On the Structural Behavior of Reinforced Concrete Walls Exposed to Fire

Patrick Bamonte; Roberto Felicetti; Nataša Kalaba; Francesco Lo Monte; Nicholas Pinoteau; Md Jihad Miah; Pierre Pimienta

doi:10.4028/www.scientific.net/KEM.711.580

Paper Titles

Fire Spalling Behaviour of Concrete: Role of Mechanical Loading (Uniaxial and Biaxial) and Cement Type
p.549

Concrete Exposed to Fire: From Fire Scenario to Structural Response
p.556

Fire Performance of Columns Made of Normal and High Strength Concrete: A Comparative Analysis
p.564

Statistical Comparison of the Results of Applying Several Methods in Checking Concrete Columns’ Fire Resistance
p.572

On the Structural Behavior of Reinforced Concrete Walls Exposed to Fire
p.580

Modelling the Response of Simply-Supported Two-Way Reinforced Concrete Slabs Exposed to Fire
p.588

The Quest for Absolute Concrete Durability Performance Criteria
p.599

Achieving Concrete Durability in Chloride Exposures
p.607

Utilization of Fabric Formwork for Improving the Durability of Concrete from Supersulfated Cement
p.615

HomeKey Engineering MaterialsKey Engineering Materials Vol. 711On the Structural Behavior of Reinforced Concrete...

On the Structural Behavior of Reinforced Concrete Walls Exposed to Fire

Abstract:

The present work deals with numerical simulations concerning the international benchmark “Vulcain tests on 3 Walls” regarding fire tests conducted in CSTB in Paris, France. To this aim, sequentially-coupled thermo-mechanical analyses have been performed on three reinforced concrete walls, characterized by different load levels and boundary conditions. The numerical results show that the imposed compressive load and boundary conditions significantly influence the magnitude of the displacements. In the case of simply supported walls, the wall with the lower load level exhibited a gradual and monotonic increase of the displacements at mid-height (both in the tests and in the numerical analyses), while the wall with the higher load level exhibited a displacement reversal due to second-order effects after approximately 60 minutes of fire exposure. This reversal, which was obtained in the analyses, was not observed in the test. Load bearing capacity of all the three specimen walls was maintained in such a way that the collapse did not take place during two hours of fire exposure.

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Periodical:

Key Engineering Materials (Volume 711)

Pages:

580-587

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.711.580

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Online since:

September 2016

Authors:

Patrick Bamonte*, Roberto Felicetti, Nataša Kalaba, Francesco Lo Monte, Nicholas Pinoteau, Md Jihad Miah, Pierre Pimienta

Keywords:

Fire, High Temperature, Transient Strain, Walls

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References

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