Electrochemical Characteristics of High-Volume Fly Ash Lightweight Aggregate Concrete Incorporating Hydrated Lime

Al-Attar, Tareq S.; Al-Shathr, Basil S.; Mohammed, Mahmood E.

doi:10.30684/etj.v38i11A.1550

	Electrochemical Characteristics of High-Volume Fly Ash Lightweight Aggregate Concrete Incorporating Hydrated Lime
Engineering and Technology Journal
Article 6, Volume 38, 11A, 2020, Pages 1629-1639 PDF (1.22 M)
Document Type: Research Paper
DOI: 10.30684/etj.v38i11A.1550
Authors
Tareq S. Al-Attar¹; Basil S. Al-Shathr²; Mahmood E. Mohammed³
¹Civil Engineering Department, University of Technology - Iraq
²Civil Eng. Dept., University of Technology, Baghdad, Iraq.
³Civil Engineering Dept., University of Technology, Baghdad, Iraq.
Abstract
Currently, the use of high-volume fly ash lightweight concrete, HVFALWC, has acquired popularity as a durable, resource-efficient, and an option of sustainability for varying concrete applications. Electrochemical characteristics such as half- cell potential, AC resistance, chloride penetration, free chloride, and pH value, up to 180 days were investigated for this type of concrete that uses 50% and 60% of fly ash as a replacement of Portland cement. The effect of using 10% hydrated lime powder as a partial substitute for the weight of cementitious materials for HVFALWC on electrochemical properties was also studied. The results in this study showed the possibility of producing friendly environmental structural lightweight concrete by using high volume fly ash (50% and 60%) as partial replacement by weight of cement. Furthermore, using 10% hydrated lime as partial replacement by weight of cementitious materials could be considered as a reliable measure to reduce the effect of chloride ions in the corrosion process
Keywords
High-volume fly ash lightweight concrete; corrosion; Porcelanite; AC resistance; pH test; Rapid chloride penetration

References
[1] J. P. Broomfield, Corrosion of Steel in Concrete Understanding, investigation and repair 2nd edition. 2007. [2] ASTM C876-15, “Standard Test Method for Corrosion Potentials of Uncoated Reinforcing Steel in Concrete,” Annu. B. ASTM Stand., no. April 2016, pp. 1–8, 2016. [3] Japan Society of Corrosion Engineerin, (JSCE), Corrosion Engineering Handbook. 2000. [4] Y. Lim, T. Noguchi, H. Lee, and S. Shin, “Advanced Resistivity Method for Corrosion Evaluation Directly above a Reinforcement Bar,” in International Conference on Sustainable Bulding Asia, 2010, pp. 709–712. [5] T. C. Madhavi, and S. Annamalai, “Electrical conductivity of concrete,” ARPN J. Eng. Appl. Sci., vol. 11, no. 9, pp. 5979–5982, 2016. [6] K. Chansuriyasak, C. Wanichlamlart, P. Sancharoen, W. Kongprawechnon, and S. Tangtermsirikul, “Comparison between half-cell potential of reinforced concrete exposed to carbon dioxide and chloride environment,” Songklanakarin J. Sci. Technol., vol. 32, no. 5, pp. 461–468, 2010. [7] J. Gulikers, R. Weidert, and M. Raupach, “RILEM TC 154-EMC : ELECTROCHEMICAL TECHNIQUES FOR MEASURING Test methods for on site measurement of resistivity of concrete,” Mater. Struct. Constr., vol. 33, pp. 603–611, 2001. [8] M. E. Al -Taee, “Corrosion Protection of Reinforcing Steel by using Mineral Admixtures and Corrosion Inhibitors,” M.Sc. thesis, Department of Building and Construction Engineering, University of Technology Baghdad – Iraq, PP.126, 2002. [9] S. K. Al-Hubbubi, “Corrosion of Steel Reinforcement in High Performace Concrete Containg Local Slag and Corrosion Inhibitor,” M.Sc. thesis, Department of Building and Construction Engineering, University of Technology, Baghdad – Iraq, PP.113 , 2001. [10] L. M. Dahkeel, “Corrosion of Steel Reinforcement in High Performance Lightweight Aggregate Concrete Containing Rice Husk Ash and Corrosion Inhibitor,” M.Sc. thesis, Department of Building and Construction Engineering , University of the Technology, Baghdad – Iraq,PP.112, 2002. [11] T. D. Rupnow and P. Icenogle, “Evaluation of Surface Resistivity Measurements as an Alternative to the Rapid Chloride Permeability Test for Quality Assurance and Acceptance – Implementation Report,” FHWA/LA.13/496, Louisiana Dep. Transp. Dev., no. 2, p. 32, 2012. [12] Iraqi Standard, “Portland cement,” IQS 5, 1984. [13] J. Sarfo-Ansah, E. Atiemo, K. Boakye, and Z. Momade, “Comparative Study of Chemically and Mechanically Activated Clay Pozzolana,” Mater. Sci. Appl., vol. 05, no. 02, pp. 86–94, 2014. [14] Iraqi Standard, “Lime That Used in Building,” IQS 807, 2004. [15] Iraqi Standard, “Natural Aggregate Resource That Used in Building and Concrete,” IQS 45, 1984. [16] U. J. Alengaram, H. Mahmud, and M. Z. Jumaat, “Enhancement and prediction of modulus of elasticity of palm kernel shell concrete,” Mater. Des., vol. 32, no. 4, pp. 2143–2148, 2011. [17] [17] ASTM C143/C143M −15a, “Standard Test Method for Slump of Hydraulic-Cement Concrete,” Annu. B. ASTM Stand., no. February 2016, pp. 1–4, 2015. [18] BS EN 12390-3:2009, “Testing hardened concrete, Part 3: Compressive strength of test specimens (2009),” Br. Stand. Inst., pp. 1–18, 2009. [19] ASTM C642 − 13, “Standard Test Method for Density , Absorption , and Voids in Hardened Concrete,” Annu. B. ASTM Stand., no. February 2013, pp. 1–3, 2013. [20] ASTM C567/C567M 14, “Standard Test Method for Determining Density of Structural Lightweight Concrete,” Annu. B. ASTM Stand., no. May 2014, pp. 1–4, 2014. [21] ASTM C1202 − 17, “Standard Test Method for Electrical Indication of Concrete’s Ability to Resist Chloride Ion Penetration,” Annu. B. ASTM Stand., no. july 2017, pp. 1–7, 2017.
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