Pradip Majumdar
Computational Fluid Dynamics and Heat Transfer
Pradip Majumdar
Computational Fluid Dynamics and Heat Transfer
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This book provides a thorough understanding of fluid dynamics and heat and mass transfer. The second edition contains new chapters on mesh generation and computational modeling of turbulent flow. Combining theory and practice in classic problems and computer code, the text includes examples in ANSYS, STAR CCM+, and COMSOL.
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This book provides a thorough understanding of fluid dynamics and heat and mass transfer. The second edition contains new chapters on mesh generation and computational modeling of turbulent flow. Combining theory and practice in classic problems and computer code, the text includes examples in ANSYS, STAR CCM+, and COMSOL.
Produktdetails
- Produktdetails
- Verlag: Taylor and Francis
- 2nd edition
- Seitenzahl: 676
- Erscheinungstermin: 29. Dezember 2021
- Englisch
- Abmessung: 254mm x 178mm x 38mm
- Gewicht: 1415g
- ISBN-13: 9781498703741
- ISBN-10: 1498703747
- Artikelnr.: 58817366
- Verlag: Taylor and Francis
- 2nd edition
- Seitenzahl: 676
- Erscheinungstermin: 29. Dezember 2021
- Englisch
- Abmessung: 254mm x 178mm x 38mm
- Gewicht: 1415g
- ISBN-13: 9781498703741
- ISBN-10: 1498703747
- Artikelnr.: 58817366
PRADIP MAJUMDAR earned his M.S. and Ph.D. in mechanical engineering from Illinois Institute of Technology. He was a professor and the chair in the Department of Mechanical Engineering at Northern Illinois University. He is recipient of the 2008 Faculty of the Year Award for Excellence in Undergraduate Education. Dr. Majumdar has been the lead investigator for numerous federal and industrial projects. Dr. Majumdar authored numerous papers on fluid dynamics, heat and mass transfer, energy systems, fuel cell, Li-ion battery storage, electronics cooling and electrical devices, engine combustion, nano-structured materials, advanced manufacturing, and transport phenomena in biological systems. Dr. Majumdar is the author of three books including Computational Methods for Heat and Mass Transfer; Fuel Cells- Principles, Design and Analysis; and Design of Thermal Energy Systems (In Press). Dr. Majumdar is currently serving as an editor of the International Communications in Heat and Mass Transfer. He has previously served as the Associate Editor of ASME Journal of Thermal Science and Engineering. Dr. Majumdar has been making keynote and plenary presentations on Li-ion Battery storage, fuel cell, electronics cooling, nanostructure materials at national/international conferences and workshops. Dr. Majumdar has participated as an international expert in GIAN lecture series on fuel cell and Li-ion battery storage. Dr. Majumdar is a fellow of the American Society of Mechanical Engineers (ASME).
Part I: Basic Equations and Numerical Analysis 1. Review of Basic Laws and
Equations 2. Approximations and Errors 3. Numerical Solutions of Systems of
Equations 4. Numerical Integration Part II: Finite Difference - Control
Volume Method 5. Basic Steps in Finite Difference-Control Volume Method 6.
Finite Difference-Control Volume Method: Multidimensional Problems 7.
Finite Difference-Control Volume Method: Unsteady State Diffusion Equation
8. Finite Difference-Control Volume Method: Convection Problems 9.
Additional Features in Computational Model and Mesh Generations 10.
Turbulent Flow Modeling Part III: Finite Element Method 11. Introduction
and Basic Steps in Finite Element Method 12. Element Shape Functions 13.
Finite Element Method: One-Dimensional Steady State Problems 14. Finite
Element Method: Multidimensional Steady-State Problems 15. Finite Element
Method: Unsteady-State Problems 16. Finite Element Method: Convection
Problems
Equations 2. Approximations and Errors 3. Numerical Solutions of Systems of
Equations 4. Numerical Integration Part II: Finite Difference - Control
Volume Method 5. Basic Steps in Finite Difference-Control Volume Method 6.
Finite Difference-Control Volume Method: Multidimensional Problems 7.
Finite Difference-Control Volume Method: Unsteady State Diffusion Equation
8. Finite Difference-Control Volume Method: Convection Problems 9.
Additional Features in Computational Model and Mesh Generations 10.
Turbulent Flow Modeling Part III: Finite Element Method 11. Introduction
and Basic Steps in Finite Element Method 12. Element Shape Functions 13.
Finite Element Method: One-Dimensional Steady State Problems 14. Finite
Element Method: Multidimensional Steady-State Problems 15. Finite Element
Method: Unsteady-State Problems 16. Finite Element Method: Convection
Problems
Part I: Basic Equations and Numerical Analysis 1. Review of Basic Laws and
Equations 2. Approximations and Errors 3. Numerical Solutions of Systems of
Equations 4. Numerical Integration Part II: Finite Difference - Control
Volume Method 5. Basic Steps in Finite Difference-Control Volume Method 6.
Finite Difference-Control Volume Method: Multidimensional Problems 7.
Finite Difference-Control Volume Method: Unsteady State Diffusion Equation
8. Finite Difference-Control Volume Method: Convection Problems 9.
Additional Features in Computational Model and Mesh Generations 10.
Turbulent Flow Modeling Part III: Finite Element Method 11. Introduction
and Basic Steps in Finite Element Method 12. Element Shape Functions 13.
Finite Element Method: One-Dimensional Steady State Problems 14. Finite
Element Method: Multidimensional Steady-State Problems 15. Finite Element
Method: Unsteady-State Problems 16. Finite Element Method: Convection
Problems
Equations 2. Approximations and Errors 3. Numerical Solutions of Systems of
Equations 4. Numerical Integration Part II: Finite Difference - Control
Volume Method 5. Basic Steps in Finite Difference-Control Volume Method 6.
Finite Difference-Control Volume Method: Multidimensional Problems 7.
Finite Difference-Control Volume Method: Unsteady State Diffusion Equation
8. Finite Difference-Control Volume Method: Convection Problems 9.
Additional Features in Computational Model and Mesh Generations 10.
Turbulent Flow Modeling Part III: Finite Element Method 11. Introduction
and Basic Steps in Finite Element Method 12. Element Shape Functions 13.
Finite Element Method: One-Dimensional Steady State Problems 14. Finite
Element Method: Multidimensional Steady-State Problems 15. Finite Element
Method: Unsteady-State Problems 16. Finite Element Method: Convection
Problems