Computation of Unsteady Internal Flows

Computation of Unsteady Internal Flows : Fundamental Methods with Case Studies

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Computation of Unsteady Internal Flows provides an in-depth understanding of unsteady flow modeling and algorithms. This understanding enables suitable algorithms and approaches for particular fields of application to be selected. In addition, the understanding of the behavior of algorithms gained allows practitioners to use them more safely in existing codes, enabling meaningful results to be produced more economically.
Features of Computation of Unsteady Internal Flows: Specialized unsteady flow modeling algorithms, their traits, and practical tips relating to their use are presented.
Case studies considering complex, practically significant problems are given.
Source code and set-up files are included. Intended to be of a tutorial nature, these enable the reader to reproduce and extend case studies and to further explore algorithm performances.
Mathematical derivations are used in a fashion that illuminates understanding of the physical implications of different numerical schemes. Physically intuitive mathematical concepts are used.
New material on adaptive time stepping is included. GBP/LISTGBP Audience: Researchers in both the academic and industrial areas who wish to gain in-depth knowledge of unsteady flow modeling will find Computation of Unsteady Internal Flows invaluable. It can also be used as a text in courses centered on computational fluid dynamics.
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Product details

  • Hardback | 355 pages
  • 155.96 x 233.93 x 22.35mm | 1,560.35g
  • Dordrecht, Netherlands
  • English
  • 2001 ed.
  • XVIII, 355 p.
  • 0792373715
  • 9780792373711

Table of contents

Preface. Nomenclature. 1. Introduction. 2. Overview of Elementary Temporal Discretizations. 3. Temporal and Spatial Discretization Relationships. 4. Solver Algorithms and General Solution Procedures. 5. Solution Adapted Time-Steps. 6. Turbulence Modelling. 7. Cyclic Annular Cavity Flows. 8. Cyclic Aero Engine Motivated Cavity Flows. 9. Cyclic Moving Boundary Flows. 10. Cyclic Complex System Flow. 11. Transient Complex System Flow. 12. Overall Conclusions with Future Perspectives. Appendices. References. Index.
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