Performance of Fly Ash Concrete with Nickel Slag Fine Aggregate in the Marine Environment

Syamsul Bahri Ahmad; Rita Irmawaty; Sumarni Hamid Aly; A. Amiruddin

doi:10.28991/CEJ-2022-08-12-010

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Syamsul Bahri Ahmad
syamba_68@yahoo.co.id
Civil Engineering Department, Hasanuddin University, South Sulawesi,, Indonesia
Rita Irmawaty Civil Engineering Department, Hasanuddin University, South Sulawesi,, Indonesia
Sumarni Hamid Aly Civil Engineering Department, Hasanuddin University, South Sulawesi,, Indonesia
A. Amiruddin Civil Engineering Department, Hasanuddin University, South Sulawesi,, Indonesia

Vol. 8 No. 12 (2022): December

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This research aims to assess the feasibility of the mechanical strength and the durability of the concrete containing 50% nickel slag and a combination of 15% and 30% fly ash with a water-cement ratio of 0.25 and 0.45 in a marine environment. Four types of concrete, namely OPC-sand (C) as control concrete, OPC-50GNS (S), 15FA-50GNS (F1), and 30FA-50GNS (F2) as comparison concrete, were tested with a 100í—200 mm cylindrical specimen. The results showed an increase in the mechanical strength and potential resistance of the comparison concrete at the age of 28 days. While at the age of 180 days, fluctuating changes were found. The compressive strength of S concrete increased by 36.9 and 9.3% respectively, F1 concrete by 37.7% and 1.7%, F2 by 33.7% and 5.9% at ratio 0.45 and 0.25. Likewise, the value of the split tensile strength and modulus of elasticity of concrete. This result was followed by reduced porosity, sorptivity, and chloride penetration resistance as an indication of better concrete durability. Fly ash appears to have a greater positive impact on potential durability than mechanical strength at a water cement ratio of 0.25 versus 0.45. Although the chloride penetration resistance is decent, the compressive strength of concrete with a water-cement ratio of 0.45 does not qualify for application in the marine environment. In contrast, concrete with a water-cement ratio of 0.25 containing 50% nickel slag and the addition of class C fly ash up to 30% was declared suitable for application to concrete in the marine environment zone C2 according to ACI 318-19.

Doi: 10.28991/CEJ-2022-08-12-010

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Ahmad, S. B., Irmawaty, R., Aly, S. H., & Amiruddin, A. (2022). Performance of Fly Ash Concrete with Nickel Slag Fine Aggregate in the Marine Environment. Civil Engineering Journal, 8(12), 2803–3814. https://doi.org/10.28991/CEJ-2022-08-12-010

