[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.1007/s40069-015-0118-3

Effect of Wet Curing Duration on Long-Term Performance of Concrete in Tidal Zone of Marine Environment

Khanzadeh-Moradllo, Mehdi (School of Civil Engineering, Construction Materials Institute, University of Tehran)
Meshkini, Mohammad H. (School of Civil Engineering, Construction Materials Institute, University of Tehran)
Eslamdoost, Ehsan (School of Civil Engineering, Construction Materials Institute, University of Tehran)
Sadati, Seyedhamed (Civil, Architecture, and Environmental Engineering Department, Missouri University of Science and Technology)
Shekarchi, Mohammad (School of Civil Engineering, Construction Materials Institute, University of Tehran)

Publication Information

International Journal of Concrete Structures and Materials / v.9, no.4, 2015 , pp. 487-498 More about this Journal

Abstract

A proper initial curing is a very simple and inexpensive alternative to improve concrete cover quality and accordingly extend the service life of reinforced concrete structures exposed to aggressive species. A current study investigates the effect of wet curing duration on chloride penetration in plain and blended cement concretes which subjected to tidal exposure condition in south of Iran for 5 years. The results show that wet curing extension preserves concrete against high rate of chloride penetration at early ages and decreases the difference between initial and long-term diffusion coefficients due to improvement of concrete cover quality. But, as the length of exposure period to marine environment increased the effects of initial wet curing became less pronounced. Furthermore, a relationship is developed between wet curing time and diffusion coefficient at early ages and the effect of curing length on time-to-corrosion initiation of concrete is addressed.

Keywords

curing; diffusion; chloride; silica fume; service life; durability;

Citations & Related Records

Times Cited By KSCI : 4 (Citation Analysis)

