Effects of the Hygrothermal Conditions on the Fracture Energy of the Concrete

Hatem Kallel; Hélène Carré; Christian La Borderie; Benoît Masson; Nhu Cuong Tran

doi:10.4028/www.scientific.net/KEM.711.397

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Chloride Distribution Feature in Surface Layer of Cement Paste under Cyclic Drying-Wetting Condition
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Chloride Proofing Performance and Rebar Corrosion Protection Performance of SHCC Having Bending Cracks
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Influence of Seawater in Strengths of Concrete Mix Design when Used in Mixing and Curing
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Lessons Learned from the Treat Island Marine Exposure Site
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Effects of the Hygrothermal Conditions on the Fracture Energy of the Concrete
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Experimental Study on Temperature Response in Damaged Concrete under Atmospheric Environment
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UHPC and FRC in Severe Environmental Conditions
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High Absorptive Normal Weight Aggregates Used as Internal Curing Agents to Reduce Hot Weather Concreting and Curing Detrimental Effects
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Durability of Ordinary Concrete after Heating at High Temperature
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 711Effects of the Hygrothermal Conditions on the...

Effects of the Hygrothermal Conditions on the Fracture Energy of the Concrete

Abstract:

The scenario of a severe accident in the containment building of a nuclear plant results in an increase in pressure, temperature and relative humidity that can reach respectively 5 bars, 140 °C and the saturation of water vapour. As well as the regulatory calculations, accurate knowledge of the thermal and mechanical behaviour of materials and more specifically of concrete is required to carry out more precise numerical simulations. Our study aims to investigate the mechanical behaviour of concrete under homogeneous conditions of moisture and temperature. An experimental apparatus was designed in order to assess the evolutions of the fracture energy of concrete. Different temperature levels up to a maximum of 110 °C and at different values of the controlled moisture content were investigated. The equipment was used to perform DCT (Disk-shape Compact Tension) tests at 30, 90 and 110 °C. Five levels of degree of liquid water saturation (S_w) were investigated for each temperature level.

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Periodical:

Key Engineering Materials (Volume 711)

Pages:

397-403

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.711.397

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Online since:

September 2016

Authors:

Hatem Kallel, Hélène Carré, Christian La Borderie, Benoît Masson, Nhu Cuong Tran

Keywords:

Concrete, Fracture Energy, Pressure, Temperature, Water Content

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