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[1] Meyer, C. (2004). Concrete Materials and Sustainable Development in the USA. Structural Engineering International, 14(3), 203–207. doi:10.2749/101686604777963757.
[2] Lehne, J., & Preston, F. (2018). Making concrete change: Innovation in low-carbon cement and concrete. Chatham House Report, London, United Kingdom. Available online: https://policycommons.net/artifacts/1423241/making-concrete-change/2037504/ (accessed on August 2022).
[3] Meyer, C. (2002). Concrete and sustainable development. ACI Special Publications, 206, 501-512.
[4] Tajra, F., Abd Elrahman, M., & Stephan, D. (2019). The production and properties of cold-bonded aggregate and its applications in concrete: A review. Construction and Building Materials, 225, 29-43. doi:10.1016/j.conbuildmat.2019.07.219.
[5] Sai Giridhar Reddy, V., & Ranga Rao, V. (2017). Eco-friendly blocks by Blended Materials. International Journal of Engineering, Transactions B: Applications, 30(5), 636–642. doi:10.5829/idosi.ije.2017.30.05b.02.
[6] AlArab, A., Hamad, B., & Assaad, J. J. (2022). Strength and Durability of Concrete Containing Ceramic Waste Powder and Blast Furnace Slag. Journal of Materials in Civil Engineering, 34(1). doi:10.1061/(asce)mt.1943-5533.0004031.
[7] Kanthe, V., Deo, S., & Murmu, M. (2018). Combine use of fly ash and rice husk ash in concrete to improve its properties. International Journal of Engineering, Transactions A: Basics, 31(7), 1012–1019. doi:10.5829/ije.2018.31.07a.02.
[8] Elchalakani, M., Basarir, H., & Karrech, A. (2017). Green Concrete with High-Volume Fly Ash and Slag with Recycled Aggregate and Recycled Water to Build Future Sustainable Cities. Journal of Materials in Civil Engineering, 29(2). doi:10.1061/(asce)mt.1943-5533.0001748.
[9] Ho, N. Y., Lee, Y. P. K., Lim, W. F., Zayed, T., Chew, K. C., Low, G. L., & Ting, S. K. (2013). Efficient Utilization of Recycled Concrete Aggregate in Structural Concrete. Journal of Materials in Civil Engineering, 25(3), 318–327. doi:10.1061/(asce)mt.1943-5533.0000587.
[10] Ma, Q., Guo, R., Zhao, Z., Lin, Z., & He, K. (2015). Mechanical properties of concrete at high temperature”A review. Construction and Building Materials, 93, 371-383. doi:10.1016/j.conbuildmat.2015.05.131.
[11] Soutsos, M. (2010). Concrete durability: a practical guide to the design of durable concrete structures. ICE Publishing, London, United Kingdom.
[12] Shetty, M. S., & Jain, A. K. (2019). Concrete Technology (Theory and Practice). Chand Publishing, New Delhi, India.
[13] Scrivener, K. L., Crumbie, A. K., & Laugesen, P. (2004). The interfacial transition zone (ITZ) between cement paste and aggregate in concrete. Interface Science, 12(4), 411–421. doi:10.1023/B:INTS.0000042339.92990.4c.
[14] Yang, H. C., Cheng, M. Y., & Wang, J. P. (2012). An investigation on the interfacial transition zone in concrete using SEM. Advanced Materials Research, 446–449, 166–170. doi:10.4028/www.scientific.net/AMR.446-449.166.
[15] Elsharief, A., Cohen, M., & Olek, J. (2004). Influence of aggregate type and gradation on the microstructure and durability properties of Portland cement mortar and concrete. International RILEM symposium on concrete science and engineering: a tribute to Arnon Bentur. doi:10.1617/2912143926.118.
[16] Poon, C. S., Lam, L., & Wong, Y. L. (1999). Effects of fly ash and silica fume on interfacial porosity of concrete. Journal of Materials in Civil Engineering, 11(3), 197-205. doi:10.1061/(ASCE)0899-1561(1999)11:3(197).
[17] Sadrmomtazi, A., Tahmouresi, B., & Kohani Khoshkbijari, R. (2018). Effect of fly ash and silica fume on transition zone, pore structure and permeability of concrete. Magazine of Concrete Research, 70(10), 519–532. doi.org/10.1680/jmacr.16.00537.
[18] Serdar, M., Biljecki, I., & BjegoviÄ‡, D. (2017). High-Performance Concrete Incorporating Locally Available Industrial By-Products. Journal of Materials in Civil Engineering, 29(3). doi:10.1061/(asce)mt.1943-5533.0001773.
