Affiliation:
1. Wuhan Hanyangzao Investment Development Co., Ltd., Wuhan 430050, China
2. School of Civil Engineering and Architecture, Wuhan University of Technology, Wuhan 430070, China
3. Wuhan Huike Quality Testing Co., Ltd., Wuhan 430050, China
4. Pearl River Water Resources Research Institute, Guangzhou 510611, China
Abstract
Reinforced concrete structures play a pivotal role in island and reef engineering projects. Given the resource constraints typical of island regions, substituting traditional manufactured sand aggregate with reef limestone not only reduces reliance on river sand but also addresses the issue of disposing of waste reef limestone slag generated during excavation. However, the performance characteristics of reef limestone concrete, particularly its bond strength with reinforcing steel, warrant further investigation. This is particularly true for the bond–slip behavior of the reinforcement. This study aims to elucidate the effects of various parameters on the bond performance between steel and reef limestone concrete through central pullout tests. These parameters include the type and diameter of the reinforcement, bond length, and loading rate. The investigation encompasses the analysis of load–slip curves, bond failure modes, and variations in bond stress. Additionally, using the Abaqus software, a numerical simulation was conducted to analyze the mesoscopic stress characteristics, thereby revealing the mechanisms of bond formation and failure modes between steel reinforcement and reef limestone concrete. The results indicate that the bond–slip curve for reef limestone concrete reinforced with ribbed rebars and Glass Fiber-Reinforced Polymer (GFRP) rebars can be broadly categorized into four phases: minor slip, slip, decline, and residual, with the residual phase exhibiting a wave-like pattern. The predominant failure modes in reef limestone concrete are either pulling out or splitting. The bond stress in reef limestone concrete decreases with an increase in rebar diameter and bond length; conversely, it increases with the loading rate, although the ultimate slip decreases. The mesoscopic failure characteristics of reinforced reef limestone concrete, as simulated in Abaqus, are consistent with the experimental outcomes.
Reference34 articles.
1. Engineering characteristics of coral reef and site assessment of hydraulic reclamation in the South China Sea;Wang;Constr. Build. Mater.,2021
2. Deshmukh, A.M., Gulhati, S.K., Roa, G.V., and Agarwal, S.L. (1985, January 12–16). Influence of Geological Aspects on Behaviour of Coral Rock. Proceedings of the 11th International Conference on soil Mechanics and Foundation Engineering, San Francisco, CA, USA.
3. Research on characteristics of coral reef calcareous rock in Nansha Islands;Wang;Chin. J. Rock Mech. Eng.,2008
4. Macroscopic and Mesoscopic Investigation on the Physical and Mechanical Characteristics of Coral Limestone at Different Depths;Ma;Geol. J. China Univ.,2023
5. Tests on dynamic properties of coral-reef limestone in South China Sea;Meng;Rock Soil Mech.,2019
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