References
- ASTM C 876. (1991). Standard Test Method for Half-Cell Potentials of Uncoated Reinforcing Steel in Concrete, American Society for Testing and Materials.
- ASTM D 1141. (1998). Standard Practice for the Preparation of Substitute Ocean Water, American Society for Testing and Materials.
- Bae, S.H., Lee, K.M,, Kim. J.S., and Kim, Y.S. (2007). Estimation of Critical Chloride Content for Corrosion of Reinforcing Steel in Concrete by Accelerated Corrosion Tests, Journal of the Korean Society of Civil Engineers, 27(5), 771-776 [in Korean].
- Bae, S.H., Park, J.I., Lee, K.M., and Choi, S. (2009). Influence of Mineral Admixtures on the Diffusion Coefficient for Chloride Ion in Concrete, Journal of the Korean Society of Civil Engineers, 29(4), 347-353 [in Korean].
- Jung, S.H., Choi, Y.C., Moon, K.D., and Choi, Y.J. (2012). "Development of green construction materials utilizing high volume coal combustion products," Proceedings of the Korean Recycled Construction Resource Institute, 12(1), 169-172 [in Korean].
- Kim, Y.J., Lee, S.S., Kim, D.S., and Yoo, J.K. (2004). Effect of the Kinds and Replacement Ratio of Mineral Admixtures on the Development of Concrete Resistance against the Penetration of Chloride Ions, Journal of Korea Concrete Institute, 16(3), 319-326 [in Korean]. https://doi.org/10.4334/JKCI.2004.16.3.319
- Korea Concrete Institute. (2009). Standard Concrete Specification. Korea Concrete Institute.
- KS F 2405. (2010). Standard test method for compressive strength of concrete, Korean Standards Association.
- Kwon, S.O. (2013). Comparative Analysis on Experimental Method of Diffusion Coefficient for Chloride Ion in Concrete, M.S. thesis, Andong National University, Korea.
- Kwon, S.O., Bae, S.H., Goo, M.S., and Lee, H.J. (2013a). "Resistance Estimation against Chloride Attack of High Volume Fly Ash Concrete," Proceedings of the Korean Recycled Construction Resource Institute, 13(1), 110-113 [in Korean].
- Kwon, S.O., Bae, S.H., Goo, M.S., Lee, H.J., and Jung, S.H. (2013b). "Comparative Evaluation for Resistance to Chloride Attack of High Volume Fly Ash and Plain Concrete according to Strength Level," Proceedings of the Korean Recycled Construction Resource Institute, 13(2), 15-18 [in Korean].
- Kwon, S.O., Bae, S.H., Goo, M.S., Lee, H.J., and Jung, S.H. (2013c). "Resistance Evaluation to Reinforcement Corrosion and Chloride Ion Penetration of High Volume Fly Ash Concrete," Proceedings of the Korean Society of Civil Engineers, 1336-1339 [in Korean],
- Malthotra, V.M., and Mehta, P.K. (2002). High-performance, high-volume fly ash concrete, Suppementary Cementing Materials for Sustainable Development, 9(3), 101.
- NT BUILD 492. (1999). Concrete, Mortar and Cement Based Repair Materials, Chloride Migration Coefficient from Non-Steady-State Migration Experiments, Nordtest.
- Oh, S.G. (2011). An Evaluation of Chloride Attack Resistibility of Concrete Mixed with Fly Ash, Journal of the Architectural Institute of Korea Structure & Construction, 27(6), 91-98 [in Korean].
- Park, J.I. (2013). Resistance against Chloride Ion Penetration of Concrete Containing Mineral Admixtures, Ph.D thesis, Andong National University, Korea.