Reference
Cited By KSCI

1	ACI Committee 308. (1998). Recommended practice for curing concrete. Farmington Hills, MI: MCP, American Concrete Institute.
2	Al-Amoudi, O. S. B., Maslehuddin, M., & Bader, M. A. (2001). Characteristics of silica fume and its impacts on concrete in the Arabian Gulf. Concrete, 35(2), 45-50 (London, UK).
3	Alizadeh, R., Ghods, P., Chini, M., Hoseini, M., Ghalibafian, M., & Shekarchi, M. (2008). Effect of curing conditions on the service life design of RC structures in the Persian Gulf Region. Journal of Materials in Civil Engineering, 20, 2-8. DOI
4	Ann, K. Y., Ahn, J. H., & Ryou, J. S. (2009). The importance of chloride content at the concrete surface in assessing the time to corrosion of steel in concrete structures. Journal of Construction and Building Materials, 23(1), 239-245. DOI
5	Atis, C. D., Ozcan, F., Kilic, A., Karahan, O., Bilim, C., & Severcan, M. H. (2005). Influence of dry and wet curing conditions on compressive strength of silica fume concrete. Building and Environment Journal, 40, 1678-1683. DOI
6	Beaudoin, J. J., Ramachandran, V. S., & Feldman, R. F. (1990). Interaction of chloride and CSH. Cement and Concrete Research, 20(6), 875-883. DOI
7	Bonavetti, V., Donza, H., Rahhal, V., & Irassar, E. (2000). Influence of initial curing on the properties of concrete containing limestone blended cement. Journal of Cement and Concrete Research, 30, 703-708. DOI
8	Crank, J. (1975). The mathematics of diffusion (2nd ed.). London, UK: Oxford.
9	Dousti, A., Shekarchi, M., Alizadeh, R., & Taheri-Motlagh, A. (2011). Binding of externally supplied chlorides in micro silica concrete under field exposure conditions. Cement & Concrete Composites, 33(10), 1071-1079. DOI
10	Ghassemzadeh, F., Shekarchi, M., Sajedi, S., Khanzadeh-Moradllo, M., & Sadati, H. (2010). Effect of silica fume and GGBS on shrinkage in the high performance concrete. In Proceedings of the sixth international conference on concrete under severe conditions: environment and loading, Yucatan, Mexico (pp. 1007-1012).
11	Ghassemzadeh, F., Shekarchi, M., Sajedi, S., Mohebbi, M. J. & Khanzadeh-Moradllo, M. (2011). Performance of repair concretes in marine environments. In Proceedings of the annual conference canadian society for civil Engineering (pp. 1654-1664). Ottawa, Canada.
12	Guneyisi, E., Ozturan, T., & Gesoglu, M. (2007). Effect of initial curing on chloride ingress and corrosion resistance characteristics of concretes made with plain and blended cements. Journal of Building and Environment, 42, 2676-2685. DOI
13	Glass, G. K., & Buenfeld, N. R. (2000). The influence of chloride binding on the chloride induced corrosion risk in reinforced concrete. Journal of Corrosion Science., 42, 329-344. DOI
14	Guneyisi, E., Gesoglu, M., Ozturan, T., & Ozbay, E. (2009). Estimation of chloride permeability of concretes by empirical modeling: Considering effects of cement type, curing condition and age. Journal of Construction and Building Materials, 23, 469-481. DOI
15	Guneyisi, E., Ozturan, T., & Gesoglu, M. (2005). A study on reinforcement corrosion and related properties of plain and blended cement concretes under different curing conditions. Journal of Cement and Concrete Composites, 27, 449-461. DOI
16	Khanzadeh-Moradllo, M., Ghassemzadeh, F., Shekarchi, M., Mosadarolom, A., & Roujei, H. (2009). Effect of curing conditions on chloride diffusion into the concrete structures in Persian Gulf region. In Proceedings of the 4th international conference on construction materials: performance, innovations and structural implications, Nagoya, Japan (pp. 703-708).
17	Khanzadeh-Moradllo, M., Shekarchi, M., & Hoseini, M. (2012). Time-dependent performance of concrete surface coatings in tidal zone of marine environment. Journal of Construction and Building Materials, 30, 198-205. DOI
18	Khatib, J. M. (2014). Effect of initial curing on absorption and pore size distribution of paste and concrete containing slag. KSCE Journal of Civil Engineering, 18(1), 264-272. DOI
19	Luping, T., & Nilsson, L. O. (1993). Chloride binding capacity and binding isotherms of OPC pastes and mortars. Cement and Concrete Research, 23(2), 247-253. DOI
20	Khatib, J. M., & Mangat, P. S. (2002). Influence of high-temperature and low-humidity curing on chloride penetration in blended cement concrete. Journal of Cement and Concrete Research, 32, 1743-1753. DOI
21	Mangat, P. S., & Limbachiya, M. C. (1999). Effect of initial curing on chloride diffusion in concrete repair materials. Journal of Cement and Concrete Research, 29, 1475-1485. DOI
22	Mohammed, T. U., Hamada, H., & Yamaji, T. (2004). Concrete after 30 years of exposure? Part II: Chloride ingress and corrosion of steel bars. ACI Materials Journal, 101(1), 13-18.
23	Mohammed, T. U., Yamaji, T., & Hamada, H. (2002). Chloride diffusion, microstructure, and mineralogy of concrete after 15 years of exposure in tidal environment. ACI Materials Journal, 99(3), 256-263.
24	Morga, M., & Marano, G. C. (2015). Chloride penetration in circular concrete columns. International Journal of Concrete Structures and Materials, 9(2), 1-11. DOI
