Experimental Investigation of the In-Plane Cyclic Behavior of Hybrid GFRP-Steel Reinforced Squat Shear Walls
Amer, O., Saad, M., Haggag, H., Ali, A. (2025). Experimental Investigation of the In-Plane Cyclic Behavior of Hybrid GFRP-Steel Reinforced Squat Shear Walls. EKB Journal Management System, 184(2), 197-214. doi: 10.21608/erj.2025.341951.1154
Osama Amer; Mohamed Saad; Hesham Haggag; Ahmed H. Ali. "Experimental Investigation of the In-Plane Cyclic Behavior of Hybrid GFRP-Steel Reinforced Squat Shear Walls". EKB Journal Management System, 184, 2, 2025, 197-214. doi: 10.21608/erj.2025.341951.1154
Amer, O., Saad, M., Haggag, H., Ali, A. (2025). 'Experimental Investigation of the In-Plane Cyclic Behavior of Hybrid GFRP-Steel Reinforced Squat Shear Walls', EKB Journal Management System, 184(2), pp. 197-214. doi: 10.21608/erj.2025.341951.1154
Amer, O., Saad, M., Haggag, H., Ali, A. Experimental Investigation of the In-Plane Cyclic Behavior of Hybrid GFRP-Steel Reinforced Squat Shear Walls. EKB Journal Management System, 2025; 184(2): 197-214. doi: 10.21608/erj.2025.341951.1154

Experimental Investigation of the In-Plane Cyclic Behavior of Hybrid GFRP-Steel Reinforced Squat Shear Walls

Engineering Research Journal
Volume 184, Issue 2, March 2025, Page 197-214  XML PDF (2.76 MB)
Document Type: Original Article
DOI: 10.21608/erj.2025.341951.1154
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Authors
Osama Amer email orcid 1; Mohamed Saad2; Hesham Haggag3; Ahmed H. Aliorcid 4
1Cairo University
2Helwan University - Faculty of Engineering - Department of Civil Engineering - Egypt
3Department of Civil Engineering, Faculty of Engineering - Helwan University
4Department of of Civil Engineering at Helwan University, Cairo, Egypt
Abstract
The susceptibility of steel reinforcement to corrosion undermines the durability of reinforced concrete (RC) elements in aggressive environments. Glass Fiber Reinforced Polymer (GFRP) bars, with superior corrosion resistance and strength-to-weight efficiency, emerge as an optimal substitute. Yet, their cyclic seismic performance remains insufficiently examined. This research investigates the hysteretic behavior of squat GFRP-RC shear walls, hybrid GFRP-steel, and traditional steel bars. Six full-scale wall specimens—two GFRP-reinforced, two hybrid GFRP-steel, and two steel-reinforced controls—underwent quasi-static cyclic lateral loading. Hybrid GFRP-steel walls demonstrated hysteretic stability with negligible residual drift, augmented by boundary elements which significantly bolstered lateral strength and mitigated residual deformations. Furthermore, these walls surpassed their GFRP-only counterparts in energy dissipation efficacy and deformation adaptability, underscoring their advanced seismic resilience in corrosive settings and the critical structural role of boundary elements. This study provides pivotal experimental insights, advocating the integration of GFRP as a viable replacement for steel reinforcement in seismic design, particularly in contexts where corrosion resistance is paramount.
Keywords
Reinforced concrete; Seismic performance; Cyclic in-plane test; RC squat shear wall; Glass Fibre-Reinforced Polymer (GFRP) bars
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