[19] Arezoumandi, M., Volz, J. S., Ortega, C. A., & Myers, J. J. (2015). Shear Behavior of High-Volume Fly Ash Concrete versus Conventional Concrete: Experimental Study. Journal of Structural Engineering, 141(3). doi:10.1061/(asce)st.1943-541x.0001003.
[20] Sengul, O., & Tasdemir, M. A. (2009). Compressive strength and rapid chloride permeability of concretes with ground fly ash and slag. Journal of Materials in Civil Engineering, 21(9), 494-501. doi:10.1061/(ASCE)0899-1561(2009)21:9(494).
[21] Nguyen, Q. D., Khan, M. S. H., Castel, A., & Kim, T. (2019). Durability and Microstructure Properties of Low-Carbon Concrete Incorporating Ferronickel Slag Sand and Fly Ash. Journal of Materials in Civil Engineering, 31(8). doi:10.1061/(asce)mt.1943-5533.0002797.
[22] Saha, A. K., & Sarker, P. K. (2018). Durability characteristics of concrete using ferronickel slag fine aggregate and fly ash. Magazine of Concrete Research, 70(17), 865–874. doi:10.1680/jmacr.17.00260.
[23] Deiaf, A. B. A. (2016). Bonding between Aggregates and Cement Pastes in Concrete. Journal of Civil Engineering and Architecture, 10(3), 353–358. doi:10.17265/1934-7359/2016.03.010.
[24] Saha, A. K. (2018). Effect of class F fly ash on the durability properties of concrete. Sustainable environment research, 28(1), 25-31.doi:10.1016/j.conbuildmat.2004.03.011.
[25] ASTM C618-03. (2017). Standard Specification for Coal Fly Ash and Raw or Calcined Natural Pozzolan for Use in Concrete. ASTM International, Pennsylvania, United States. doi:10.1520/C0618-03.
[26] Zhang, Q., Ji, T., Yang, Z., Wang, C., & Wu, H. C. (2020). Influence of different activators on microstructure and strength of alkali-activated nickel slag cementitious materials. Construction and Building Materials, 235, 117449. doi:10.1016/j.conbuildmat.2019.117449.
[27] ASTM C143/C143M – 12. (2015). Standard Test Method for Slump of Hydraulic-Cement Concrete. ASTM International, Pennsylvania, United States. doi:10.1520/C0143_C0143M-12.
[28] SNI-1974. (2011). Testing of concrete compressive strength with a cylindrical test object. National Standardization Agency, Jakarta, Indonesia.
[29] ASTM C496/C496M-04. (2017). Standard Test Method for Splitting Tensile Strength of Cylindrical Concrete Specimens. ASTM International, Pennsylvania, United States. doi:10.1520/C0496_C0496M-04.
[30] ASTM C469/C469M-22. (2022). Standard Test Method for Static Modulus of Elasticity and Poisson's Ratio of Concrete in Compression. ASTM International, Pennsylvania, United States. doi:10.1520/C0469_C0469M-22.
[31] Li, K. (2016). Durability design of concrete structures: Phenomena, modelling and practice. John Wiley & Sons, Hoboken, United States. doi:10.1002/9781118910108.
[32] ASTM C642-21. (2022). Standard Test Method for Density, Absorption and Voids in Hardened Concrete. ASTM International, Pennsylvania, United States. doi:10.1520/C0642-21.
[33] ASTM C1585-13. (2020). Standard Test Method for Measurement of Rate of Absorption of Water by Hydraulic Cement Concretes. ASTM International, Pennsylvania, United States. doi:10.1520/C1585-13.
[34] NT BUILD 492. (1999). Concrete, Mortar and Cement-Based Repair Materials, Chloride Migration Coefficient On from Non-Steady-State Migration Experiments. NORDTEST, Espoo, Finland.
[35] ACI 318-19. (2019). Building Code Requirements for Structural Concrete and Commentary. American Concrete Institute (ACI), Farmington Hills, United States.

Publication Start Year:	2015
JCR 2023 Impact Factor (IF):	4.3
JIF QUARTILE:	Q1
SJR 2023 Quartile:	Q1
Acceptance Rate:	27%
Review Speed (Average):	76 days
Issue Per Year:	12
Number of Volumes:	10
Number of Issues:	107
Number of Articles:	1552
Number of Reviewers:	3417
Number of Contributors:	3604
Contributing Countries:	86
No. of WoS Citations:	7986
WoS h-index:	34
Scopus CiteScore:	7.0
No. of Google Citations:	17324
Google h-index:	47
Google i10-index:	393
Abstract Views:	5,819,908
PDF Download:	3,790,637

Performance of Fly Ash Concrete with Nickel Slag Fine Aggregate in the Marine Environment

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