Machine learning-driven optimization of concrete mixes incorporating treated sludge

This study investigates the mechanical performance of concrete incorporating treated sludge as a partial cement replacement, analyzing compressive, flexural, and split tensile strengths across various curing durations. Experimental results demonstrate strength improvement with extended curing time and optimal water-to-cement (W/C) ratios. While 10%?15% cement replacement maintains structural viability, higher substitution levels (beyond 17.5%) lead to strength deterioration, with concrete exceeding 22.5% sludge replacement exhibiting limited structural feasibility. To enhance predictive accuracy and optimize sustainable concrete mix design, machine learning models are employed to estimate compressive strength. machine learning models. Extra Trees Regressor, AdaBoost, Random Forest, and Gradient Boosting Regressor were developed to predict compressive strength. Among these, the Gradient Boosting and Random Forest models demonstrated the highest predictive accuracy, with R² values of 0.975 and 0.977, respectively. The study confirms that integrating machine learning with experimental methods offers a robust, data-driven approach for optimizing concrete mix design and supports the sustainable reuse of sewage sludge in construction applications.