25	Neville, A. (2000). Good reinforced concrete in the Arabian Gulf. Journal of Materials and Structures, 33, 655-664. DOI
26	Neville, A. M., & Brooks, J. (1990). Concrete technology. Singapore, Singapore: Longman Scientific and Technical.
27	Pargar, F., Layssi, H., & Shekarchi, M. (2007). Investigation on chloride threshold value in an old concrete structure. In Proceeding of the fifth international conference on concrete under severe conditions, CONSEC'07, Tours, France (pp. 175-182).
28	Pritzl, M. D., Tabatabai, H., & Ghorbanpoor, A. (2014). Laboratory evaluation of select methods of corrosion prevention in reinforced concrete bridges. International Journal of Concrete Structures and Materials, 8(3), 201-212. DOI
29	Perenchio, W. F. (1997). The drying shrinkage dilemma. Concrete Construction, 42, 379-383.
30	Powers, T. C., Copeland, L. E., & Mann, H. M. (1959). Capillary continuity or discontinuity in cement pastes. Journal of Portland Cement Association, Research and Development Laboratories, 1(2), 38-48.
31	Radlinska, A., McCarthy, L. M., Matzke, J., & Nagel, F. (2014). Synthesis of DOT use of beam end protection for extending the life of bridges. International Journal of Concrete Structures and Materials, 8(3), 185-199. DOI
32	Radlinski, M., & Olek, J. (2015). Effects of curing conditions on the properties of ternary (ordinary portland cement/fly ash/silica fume) concrete. ACI Materials Journal, 112(1), 49-58.
33	Sadati, S., Arezoumandi, M., & Shekarchi, M. (2015). Longterm performance of concrete surface coatings in soil exposure of marine environments. Construction and Building Materials, 94, 656-663. DOI
34	Shamim Khan, M., & Ayers, M. E. (1993). Curing requirements of silica fume and fly ash mortars. Journal of Cement and Concrete Research, 23, 1480-1490. DOI
35	Shekarchi, M., Rafiee, A., & Layssi, H. (2009). Long-term chloride diffusion in silica fumes concrete in harsh marine climates. Journal of Cement and Concrete Composites, 31(10), 769-775. DOI
36	Thomas, M. D. A. (1991). Marine performance of PFA concrete. Magazine of Concrete Research, 43(151), 171-185. DOI
37	Song, H. W., Lee, C. H., & Ann, K. Y. (2008). Factors influencing chloride transport in concrete structures exposed to marine environments. Journal of Cement and Concrete Composites, 30(1), 113-121. DOI
38	Swamy, R. N. (1988). Durability of steel reinforcement in marine environment. In Proceedings of the 2nd international conference on concrete in marine environment, St. Andrews By-The-Sea, Canada (pp. 147-161).
39	The European Union, Brite EuRam III, DuraCrete R17. (2000). Probabilistic performance based durability design of concrete structures, includes general guidelines for durability design and redesign. DuraCrete Final Technical Report, Document BE95-1347/R17.
40	Thomas, M. (1996). Chloride thresholds in marine concrete. Cement and Concrete Research, 26(4), 513-519. DOI
41	Thomas, M. D. A., Matthews, J. D., & Haynes C. A. (1990). Chloride diffusion and reinforcement corrosion in marine exposed concretes containing pulverized-fuel ash. In C. L. Page, K. W. J. Treadaway & P. B. Bamforth (Eds.), Proceedings of the third international symposium on corrosion of reinforcement in concrete construction, Garston, UK (pp. 198-212).
42	Toutanji, H. A., & Bayasi, Z. (1999). Effect of curing procedures on properties of silica fume concrete. Journal of Cement and Concrete Research, 29, 497-501. DOI
43	Zhang, M. H., Bilodeau, A., Malhotra, V. M., Kim, K. S., & Kim, J. C. (1999). Concrete incorporating supplementary cementing materials: Effect on compressive strength and resistance to chloride-ion penetration. ACI Materials Journal, 96(2), 181-189.

None	(2015) Construction & building materials Quantitative measurement of the influence of degree of saturation on ion penetration in cement paste by using X-ray imaging / 141 (None) , 113
None	(2015) Cement & concrete composites Comparing ion diffusion in alternative cementitious materials in real time by using non-destructive X-ray imaging / 82 (None) , 67
3	(2015) ASCE-ASME journal of risk and uncertainty in engineering systems. Part A, Civil Engineering Reliability-Based Multiobjective Design Optimization of Reinforced Concrete Bridges Considering Corrosion Effect / 3 (3) , 04016015
5	(2015) Magazine of concrete research A study on the effect of curing temperature and duration on rebar corrosion / 70 (5) , 260
2	(2015) Journal of materials in civil engineering / Edit by American Society of Civil Engineers Differences between Time-Dependent Instantaneous and Apparent Chloride Diffusion Coefficients of Concrete in Tidal Environment / 33 (2) , 04020466
3	(2015) European journal of environmental and civil engineering Ingress of chloride ions with carbonation: parameter estimation and analytical simplification / 25 (3) , 387
1	(2021) IOP conference series : Earth and environmental science Diffusion of chloride from seawater into the concrete analysis: a literature review on implemented approaches / 930 (1) , 012015