Effect of flexure induced transverse crack and self-healing on chloride diffusivity of reinforced mortar
Cracks in reinforced concrete are unavoidable. Durability is of increasing concern in the concrete industry, and it is significantly affected by the presence of cracks. The corrosion of reinforcing steel due to chloride ions in deicing salts or sea-water is a major cause of premature deterioration o...
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| Published in | Journal of materials science Vol. 42; no. 22; pp. 9131 - 9136 |
|---|---|
| Main Author | |
| Format | Journal Article |
| Language | English |
| Published |
Heidelberg
Springer
01.11.2007
Springer Nature B.V |
| Subjects | |
| Online Access | Get full text |
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| Abstract | Cracks in reinforced concrete are unavoidable. Durability is of increasing concern in the concrete industry, and it is significantly affected by the presence of cracks. The corrosion of reinforcing steel due to chloride ions in deicing salts or sea-water is a major cause of premature deterioration of reinforced concrete structures. Although, it is generally recognized that cracks accelerate the ingress of chlorides in concrete, a lack of consensus on this subject does not yet allow reliable quantification of their effects. The present work studies the relationship between crack widths and chloride diffusivity. Flexural load was introduced to generate cracks of width ranging between 29 and 390 μm. As crack width was increased, the effective diffusion coefficient was also increased, thus reducing the initiation period of corrosion process. For cracks with widths less than 135 μm, the effect of crack widths on the effective diffusion coefficient of mortar was found to be marginal, whereas for crack widths higher than 135 μm the effective diffusion coefficient increased rapidly. Therefore, the effect of crack width on chloride penetration was more pronounced when the crack width is higher than 135 μm. Results also indicate that the relation between the effective diffusion coefficient and crack width was found to be power function. In addition, a significant amount of self-healing was observed within the cracks with width below 50 μm subjected to NaCl solution exposure. The present research may provide insight into developing design criteria for a durable concrete and in predicting service life of a concrete structures. |
|---|---|
| AbstractList | Cracks in reinforced concrete are unavoidable. Durability is of increasing concern in the concrete industry, and it is significantly affected by the presence of cracks. The corrosion of reinforcing steel due to chloride ions in deicing salts or sea-water is a major cause of premature deterioration of reinforced concrete structures. Although, it is generally recognized that cracks accelerate the ingress of chlorides in concrete, a lack of consensus on this subject does not yet allow reliable quantification of their effects. The present work studies the relationship between crack widths and chloride diffusivity. Flexural load was introduced to generate cracks of width ranging between 29 and 390 μm. As crack width was increased, the effective diffusion coefficient was also increased, thus reducing the initiation period of corrosion process. For cracks with widths less than 135 μm, the effect of crack widths on the effective diffusion coefficient of mortar was found to be marginal, whereas for crack widths higher than 135 μm the effective diffusion coefficient increased rapidly. Therefore, the effect of crack width on chloride penetration was more pronounced when the crack width is higher than 135 μm. Results also indicate that the relation between the effective diffusion coefficient and crack width was found to be power function. In addition, a significant amount of self-healing was observed within the cracks with width below 50 μm subjected to NaCl solution exposure. The present research may provide insight into developing design criteria for a durable concrete and in predicting service life of a concrete structures. The relationship between crack widths and chloride diffusivity was studied. Flexural load was introduced to generate cracks with widths ranging between 29 and 390 micron. As the crack width increased, the effective diffusion coefficient also increased, thus reducing the initiation period of the corrosion process. For cracks with widths < 135 micron, the effect of crack widths on the effective diffusion coefficient of mortar was marginal, whereas for crack widths > 135 micron, the effective diffusion coefficient increased rapidly. Therefore, the effect of crack width on chloride penetration was more pronounced when the crack width was > 135 micron. Results indicated that the relation between the effective diffusion coefficient and crack width was a power function. A significant amount of self-healing was observed within the cracks with widths < 50 micron subjected to NaCl solution exposure. This research may provide insight into developing design criteria for a durable concrete and in predicting the service life of concrete structures. 