Arbitrary Lagrangian Eulerian and Fluid-Structure Interaction
Numerical Simulation
Will be published approx. on 15. January 2010
Book
Hardback
312 pages
978-1-84821-131-5 (ISBN)
Description
This book provides the fundamental basics for solving fluid structure interaction problems, and describes different algorithms and numerical methods used to solve problems where fluid and structure can be weakly or strongly coupled. These approaches are illustrated with examples arising from industrial or academic applications. Each of these approaches has its own performance and limitations. Given the book's comprehensive coverage, engineers, graduate students and researchers involved in the simulation of practical fluid structure interaction problems will find this book extremely useful.
More details
Product info
gebunden
Edition
1. Auflage
Language
English
Place of publication
London
United Kingdom
Target group
Professional and scholarly
Product notice
Unsewn / adhesive bound
Paper over boards
Dimensions
Height: 243 mm
Width: 164 mm
Thickness: 27 mm
Weight
577 gr
ISBN-13
978-1-84821-131-5 (9781848211315)
Schweitzer Classification
Other editions
Additional editions
M'hamed Souli | David J. Benson
Arbitrary Lagrangian Eulerian and Fluid-Structure Interaction
Numerical Simulation
E-Book
03/2013
Wiley-ISTE
€139.99
Available for download
M'hamed Souli | David J. Benson
Arbitrary Lagrangian Eulerian and Fluid-Structure Interaction
Numerical Simulation
E-Book
03/2013
Wiley-ISTE
€139.99
Available for download
Persons
Mhamed Souli is Professor of computational mechanics at Lille University in France. His research and development interests include fluid structure interaction, CFD with emphasis on multiphase flow and coupling with structures, and their applications to industrial problems.
David J. Benson is Professor of Computational Mechanics in the Department of Structural Engineering at the University of California, San Diego. He is a Fellow of the American Physical Society, American Society of Mechanical Engineers, and the US Association of Computational Mechanics. He serves on the editorial board of the International Journal of Solids and Structures.
David J. Benson is Professor of Computational Mechanics in the Department of Structural Engineering at the University of California, San Diego. He is a Fellow of the American Physical Society, American Society of Mechanical Engineers, and the US Association of Computational Mechanics. He serves on the editorial board of the International Journal of Solids and Structures.
Content
Introduction xi
Mhamed SOULI
Chapter 1. Introduction to Arbitrary Lagrangian-Eulerian in Finite Element Methods 1
David J. BENSON
1.1. Introduction 1
1.2. Governing equations 3
1.3. Operator splitting 4
1.4. The Lagrangian step 7
1.5. Mesh relaxation 25
1.6. The Eulerian step 27
1.7. Future research directions 44
1.8. Bibliography 45
Application to Dynamic Problems 51
Mhamed SOULI
2.1. Introduction 51
2.2. General ALE description of Navier-Stokes equations 54
2.3. Fluid-structure interaction 57
2.4. Numerical applications 72
Chapter 2. Fluid-Structure Interaction: Application to Dynamic Problems 51
Mhamed SOULI
2.5. Conclusion 104
2.6. Acknowledgments 104
2.7. Bibliography 105
Chapter 3. Implicit Partitioned Coupling in Fluid-Structure Interaction 109
Michael SCHÄFER
3.1. Introduction 109
3.2. Computational fluid mechanics 110
3.3. Computational structural mechanics 121
3.4. Fluid-structure interaction algorithms 136
3.5. Results and applications 150
3.6. Bibliography 161
Chapter 4. Avoiding Instabilities Caused by Added Mass Effects in Fluid-Structure Interaction Problems 165
Sergio IDELSOHN, Facundo DEL PIN and Riccardo ROSSI
4.1. Introduction 165
4.2. The discretized equations to be solved in a FSI problem 169
4.3. Monolithic solution of the FSI equations by pressure segregation 174
4.4. Static condensation of the pressure 176
4.5. Evaluation of the Laplace matrix for FSI problems 187
4.6. The partitioned (or staggered) scheme 189
4.7. Numerical examples 195
4.8. Conclusions 215
4.9. Acknowledgments 216
4.10. Bibliography 216
Chapter 5. Multidomain Finite Element Computations: Application to Multiphasic Problems 221
Thierry COUPEZ, Hugues DIGONNET, Elie HACHEM, Patrice LAURE, Luisa SILVA, Rudy VALETTE
5.1. Introduction 221
5.2. Characterization of different phases 228
5.3. Stabilized finite element formulations 240
5.4. Multiphasic problems with fluid-air and fluid-fluid interface 256
5.5. Immersion of solid bodies in fluid 264
5.6. Conclusion 281
5.7. Acknowledgements 282
5.8. Bibliography 282
List of Authors 291
Index 293