Durability of an Ultra High Performance Fiber Reinforced Concrete (UHPFRC) under progressive aging

We assess the durability of an Ultra High Performance Fiber Reinforced Concrete (UHPFRC) after accelerated aging, i.e. after partial drying, or 105°C oven-drying (dry reference state), 200, 300 or 400°C heat-treatment, or progressive splitting (Brazilian test). Our key experimental tool is gas perme...

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Veröffentlicht in:	Cement and concrete research 2014-01, Vol.55, p.1-13
Hauptverfasser:	Wang, Wei, Liu, Jian, Agostini, Franck, Davy, Catherine A., Skoczylas, Frédéric, Corvez, Dominique
Format:	Artikel
Sprache:	eng
Schlagworte:	Aging (C) Applied sciences Bending strength (C) Brazil Buildings. Public works Cements Concretes Concretes. Mortars. Grouts Construction works Curing Drying ovens Durability Durability (C) Exact sciences and technology Fiber reinforced concretes Fiber reinforcement (E) Fibre reinforced concrete (including asbestos cement) Formworks Heat treatment High performance concrete (E) Materials Mortars Other special applications (sand concrete, roller compacted concrete, heavy concrete, architectural concrete, etc.) Permeability (C) Porosity Strength of materials (elasticity, plasticity, buckling, etc.) Structural analysis. Stresses Sustaining
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creator	Wang, Wei Liu, Jian Agostini, Franck Davy, Catherine A. Skoczylas, Frédéric Corvez, Dominique
description	We assess the durability of an Ultra High Performance Fiber Reinforced Concrete (UHPFRC) after accelerated aging, i.e. after partial drying, or 105°C oven-drying (dry reference state), 200, 300 or 400°C heat-treatment, or progressive splitting (Brazilian test). Our key experimental tool is gas permeability Kgas under varying confinement Pc, coupled to MIP and SEM analysis. UHPFRC properties are compared to standard mortar and ordinary concrete. Whereas usual UHPFRCs involve pozzolanic additions and thermal curing, this UHPFRC does not, and is significantly more porous (by 9–10%). However, 74% of its porosity comprises pores smaller than 4nm, i.e. located within the C–S–H. Dry reference state UHPFRC lies in the range of very high durable materials, with an average Kgas=10−18m2. Damage by heat-treatment at 400°C induces limited de-bonding at the fiber/paste interface, which increases Kgas up to 10−17m2 at Pc=6MPa. While sustaining more than 300μm/m tensile strain, Kgas of UHPFRC remains virtually identical. •Gas permeability is used to assess durability of a UHPFRC after accelerated aging.•Dry gas permeability of UHPFRC (10–18 m2) places it in the very high durability range.•400°C heat-treated UHPFRC displays limited de-bonding at the fiber/paste interface.•400°C heat-treated UHPFRC is still placed within very high durability range, Kgas= 10–17 m2.•Brazilian splitting leads to 360μm/m diametral strain, but low Kgas is preserved.
doi_str_mv	10.1016/j.cemconres.2013.09.008
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Our key experimental tool is gas permeability Kgas under varying confinement Pc, coupled to MIP and SEM analysis. UHPFRC properties are compared to standard mortar and ordinary concrete. Whereas usual UHPFRCs involve pozzolanic additions and thermal curing, this UHPFRC does not, and is significantly more porous (by 9–10%). However, 74% of its porosity comprises pores smaller than 4nm, i.e. located within the C–S–H. Dry reference state UHPFRC lies in the range of very high durable materials, with an average Kgas=10−18m2. Damage by heat-treatment at 400°C induces limited de-bonding at the fiber/paste interface, which increases Kgas up to 10−17m2 at Pc=6MPa. While sustaining more than 300μm/m tensile strain, Kgas of UHPFRC remains virtually identical. •Gas permeability is used to assess durability of a UHPFRC after accelerated aging.•Dry gas permeability of UHPFRC (10–18 m2) places it in the very high durability range.•400°C heat-treated UHPFRC displays limited de-bonding at the fiber/paste interface.•400°C heat-treated UHPFRC is still placed within very high durability range, Kgas= 10–17 m2.•Brazilian splitting leads to 360μm/m diametral strain, but low Kgas is preserved.</description><identifier>ISSN: 0008-8846</identifier><identifier>EISSN: 1873-3948</identifier><identifier>DOI: 10.1016/j.cemconres.2013.09.008</identifier><identifier>CODEN: CCNRAI</identifier><language>eng</language><publisher>Kidlington: Elsevier Ltd</publisher><subject>Aging (C) ; Applied sciences ; Bending strength (C) ; Brazil ; Buildings. Public works ; Cements ; Concretes ; Concretes. Mortars. 