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This book is designed for undergraduate and graduate engineering students who are encountering computational fluid dynamics for the first time in their study of fluid machines. The approach emphasizes a gradual and effective learning process, aiming to minimize the time required to attain a solid foundational understanding. Clarity of exposition is prioritized over strict mathematical rigor, with continuous reference to the physical significance of the mathematical formulas presented. This approach enables students to independently produce acceptable results for most case studies of general interest. The book provides a comprehensive collection of essential concepts needed for correctly configuring any computational fluid dynamics software. To enhance accessibility, it focuses on OpenFOAM, a free and open-source software renowned for its extensive community of developers and users.
List of contents
Preliminary concepts.- Governing Equations of Fluid Dynamics.- The Finite Volume Method.- Linear systems and their solution.- Pressure-Velocity Coupling.- OpenFOAM®.- Boundary Conditions.- Turbulence.
About the author
Giovanni Caramia is a fixed-term researcher in Systems and Machines for Energy and the Environment at the Polytechnic of Bari. He has gained significant experience in the field of computational fluid dynamics through his successful work in addressing research-related issues, as well as supporting innumerable students with their thesis projects. As an advocate for open-source software in education and academia, he predominantly uses OpenFOAM® for performing fluid dynamics simulations.
Elia Distaso is a Professor of Systems and Machines for Energy and the Environment at the Polytechnic of Bari, Italy. He received his training at the same institution and at the Engine Research Center (ERC) of the University of Wisconsin-Madison, USA. His research focuses on reactive and non-reactive processes related to propulsion and energy production systems.
Summary
This book is designed for undergraduate and graduate engineering students who are encountering computational fluid dynamics for the first time in their study of fluid machines. The approach emphasizes a gradual and effective learning process, aiming to minimize the time required to attain a solid foundational understanding. Clarity of exposition is prioritized over strict mathematical rigor, with continuous reference to the physical significance of the mathematical formulas presented. This approach enables students to independently produce acceptable results for most case studies of general interest. The book provides a comprehensive collection of essential concepts needed for correctly configuring any computational fluid dynamics software. To enhance accessibility, it focuses on OpenFOAM, a free and open-source software renowned for its extensive community of developers and users.
