Authors: Mona Elsalamawy, Ashraf Ragab Mohamed, Abdellatif Elsayed Abosen

Abstract:

This paper aims to evaluate the effectiveness of different crystalline coating materials concerning of chloride ions penetration. The concrete ages at the coating installation and its moisture conditions were addressed; where, these two factors may play a dominant role for the effectiveness of the used materials. Rapid chloride ions penetration test (RCPT) was conducted at different ages and moisture conditions according to the relevant standard. In addition, the contaminated area and the penetration depth of the chloride ions were investigated immediately after the RCPT test using chemical identifier, 0.1 M silver nitrate AgNO₃ solution. Results have shown that, the very low chloride ions penetrability, for the studied crystallization materials, were investigated only with the old age concrete (G1). The significant reduction in chloride ions’ penetrability was illustrated after 7 days of installing the crystalline coating layers. Using imageJ is more reliable to describe the contaminated area of chloride ions, where the distribution of aggregate and heterogeneous of cement mortar was considered in the images analysis.

Keywords: Chloride permeability, contaminated area, crystalline waterproofing materials, RCPT, XRD.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1314594

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References:

[1] M. Baykal, Carrasquillo, R.L. and Fowler, D., Implementation of Durability Models for Portland Cement Concrete into Performance-Based Specifications, Research Report 1706-4, Center for Transportation Research, Austin, TX, 2002.
[2] B.Z. Savas, Effects of microstructure on durability of concrete, North Carolina State University, Ann Arbor, 2000, p. 190.
[3] M.V. Diamanti, A. Brenna, F. Bolzoni, M. Berra, T. Pastore, M. Ormellese, Effect of polymer modified cementitious coatings on water and chloride permeability in concrete, Construction and Building Materials 49 (2013) 720-728.
[4] R.N. Swamy, S. Tanikawa, An external surface coating to protect concrete and steel from aggressive environments, Mater Struct 26(8) (1993) 465-478.
[5] BS EN 1504, Products and systems for the protection and repair of concrete structures, EN 1504 Part 2: Surface protection systems for concrete, BSI, www.bsigroup.com, 2004, p. 50.
[6] L. Bertolini, B. Elsener, P. Pedeferri, R.P. Polder, Surface Treatments, Corrosion of Steel in Concrete, WILEY-VCH Verlag GmbH & C o. KGaA, Weinheim2004, pp. 231-248.
[7] ASTM C1202-12, Standard Test Method for Electrical Indication of Concrete’s Ability to Resist Chloride Ion Penetration, ASTM International, West Conshohocken, PA, 2012, www.astm.org, 2012, p. 8.
[8] BS EN 206-1:2000, Concrete. Specification, performance, production and conformity, BSI, www.bsigroup.com, 2000, p. 74.
[9] ASTM C494/C494M-15, Standard Specification for Chemical Admixtures for Concrete, ASTM International, West Conshohocken, PA, 2015, www.astm.org, 2015, p. 10.
[10] F. He, C. Shi, Q. Yuan, C. Chen, K. Zheng, AgNO3-based colorimetric methods for measurement of chloride penetration in concrete, Construction and Building Materials 26(1) (2012) 1-8.
[11] Q. Yuan, C. Shi, F. He, G. De Schutter, K. Audenaert, K. Zheng, Effect of hydroxyl ions on chloride penetration depth measurement using the colorimetric method, Cement and Concrete Research 38(10) (2008) 1177-1180.
[12] M.H. Morteza Haeri, ImageJ Plugin for Analysis of Porous Scaffolds used in Tissue Engineering, Journal of Open Research Software 3(1):e1 (2015) 4.
[13] P.F. McGrath, R.D. Hooton, Re-evaluation of the AASHTO T259 90-day salt ponding test, Cement and Concrete Research 29(8) (1999) 1239-1248.
[14] A.R. Mohamed, W.W. El-Nadoury, M.T. Ayyob, Generalized Chloride Permeability Test for Blended and Nonblended Concrete, ACI Materials Journal V. 111, No. 3 (2014).
[15] V. Baroghel-Bouny, P. Belin, M. Maultzsch, D. Henry, AgNO3 spray tests: advantages, weaknesses, and various applications to quantify chloride ingress into concrete. Part 1: Non-steady-state diffusion tests and exposure to natural conditions, Mater Struct 40(8) (2007) 759.
[16] V. Baroghel-Bouny, P. Belin, M. Maultzsch, D. Henry, AgNO3 spray tests: advantages, weaknesses, and various applications to quantify chloride ingress into concrete. Part 2: Non-steady-state migration tests and chloride diffusion coefficients, Mater Struct 40(8) (2007) 783.
[17] V. Baroghel-Bouny, M. Dierkens, X. Wang, A. Soive, M. Saillio, M. Thiery, B. Thauvin, Ageing and durability of concrete in lab and in field conditions: investigation of chloride penetration, Journal of Sustainable Cement-Based Materials 2(2) (2013) 67-110.