Punching shear repairing of two-way solid slab subjected to high temperature using CFRP rope considering different configurations

Punching shear repairing of two-way solid slab subjected to high temperature using CFRP rope considering different configurations

Flat slabs are increasingly utilized in multi-story structures, including office buildings and parking facilities. However, the necessity for punching shear reinforcement arises due to factors such as design deficiencies, fire exposure, non-compliance with updated codes, or increased vertical loadin...

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Bibliographic Details
Main Authors: Ahmed M. Ashteyat, Ala’ Taleb Obaidat, Ibrahim Al Hazmi, Ahmad Al-Khreisat
Format: Article
Language:English
Published: Taylor & Francis Group 2025-02-01
Series:Journal of Asian Architecture and Building Engineering
Subjects:
two-way slab
near surface mounted
carbon fiber rope
punching shear
Online Access:http://dx.doi.org/10.1080/13467581.2025.2465819
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Summary:Flat slabs are increasingly utilized in multi-story structures, including office buildings and parking facilities. However, the necessity for punching shear reinforcement arises due to factors such as design deficiencies, fire exposure, non-compliance with updated codes, or increased vertical loading. This study examines the behavior of nine two-way slabs (1050 × 1050 × 70 mm) supported by steel plate columns (150 × 150 × 50 mm). Seven slabs were heated to 600 °C for 3 hours. Six of these slabs were then rehabilitated using near-surface mounted carbon fiber reinforced polymer (NSM-CFRP) ropes and strips, applied in different configurations (orthogonal and radial). Results indicated that thermal exposure led to a significant reduction in ultimate load capacity, up to 48%, increased deflection, and enhanced ductility relative to the control. The incorporation of NSM-CFRP ropes enhanced the ultimate capacity by 11% to 54% compared to the thermally damaged specimens. The most effective configuration involved a single rope in an orthogonal layout, which showed an increase in the ultimate capacity by 30%, while additional ropes provided no significant capacity gain, likely due to reduced effectiveness from close spacing. A finite element model developed in ABAQUS showed strong agreement with experimental data, offering valuable insights for optimizing reinforcement strategies in flat slab construction.
ISSN:1347-2852

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