An intuitive and comprehensive exploration of computational fluid dynamics in the study of wind engineering
Computational Fluid Dynamics for Wind Engineering provides readers with a detailed understanding of the use of computational fluid dynamics (CFD) in understanding wind loading on structures, a problem becoming more pronounced as urban density increases and buildings become larger. The work emphasizes the application of CFD to practical problems in wind loading and helps readers understand important associated factors such as turbulent flow around buildings and bridges.
Written by a highly qualified professor with extensive research experience in related fields, the book includes accessible summaries at the end of each chapter. Every chapter also offers relevant and engaging practice material to help students learn and retain the concepts discussed within, and the use of the OpenFOAM tool--an open-source wind engineering application--is explored as well.
Computational Fluid Dynamics for Wind Engineering covers topics like:
- Fluid mechanics, turbulence in fluid mechanics, turbulence modelling, and mathematical modelling of wind engineering problems
- The finite difference method for CFD, solutions to the incompressible Navier-Stokes equations, visualization, and animation in CFD, and the application of CFD to building and bridge aerodynamics
- How to compare CFD analysis with wind tunnel measurements, field measurements, and the ASCE-7 pressure coefficients
- Wind effects and strain on large structures
Providing comprehensive coverage of how CFD can explain wind load on structures and helpful examples of practical applications, Computational Fluid Dynamics for Wind Engineering serves as an invaluable resource for senior undergraduate students, graduate students, and researchers and practitioners of civil and structural engineering.
About the Author:
Panneer Selvam is University Professor and holds the James T. Womble Endowed Professorship in Computational Mechanics and Nanotechnology Modelling in the Department of Civil Engineering at the University of Arkansas. His research interests include structural analysis, structural loading, finite element methods in civil engineering, numerical modelling of linear, nonlinear, and dynamic behaviour in structural mechanics, and fluid dynamics and acoustics using boundary element, finite element, and finite difference methods. He is also interested in computer modeling in wind engineering, understanding turbulent flow, thermal energy storage, thermal management for electronics, and fluid-structure interaction problems.
