JKSMI
Journal of the Korea Institute for
Structural Maintenance and Inspection
KSMI
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ISSN : 2234-6937 (Print)
ISSN : 2287-6979 (Online)
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Journal of the Korea Concrete Institute
J Korea Inst. Struct. Maint. Insp.
Indexed by
Korea Citation Index (KCI)
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2019-09
(Vol.23 No.5)
10.11112/jksmi.2019.23.5.30
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REF
1.
ACI 201.2R-08 (2008), Guide to Durable Concrete, American Concrete Institute (ACI).
2.
ASTM C 1202 (2005), Standard Test Method for Electrical Indication of Concrete's Ability to Resist Chloride Ion Penetration, America Society for Testing and Materials.
3.
Bentz, E.C. (2003), Probabilistic Modeling of Service life for Structures Subjected to Chlorides, ACI Mater Journal, 100(5) 391-397.
4.
Berke, N. S., Hicks, M. C. (1994), Predicting Chloride Profiles in Concrete, CORROSION, 50(3), 234-239.
5.
Broomfield, J.P. (2006), Corrosion of Steel in Concrete: Understanding, Investigation and Repair, CRC Press: London.
6.
CEN (2000), Eurocode 1: Basis of Design and Actions on Structures, EN-1991, Brussels: European Committee for Standardization (Comité Européen de Normalisation, CEN).
7.
Chung, L., Kim, J. H., Yi, S. T. (2008), Bond strength prediction for reinforced concrete members with highly corroded reinforcing bars, Cement and Concrete Composites, 30(7), 603-611.
8.
DuraCrete Final Report (2000), DuraCrete Probabilistic Performance Based Durability Design of Concrete Structures.
9.
Ehlen, M. A. (2018), Life-365TM Service Life Prediction Model and Computer Program for Predicting the Service Life and Life-cycle Costs of Reinforced Concrete Exposed to Chlorides, Life365 manual, SFA, 9-38.
10.
Ishida, T., Maekawa, K., Kishi, T. (2007), Enhanced Modeling of Moisture Equilibrium and Transport in Cementitious Materials Under Arbitrary Temperature and Relative Humidity History, Cement and Concrete Research, 37(4), 565-578.
11.
JSCE (2002), Concrete Library 109: Proposal of the Format for Durability Database of Concrete, Japan Society of Civil Engineering (JSCE).
12.
JSCE (2007), Standard Specification for Concrete Structures: Materials and Construction, Japan Society of Civil Engineering(JSCE) Guidelines for Concrete, 16.
13.
JSCE (2012), Standard Specification for Concrete Structures: Design, Japan Society of Civil Engineering(JSCE) Guidelines for Concrete, 15.
14.
KCI (2012), Concrete Standard Specification-Durability Part, Korea Concrete Institute.
15.
Kim, J. H., Jeong, J. Y., Jang, S. Y., Jung, S. H., Kim, S. I. (2015), Strength Development and Durability of High-Strength High-Volume GGBFS Concrete, Journal of Korean Recycled Construction Resources Institute, 3(3), 261-267.
16.
Lee, H. J., Bae, S. H., Jung, S. H. (2017), Resistance to Corrosion of Reinforcing Steel and Critical Chloride Content of High Volume Fly Ash Concrete, Journal of Korean Recycled Construction Resources Institute, 5(4), 375-381.
17.
Leng, F., Feng, N., Lu, X. (2000), An Experiment Study on the Properties of Resistance to Diffusion of Chloride Ions of Fly Ash and Blast Furnace Slag Concrete, Cement and Concrete Research 30(6), 989-992.
18.
Maekawa, K., Ishida, T., Kishi, T. (2003), Multi-Scale Modeling of Concrete Performance, Journal of Advanced Concrete Technology, 1(2), 91-126.
19.
Nilsson, L. O., Sandberg, P., Poulsen, E., Tang, L., Andersen, A., Frederiksen, J. M. (1997), HETEK: system for estimation of chloride ingress into concrete: Theoretical background, Denmark Ministry of Transport.
20.
Nordtest method (1999), Concrete, mortar and cement-based repair materials: Chloride migration coefficient from non-steady-state migration experiments, Nordic Counclil of Ministers, 1-8.
21.
Oh, B. H., Jang, S. Y. (2007), Effects of material and environmental parameters on chloride penetration profiles in concrete structures, Cement and Concrete Research, 37(1), 47-53.
22.
Pack, S. W., Jung, M. S., Song, H. W., Kim, S. H., Ann, K. Y. (2010), Prediction of time dependent chloride transport in concrete structures exposed to a marine environment, Cement and Concrete Research, 40(2), 302-312.
23.
Song, H. W., Kwon, S. J. (2009), Evaluations of Chloride Penetration in High Performance Concrete Using Neural Network Algorithm and Micro Pore Structure, Cement and Concrete Research, 39(9), 814-824.
24.
Tang, L., Nilsson, L. O. (1993), Chloride binding capacity and binding isotherms of OPC and mortar, Cement and Concrete Research, 23(2), 347-353.
25.
Thomas, M. D. A., Bamforth, P. B. (1999), Modeling chloride diffusion in concrete: Effect of fly ash and slag, Cement and Concrete Research. 29(4), 487-495.