25 refs. Cracks in reinforced concrete are unavoidable. Durability is of increasing concern in the concrete industry, and it is significantly affected by the presence of cracks. The corrosion of reinforcing steel due to chloride ions in deicing salts or sea-water is a major cause of premature deterioration of reinforced concrete structures. Although, it is generally recognized that cracks accelerate the ingress of chlorides in concrete, a lack of consensus on this subject does not yet allow reliable quantification of their effects. The present work studies the relationship between crack widths and chloride diffusivity. Flexural load was introduced to generate cracks of width ranging between 29 and 390 km. As crack width was increased, the effective diffusion coefficient was also increased, thus reducing the initiation period of corrosion process. For cracks with widths less than 135 km, the effect of crack widths on the effective diffusion coefficient of mortar was found to be marginal, whereas for crack widths higher than 135 km the effective diffusion coefficient increased rapidly. Therefore, the effect of crack width on chloride penetration was more pronounced when the crack width is higher than 135 km. Results also indicate that the relation between the effective diffusion coefficient and crack width was found to be power function. In addition, a significant amount of self-healing was observed within the cracks with width below 50 km subjected to NaCl solution exposure. The present research may provide insight into developing design criteria for a durable concrete and in predicting service life of a concrete structures. Cracks in reinforced concrete are unavoidable. Durability is of increasing concern in the concrete industry, and it is significantly affected by the presence of cracks. The corrosion of reinforcing steel due to chloride ions in deicing salts or sea-water is a major cause of premature deterioration of reinforced concrete structures. Although, it is generally recognized that cracks accelerate the ingress of chlorides in concrete, a lack of consensus on this subject does not yet allow reliable quantification of their effects. The present work studies the relationship between crack widths and chloride diffusivity. Flexural load was introduced to generate cracks of width ranging between 29 and 390 mum. As crack width was increased, the effective diffusion coefficient was also increased, thus reducing the initiation period of corrosion process. For cracks with widths less than 135 mum, the effect of crack widths on the effective diffusion coefficient of mortar was found to be marginal, whereas for crack widths higher than 135 mum the effective diffusion coefficient increased rapidly. Therefore, the effect of crack width on chloride penetration was more pronounced when the crack width is higher than 135 mum. Results also indicate that the relation between the effective diffusion coefficient and crack width was found to be power function. In addition, a significant amount of self-healing was observed within the cracks with width below 50 mum subjected to NaCl solution exposure. The present research may provide insight into developing design criteria for a durable concrete and in predicting service life of a concrete structures. |
| Author | Şahmaran, Mustafa |
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| Cites_doi | 10.1007/BF02480672 10.1016/0008-8846(87)90002-0 10.1016/S0008-8846(02)01099-2 10.1680/macr.1999.51.2.143 10.1061/(ASCE)0899-1561(1999)11:3(181) 10.1016/S0008-8846(00)00216-7 |
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| Keywords | Experimental result Corrosion Chlorides Construction materials Experimental study Reinforced mortar Diffusivity Crack |
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| Snippet | Cracks in reinforced concrete are unavoidable. Durability is of increasing concern in the concrete industry, and it is significantly affected by the presence... The relationship between crack widths and chloride diffusivity was studied. Flexural load was introduced to generate cracks with widths ranging between 29 and... |
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| SubjectTerms | Applied sciences Buildings. Public works Chloride Chloride ions Chlorides Concrete Concrete industry Concrete structures Concretes Concretes. Mortars. Grouts Corrosion Corrosion effects Crack initiation Cracks deicing agents Deicing salt Diffusion Diffusion coefficient Diffusivity Durability Durability. Pathology. Repairing. Maintenance Exact sciences and technology Flexing industry ions Life prediction Materials Materials science Mortars Mortars (material) prediction Reinforced concrete Reinforcing steels Seawater Self healing materials Service life sodium chloride steel Steel structures Stress corrosion cracking |
| Title | Effect of flexure induced transverse crack and self-healing on chloride diffusivity of reinforced mortar |
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