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Experimental Behavior of GFRP Bar-Reinforced CFRP Strip Tie-Confined Normal-Strength Concrete Columns under Different Loading Conditions

journal contribution
posted on 2024-11-17, 15:53 authored by Muhammad Ayoub, Hayder Alaa Hasan, M Neaz Sheikh, Muhammad NS Hadi
In this study, a total of 10 steel and glass fiber-reinforced polymer (GFRP) bar-reinforced normal strength concrete (NSC) specimens with a square cross section of 200 mm × 200 mm were experimentally tested up to failure under different loading conditions. Out of the 10 specimens, 8 specimens had a height of 800 mm and were tested as columns under concentric and eccentric axial loads. The remaining two specimens had a length of 1,500 mm and were tested as beams under four-point bending. The tested specimens were utilized to investigate the efficiency of carbon fiber-reinforced polymer (CFRP) strip ties (CSTs) in transversely confining NSC specimens. Two configurations of CSTs were used: a square (S) configuration and a square overlapping square (SS) configuration. The experimental results indicated that the peak axial load and ductility of the concentrically loaded GFRP bar-reinforced concrete specimens were lower than those of steel bar-reinforced specimens. The peak axial load and ductility of the concentrically loaded GFRP bar-reinforced concrete specimens with SS configuration were about 49% and 100%, respectively, higher than those of GFRP bar-reinforced concrete specimens with S configuration. Also, the GFRP bar-reinforced concrete specimens tested under eccentric loading and four-point bending achieved higher peak axial loads, flexural loads, and bending moments at the second peak loads than the corresponding steel bar-reinforced specimens.

History

Journal title

Journal of Composites for Construction

Volume

27

Issue

2

Language

English

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