulsion and power generation
- 2. Review of thermodynamics, fluid mechanics, and heat transfer
- 3. 1-D flow and network modeling
- 4. Internal flow around rotors and stators
- 5. Labyrinth seals
- 6. Whole engine modeling.
by "Nielsen BookData"