Concrete exposed to fire: From fire scenario to structural response

Francesco Pesavento; Matteo Pachera; Pierfrancesco Brunello; Bernhard A. Schrefler

doi:10.4028/www.scientific.net/KEM.711.556

Concrete exposed to fire: From fire scenario to structural response

Francesco Pesavento, Matteo Pachera, Pierfrancesco Brunello, Bernhard A. Schrefler

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

4 Scopus citations

Abstract

In this paper a model for the analysis of concrete structures exposed to fire, based on Porous Media Mechanics, is coupled with a computational fluid dynamics model. To show the capability of this strategy the numerical simulation of a simple concrete slab exposed to fire is presented. The thermal loads as well as the moisture exchange between the structure surface and the environment are calculated by means of computational fluid dynamics program. Thanks to this strategy the structural verification is no longer based on the standard fire curves commonly used in the engineering practice, but it is directly related to a realistic fire scenario. With the simple example proposed, it is possible to highlight how the localized thermal load generates a nonuniform pressure rise in the material, which results in an increase of the structure stress state and of the spalling risk. Spalling is likely the most dangerous collapse mechanism for a concrete structure. Numerical results of various sections of the slab exposed to fire are presented, showing the effects of a more realistic distribution of the thermal loads with respect to the ones obtained by using the standard fire curves. This coupling approach still represents a "one way" strategy, i.e. realized without considering explicitly the exchange of boundary conditions from the structure to the fluid. This results in an approximation, but from physical point of view the current form of the solid-fluid coupling is considered sufficiently accurate in this first phase of the research.

Original language	English (US)
Title of host publication	Concrete under Severe Conditions - Environment and Loading
Editors	Matteo Colombo, Marco di Prisco
Publisher	Trans Tech Publications Ltd
Pages	556-563
Number of pages	8
ISBN (Print)	9783035710441
DOIs	https://doi.org/10.4028/www.scientific.net/KEM.711.556
State	Published - 2016
Event	8th International Conference on Concrete under Severe Conditions - Environment and Loading, CONSEC 2016 - Lecco, Italy Duration: Sep 12 2016 → Sep 14 2016

Publication series

Name	Key Engineering Materials
Volume	711
ISSN (Print)	1013-9826
ISSN (Electronic)	1662-9795

Other

Other	8th International Conference on Concrete under Severe Conditions - Environment and Loading, CONSEC 2016
Country/Territory	Italy
City	Lecco
Period	9/12/16 → 9/14/16

Keywords

CFD
FEM
Fire-structure interaction
High temperature
Porous media mechanics
Spalling risk

ASJC Scopus subject areas

Materials Science(all)
Mechanics of Materials
Mechanical Engineering

Access to Document

10.4028/www.scientific.net/KEM.711.556

Cite this

Pesavento, F., Pachera, M., Brunello, P., & Schrefler, B. A. (2016). Concrete exposed to fire: From fire scenario to structural response. In M. Colombo, & M. di Prisco (Eds.), Concrete under Severe Conditions - Environment and Loading (pp. 556-563). (Key Engineering Materials; Vol. 711). Trans Tech Publications Ltd. https://doi.org/10.4028/www.scientific.net/KEM.711.556

Concrete exposed to fire: From fire scenario to structural response. / Pesavento, Francesco; Pachera, Matteo; Brunello, Pierfrancesco et al.
Concrete under Severe Conditions - Environment and Loading. ed. / Matteo Colombo; Marco di Prisco. Trans Tech Publications Ltd, 2016. p. 556-563 (Key Engineering Materials; Vol. 711).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

Pesavento, F, Pachera, M, Brunello, P & Schrefler, BA 2016, Concrete exposed to fire: From fire scenario to structural response. in M Colombo & M di Prisco (eds), Concrete under Severe Conditions - Environment and Loading. Key Engineering Materials, vol. 711, Trans Tech Publications Ltd, pp. 556-563, 8th International Conference on Concrete under Severe Conditions - Environment and Loading, CONSEC 2016, Lecco, Italy, 9/12/16. https://doi.org/10.4028/www.scientific.net/KEM.711.556

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abstract = "In this paper a model for the analysis of concrete structures exposed to fire, based on Porous Media Mechanics, is coupled with a computational fluid dynamics model. To show the capability of this strategy the numerical simulation of a simple concrete slab exposed to fire is presented. The thermal loads as well as the moisture exchange between the structure surface and the environment are calculated by means of computational fluid dynamics program. Thanks to this strategy the structural verification is no longer based on the standard fire curves commonly used in the engineering practice, but it is directly related to a realistic fire scenario. With the simple example proposed, it is possible to highlight how the localized thermal load generates a nonuniform pressure rise in the material, which results in an increase of the structure stress state and of the spalling risk. Spalling is likely the most dangerous collapse mechanism for a concrete structure. Numerical results of various sections of the slab exposed to fire are presented, showing the effects of a more realistic distribution of the thermal loads with respect to the ones obtained by using the standard fire curves. This coupling approach still represents a {"}one way{"} strategy, i.e. realized without considering explicitly the exchange of boundary conditions from the structure to the fluid. This results in an approximation, but from physical point of view the current form of the solid-fluid coupling is considered sufficiently accurate in this first phase of the research.",

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AB - In this paper a model for the analysis of concrete structures exposed to fire, based on Porous Media Mechanics, is coupled with a computational fluid dynamics model. To show the capability of this strategy the numerical simulation of a simple concrete slab exposed to fire is presented. The thermal loads as well as the moisture exchange between the structure surface and the environment are calculated by means of computational fluid dynamics program. Thanks to this strategy the structural verification is no longer based on the standard fire curves commonly used in the engineering practice, but it is directly related to a realistic fire scenario. With the simple example proposed, it is possible to highlight how the localized thermal load generates a nonuniform pressure rise in the material, which results in an increase of the structure stress state and of the spalling risk. Spalling is likely the most dangerous collapse mechanism for a concrete structure. Numerical results of various sections of the slab exposed to fire are presented, showing the effects of a more realistic distribution of the thermal loads with respect to the ones obtained by using the standard fire curves. This coupling approach still represents a "one way" strategy, i.e. realized without considering explicitly the exchange of boundary conditions from the structure to the fluid. This results in an approximation, but from physical point of view the current form of the solid-fluid coupling is considered sufficiently accurate in this first phase of the research.

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Concrete exposed to fire: From fire scenario to structural response

Abstract

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Keywords

ASJC Scopus subject areas

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