Introduction Early-age cracking in mass concrete structures, driven by thermal stresses from cement hydration, remains a critical durability concern. One effective way to reduce the risk of early cracking is to select a concrete mixture formulation that reduces heat emission. This study considers, for the first time, the inverse problem of preventing early crack formation: determining the maximum allowable concrete heat release (Qmax) for the given geometric characteristics of the structure and concreting parameters using machine learning methods. Materials and Methods A dataset of 39,200 numerical experiments was collected via thermo-mechanical modeling, considering variables like slab thickness, heat transfer coefficient, concrete grade, ambient temperature, and concreting duration. The target value Q max was identified using the bisection method, ensuring the tensile stress-to-strength ratio remained below unity. A feedforward Artificial Neural Network (ANN) with two hidden layers was developed and trained on this dataset. Results The ANN model achieved exceptional prediction accuracy, with a correlation coefficient of 0.99955 between target and predicted Q max values. Analysis revealed that the concrete compressive strength grade had a minimal effect on the maximum permissible heat release. Discussion Feature importance analysis showed that the curing rate and slab thickness are the most significant parameters influencing the Q max value. The negligible impact of compressive strength stems from its competing effects on tensile strength and elastic modulus. Conclusion The developed ANN model provides a highly accurate tool for predicting permissible concrete heat release, enabling optimized mix design to mitigate early thermal cracking in massive foundation slabs.
Tyurina et al. (Wed,) studied this question.