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Our key experimental tool is gas permeability Kgas under varying confinement Pc, coupled to MIP and SEM analysis. UHPFRC properties are compared to standard mortar and ordinary concrete. Whereas usual UHPFRCs involve pozzolanic additions and thermal curing, this UHPFRC does not, and is significantly more porous (by 9–10%). However, 74% of its porosity comprises pores smaller than 4nm, i.e. located within the C–S–H. Dry reference state UHPFRC lies in the range of very high durable materials, with an average Kgas=10−18m2. Damage by heat-treatment at 400°C induces limited de-bonding at the fiber/paste interface, which increases Kgas up to 10−17m2 at Pc=6MPa. While sustaining more than 300μm/m tensile strain, Kgas of UHPFRC remains virtually identical. •Gas permeability is used to assess durability of a UHPFRC after accelerated aging.•Dry gas permeability of UHPFRC (10–18 m2) places it in the very high durability range.•400°C heat-treated UHPFRC displays limited de-bonding at the fiber/paste interface.•400°C heat-treated UHPFRC is still placed within very high durability range, Kgas= 10–17 m2.•Brazilian splitting leads to 360μm/m diametral strain, but low Kgas is preserved.</description><subject>Aging (C)</subject><subject>Applied sciences</subject><subject>Bending strength (C)</subject><subject>Brazil</subject><subject>Buildings. Public works</subject><subject>Cements</subject><subject>Concretes</subject><subject>Concretes. Mortars. Grouts</subject><subject>Construction works</subject><subject>Curing</subject><subject>Drying ovens</subject><subject>Durability</subject><subject>Durability (C)</subject><subject>Exact sciences and technology</subject><subject>Fiber reinforced concretes</subject><subject>Fiber reinforcement (E)</subject><subject>Fibre reinforced concrete (including asbestos cement)</subject><subject>Formworks</subject><subject>Heat treatment</subject><subject>High performance concrete (E)</subject><subject>Materials</subject><subject>Mortars</subject><subject>Other special applications (sand concrete, roller compacted concrete, heavy concrete, architectural concrete, etc.)</subject><subject>Permeability (C)</subject><subject>Porosity</subject><subject>Strength of materials (elasticity, plasticity, buckling, etc.)</subject><subject>Structural analysis. 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Our key experimental tool is gas permeability Kgas under varying confinement Pc, coupled to MIP and SEM analysis. UHPFRC properties are compared to standard mortar and ordinary concrete. Whereas usual UHPFRCs involve pozzolanic additions and thermal curing, this UHPFRC does not, and is significantly more porous (by 9–10%). However, 74% of its porosity comprises pores smaller than 4nm, i.e. located within the C–S–H. Dry reference state UHPFRC lies in the range of very high durable materials, with an average Kgas=10−18m2. Damage by heat-treatment at 400°C induces limited de-bonding at the fiber/paste interface, which increases Kgas up to 10−17m2 at Pc=6MPa. While sustaining more than 300μm/m tensile strain, Kgas of UHPFRC remains virtually identical. •Gas permeability is used to assess durability of a UHPFRC after accelerated aging.•Dry gas permeability of UHPFRC (10–18 m2) places it in the very high durability range.•400°C heat-treated UHPFRC displays limited de-bonding at the fiber/paste interface.•400°C heat-treated UHPFRC is still placed within very high durability range, Kgas= 10–17 m2.•Brazilian splitting leads to 360μm/m diametral strain, but low Kgas is preserved.</abstract><cop>Kidlington</cop><pub>Elsevier Ltd</pub><doi>10.1016/j.cemconres.2013.09.008</doi><tpages>13</tpages></addata></record>
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subjects	Aging (C) Applied sciences Bending strength (C) Brazil Buildings. Public works Cements Concretes Concretes. Mortars. Grouts Construction works Curing Drying ovens Durability Durability (C) Exact sciences and technology Fiber reinforced concretes Fiber reinforcement (E) Fibre reinforced concrete (including asbestos cement) Formworks Heat treatment High performance concrete (E) Materials Mortars Other special applications (sand concrete, roller compacted concrete, heavy concrete, architectural concrete, etc.) Permeability (C) Porosity Strength of materials (elasticity, plasticity, buckling, etc.) Structural analysis. Stresses Sustaining
title	Durability of an Ultra High Performance Fiber Reinforced Concrete (UHPFRC) under progressive aging
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