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Bond degradation of basalt fiber-reinforced polymer (BFRP) bars exposed to accelerated aging conditions
Highlights Durability of conditioned basalt and glass FRP bars was investigated. Parameters included the exposure type and duration. Basalt bars showed excellent adhesion and bond strengths to concrete. Conditioning reduced the bond strength of basalt bars by 14–25%. BPE model was calibrated to consider the bar conditioning.
Abstract Bond durability of sand-coated basalt fiber-reinforced polymer (BFRP) bars was investigated. Pullout specimens were tested under direct tensile load after being exposed to accelerated conditioning environments. The test parameters included the bar material (basalt and glass), the conditioning environment (acid, saline, and alkaline), and the duration of exposure (30, 60, and 90days). The bond behavior of the tested specimens was reported in terms of stress–slip response, bond strength, bar slip, adhesion, and failure mechanism. The BFRP bars showed higher adhesion and bond strengths to concrete than the ribbed glass fiber-reinforced polymer (GFRP) bars irrespective of the fiber type and the exposure condition. The absorption of the bar material and its quality of manufacturing affected the bond behavior of the conditioned specimens. All specimens failed in pullout mode by inter-laminar shear between the layers of the bar. Conditioning reduced the bond strength of the BFRP bars by 14–25% of their initial strength. Ribbed GFRP specimens subjected to acid exposure suffered the highest loss in bond strength (25%) compared to 17% for GFRP specimens exposed to alkaline and ocean water. Conditioning had insignificant influence on the slip of the bars.
Bond degradation of basalt fiber-reinforced polymer (BFRP) bars exposed to accelerated aging conditions
Highlights Durability of conditioned basalt and glass FRP bars was investigated. Parameters included the exposure type and duration. Basalt bars showed excellent adhesion and bond strengths to concrete. Conditioning reduced the bond strength of basalt bars by 14–25%. BPE model was calibrated to consider the bar conditioning.
Abstract Bond durability of sand-coated basalt fiber-reinforced polymer (BFRP) bars was investigated. Pullout specimens were tested under direct tensile load after being exposed to accelerated conditioning environments. The test parameters included the bar material (basalt and glass), the conditioning environment (acid, saline, and alkaline), and the duration of exposure (30, 60, and 90days). The bond behavior of the tested specimens was reported in terms of stress–slip response, bond strength, bar slip, adhesion, and failure mechanism. The BFRP bars showed higher adhesion and bond strengths to concrete than the ribbed glass fiber-reinforced polymer (GFRP) bars irrespective of the fiber type and the exposure condition. The absorption of the bar material and its quality of manufacturing affected the bond behavior of the conditioned specimens. All specimens failed in pullout mode by inter-laminar shear between the layers of the bar. Conditioning reduced the bond strength of the BFRP bars by 14–25% of their initial strength. Ribbed GFRP specimens subjected to acid exposure suffered the highest loss in bond strength (25%) compared to 17% for GFRP specimens exposed to alkaline and ocean water. Conditioning had insignificant influence on the slip of the bars.
Bond degradation of basalt fiber-reinforced polymer (BFRP) bars exposed to accelerated aging conditions
Altalmas, Ahmad (author) / El Refai, Ahmed (author) / Abed, Farid (author)
Construction and Building Materials ; 81 ; 162-171
2015-02-18
10 pages
Article (Journal)
Electronic Resource
English
Accelerated aging , Basalt , Fiber-reinforced polymers , Pullout , Bond , Durability , Glass , Tensile , Concrete
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