Thermal coupling of fluid flow and structural response of a tunnel induced by fire

• Published in: International journal for numerical methods in engineering Vol. 87; no. 1-5; pp. 361 - 385
• Main Authors: Schrefler, B. A., Codina, R., Pesavento, F., Principe, J.
• Format: Journal Article
• Language: English
• Published: Chichester, UK John Wiley & Sons, Ltd 08.07.2011; Wiley
• Subjects: Applied sciences; Buildings. Public works; Computational fluid dynamics; Computational methods in fluid dynamics; Computer simulation; concrete; Concretes; Conservation; Convection and heat transfer; coupling; Exact sciences and technology; fire; Fires; Fluid dynamics; fluid-solid; Fracture mechanics (crack, fatigue, damage...); Fundamental areas of phenomenology (including applications); Mathematical analysis; Mathematical models; Physics; Solid mechanics; Structural and continuum mechanics; Tunnels (transportation); Tunnels, galleries; Turbulent flows, convection, and heat transfer; Motor car; Enthalpy; Decomposition method; High temperature; Fluid structure interaction; Porous material; Modeling; Convection; Finite element method; Phase transformation; coupling; Conservation law; Fire development; fluid-solid; Dirichlet problem; fire; Tunnels; Neumann problem; Computational fluid dynamics; Subgrid scale method; Phase change; Thermomechanical properties; Heterogeneous material; Boundary value problem; Subsonic flow; Internal fluid; Concrete; Domain decomposition; Heat transfer
• ISSN: 0029-5981; 1097-0207; 1097-0207
• DOI: 10.1002/nme.3077

In this work we present the progress in the development of an algorithm for the simulation of thermal fluid–structural coupling in a tunnel fire. The coupling strategy is based on a Dirichlet/Neumann non‐overlapping domain decomposition of the problem, which is carried out by developing a master code that controls solvers dedicated to the fluid mechanics and to the solid mechanics simulation. The computational fluid dynamics formulation consists of a stabilized finite element approximation of the low Mach number equations based on the subgrid scale concept, that allows us to deal with convection‐dominated problems and to use equal order interpolation of velocity and pressure. The thermo‐structural model of the tunnel vault, that considers a multiphase porous material where pores are partly filled with liquid and partly by gas, is specially devised for the simulation of concrete at high temperatures and consists of balance equations for mass conservation of dry air, mass conservation of water species (both in the liquid and gaseous state), enthalpy conservation and linear momentum conservation taking phase changes into account. The developed algorithm is applied to the problem of the response of a tunnel to a fire. We consider the combustion process as a heat release which can vary usually from 1thinspaceMW for small car fires to 100 MW for catastrophic fires. The released heat is transferred to the concrete walls of the tunnel which could cause extensive and heavy damage of the structure. Copyright © 2010 John Wiley & Sons, Ltd.