1 Department of Civil Engineering, Federal University of Oye Ekiti, Ekiti State, Nigeria.
2 Department of Civil and Natural resources engineering, Yaba College of Technology, Yaba, Lagos State, Nigeria.
3 Department of Building Technology, Federal Polytechnic Ede, Osun State, Nigeria.
4 Department of Civil Engineering, Federal university of Technology Akure, Ondo State, Nigeria.
5 Department of Civil Engineering, Federal Polytechnic Oko, Anambra State, Nigeria.
6 Department of Civil Engineering Technology Auchi Polytechnic, Auchi, Edo State, Nigeria.
7 Department of Environment, University of Lagos, Lagos state, Nigeria.
8 Department of Civil engineering, Federal University of Technology Owerri, Nigeria.
Research Article
World Journal of Advanced Research and Reviews, 2024, 23(01), 2522-2539
Received on 15 June 2024; revised on 21 July 2024; accepted on 24 July 2024
Because of its quality, which allows for veracities, Today, concrete is the most frequently utilized civil engineering material. Concrete has a low tensile strength and a high compressive strength. Even though Nigeria is Africa's giant, it has been discovered that its local contractor does not have a well-used standard mix procedure. Local Nigerian contractors have relied on an international mix. COREN recently established a mix design. It is critical that we determine whether this design process will be suitable for usage by local contractors. To assess the effectiveness of the published local mix against defined international standards, a complete experimental analysis of the COREN mix design with ACI and DoE was used in this study. With a target compressive strength of 30N/mm2, three concrete mix designs with 0.48 and 0.50 water/cement ratios were used, and this mix was subjected to compressive tests, split tensile tests, and three-point bending. With respect to all the test conducted and analyzed, this attests to the level of significance of COREN i.e. For 28days mix with 0.48w/c, compressive strength with COREN gave 32N/mm2 against 31N/mm2 and 30N/mm2 for ACI and DoE mix, respectively. Splitting tensile strength of 2.7 N/mm2 was achieved with COREN mix against 2.8N/mm2 and 2.7N/mm2 from ACI and DoE, respectively. Likewise, results of flexural strength are 4.7N/mm2, 5.3N/mm2 and 5.1N/mm2 for COREN, ACI and DoE, respectively. For 28days mix with 0.50w/c, compressive strength with COREN gave 29N/mm2 against 30N/mm2 for ACI and DoE mix, respectively. Splitting tensile strength of 2.5N/mm2 was achieved with COREN mix against 2.4N/mm2 and 2.8N/mm2 from ACI and DoE, respectively. Likewise, results of flexural strength are 5.1N/mm2, 4.7N/mm2 and 5.6N/mm2 for COREN, ACI and DoE, respectively.
Mix design methods; Concrete mix; Durability; Concrete; Coren; ACI; DoE
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Peter Dayo Fakoyede, Oparinde Abdulsalam Olamilekan, Adeleke Olaniyi Benjamin, Ewemade Cornelius Enabulele, Nzemeka Ogechukwu Israel, Grace Agbons Aruya, Jimoh Bode Jacob, Chibuike Godswill Nzeanorue, Habeeb Yusuf Akanji and Ikudehinbu Temitope. Comparison of Coren mix design with other international mix (ACI and DoE) design methods. World Journal of Advanced Research and Reviews, 2024, 23(1), 2522-2539. Article DOI: https://doi.org/10.30574/wjarr.2024.23.1.2230