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Deep neural network modeling of the properties of sustainable high-performance concrete from industrial waste materials

Aissa Laouissi, Asma Benkhelladi, Messaouda Boumaaza, Yacine Karmi, Mostefa Hani, Ahmed Belaadi, Rebih Zaitri, Ibrahim M.H. Alshaikh, Djamel Ghernaout, Yazid Chetbani

2025Results in Engineering10 citationsDOIOpen Access PDF

Abstract

• Adding recycled metal fibers improves the physicomechanical properties of high-performance fiber-reinforced concrete (HPFRCs). • Carrying out sensitivity assessment analysis for each constituent of the reinforced mixture. • HPFRC curing time considerably influences its performance. • The newly developed deep neural network models are highly accurate for predicting HPFRC flexural strength, compressive strength, tensile strength, and water absorption. • HPFRC algorithm optimization and engineering requirements are clearly described. The manufacture of concrete significantly impacts the environment due to the substantial consumption of non-renewable resources and CO₂ emissions generated during cement manufacturing. This work develops a sustainable high-performance fiber-reinforced concrete (HPFRC) by integrating recycled stainless-steel fibers (SFC) sourced from industrial cables, thereby advancing circular economy principles. An extensive experimental study was performed to evaluate the effects of variations in water-to-binder ratio ( W/B ), fiber content (SFC), fiber aspect ratio ( L/d ), and curing time ( T ) on four principal properties: compressive strength (CS), flexural strength (FS), splitting tensile strength (STS), and water absorption (WA). The optimal mechanical performance was attained with a mix design of W/B = 0.29, L/d = 63, SFC = 29 kg/m³, and a curing time of 90 days, resulting in CS = 115.36 MPa, FS = 11.85 MPa, and STS = 9.46 MPa. The least water absorption (0.42 %) was recorded with a water-to-binder ratio of 0.27, a length-to-diameter ratio of 63, and a specific gravity of 24 kg/m³ at 90 days, signifying exceptional durability. Analysis of variance (ANOVA) indicated that curing time exerted the most substantial influence on all mechanical parameters, accounting for up to 69.6 % of the observed variance. Six deep neural network (DNN) architectures were constructed to represent and forecast these qualities, with each architecture optimized using a distinct algorithm: Genetic Algorithm (GA), Dragonfly Algorithm (DA), Improved Grey Wolf Optimizer (IGWO), Levenberg–Marquardt (LM), BFGS, and Conjugate Gradient (CGP). The IGWO-DNN model demonstrated superior predictive ability, attaining R² values over 0.98 for all outputs, accompanied by negligible prediction errors (MAPE of 0.53 % for CS and 1.33 % for WA; RMSE of 0.88 MPa for CS and 0.20 % for WA). This combined experimental-AI framework illustrates an effective method for designing eco-efficient concrete with enhanced mechanical and durability properties, utilizing industrial waste and sophisticated optimization algorithms.

Topics & Concepts

Artificial neural networkEnvironmental scienceWaste managementCivil engineeringEngineeringComputer scienceArtificial intelligenceConcrete and Cement Materials ResearchInnovative concrete reinforcement materialsRecycled Aggregate Concrete Performance
Deep neural network modeling of the properties of sustainable high-performance concrete from industrial waste materials | Litcius