Litcius/Paper detail

Mechanical properties and radiological implications of replacing sand with waste ceramic aggregate in ordinary concrete

I.O. Olarinoye, M.T. Kolo, Dauda Biodun Amuda, Celestine Oche, Beadaa Mohammed, Jamila S. Alzahrani, M.S. Al-Buriahi

2024Journal of Radiation Research and Applied Sciences14 citationsDOIOpen Access PDF

Abstract

The mining of aggregates for the production of concrete creates ecological problems. In this study, the effect of partially replacing sand as fine aggregate (FA) with waste ceramic tiles (WCT) on the density, compressive strength (CS), specific radioactivity of naturally occurring radioactive materials ( 238 U, 232 Th, and 40 K), and the radiation shielding competence of concrete was investigated. Ordinary concrete samples consisting of cement, fine aggregate (river sand), coarse aggregate (granite), and water were prepared in 50 mm × 50 mm x 50 mm cubical steel moulds. The samples were coded as C-WCT0, C-WCT5, C-WCT10, C-WCT15, C-WCT20, and C-WCT25, representing concrete samples in which the FA component was replaced by 0, 5, 10, 15, 20, and 25% pulverized WCT, respectively. The CS and density of the samples were determined after 7-, 14-, and 28-day curing periods. The gamma spectrometric method was used to determine the specific activity of 238 U, 232 Th, and 40 K using a hyper pure germanium detector. The photon and neutron shielding parameters of the concrete blocks were calculated with the aid of the EPICS2017 cross-section library and relevant standard formulae. The mean CS for each concrete category increase with curing age. The density of the concrete varied from 2213 kg/m 3 to 2488 kg/m 3 as the FA replacement level rose to 15%. Using WCT as a partial replacement for FA altered the chemical composition and decreased the specific activities of 238 U, 232 Th, and 40 K, in the concrete samples. C-WCT15 had the best gamma photon and fast neutron absorption features among the concrete samples. The use of WCT as aggregate in concrete production is a sustainable and environmental-friendly way of producing concrete for general civil engineering and shielding applications in medical and other radiation facilities. This study also affirms that using alternative materials with lower specific activity to replace sand is radiologically desirable in reducing the indoor radiation dose of occupants of concrete-based structures. The replacement of 15% sand by WCT produced stronger, radiologically safer, and more effective radiation absorbing concrete.

Topics & Concepts

Aggregate (composite)CeramicRadiological weaponMaterials scienceGeotechnical engineeringComposite materialWaste managementEnvironmental scienceGeologyEngineeringChemistryRadiochemistryRadiation Shielding Materials AnalysisNuclear materials and radiation effectsConcrete and Cement Materials Research
Mechanical properties and radiological implications of replacing sand with waste ceramic aggregate in ordinary concrete | Litcius