Numerical analysis of the pressure field on curved and open self-weighted metallic roofs due to the wind effect by the finite volume method

Applied Mathematics and Computation

Volumn 209, Issue 1, 2009, Pages 31-41

  del Coz Diaz J J ^a   Garcia Nieto P J ^a   Gonzalez Perez J A ^b   Martin Navarro A ^b  

^a UNIVERSITY OF OVIEDO   (Spain)

^b UNIVERSIDAD DE SEVILLA   (Spain)

Author keywords

Computational fluid dynamics; Curved self weighted metallic roofs; Finite volume modeling; Numerical and experimental methods; Steady incompressible flow

Indexed keywords

ATMOSPHERIC PRESSURE; COMPUTATIONAL FLUID DYNAMICS; DYNAMICS; FINITE ELEMENT METHOD; FINITE VOLUME METHOD; FLUID DYNAMICS; INCOMPRESSIBLE FLOW; NAVIER STOKES EQUATIONS; NUMERICAL METHODS; TURBULENCE; TURBULENT FLOW;

AIR PRESSURES; CURVED SELF-WEIGHTED METALLIC ROOFS; EUROPEAN STANDARDS; EXPERIMENTAL TESTS; FINITE ELEMENTS; FINITE VOLUME MODELING; FINITE VOLUMES; FINITE-ELEMENT METHODS; NON LINEARITIES; NUMERICAL AND EXPERIMENTAL METHODS; PRESSURE FIELDS; REDUCED SCALE MODELS; STEADY INCOMPRESSIBLE FLOW;

ROOFS;

EID: 60249103268     PISSN: 00963003     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.amc.2008.06.063     Document Type: Article

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