Abstract
Forecasting the compressive strength of concrete is a complex task owing to the interactions among concrete ingredients. In addition, an important characteristic of the concrete failure surface is its six-fold symmetry. In this study, an artificial neural network (ANN) and adaptive neuro fuzzy interface system (ANFIS) were employed to model the compressive strength of natural volcanic ash mortar (VAM) by using the six-fold symmetry of concrete failure. The modeling was correlated with four parameters. To train and test the projected models, data for more than 150 samples were collected from the literature. Furthermore, mortar samples with varying proportions of volcanic ash were prepared in the laboratory and tested, and the results were used to validate the models. The performance of the developed models was assessed using numerous statistical measures. The results show that both the ANN and ANFIS models accurately predict the compressive strength of VAM with R-square above 0.9 and lower error statistics. The permutation feature analysis confirmed that the age of specimens affects the strength of VAM the most, followed by the water-to-cement ratio, curing temperature, and percentage of volcanic ash.
Highlights
Construction industries are known for their hazardous effects on the environment [1,2].Recent studies have shown that construction industries consume 40% of the world’s energy [3,4]
They are responsible for 23% of air pollution, 45% of landfill waste, and 35% of CO2 emissions [5,6]
We investigated the effect of partially replacing cement in mortar with volcanic ash (VA) at different percentages as well as the effect of different curing temperatures at different ages of mortar
Summary
Recent studies have shown that construction industries consume 40% of the world’s energy [3,4]. They are responsible for 23% of air pollution, 45% of landfill waste, and 35% of CO2 emissions [5,6]. The binding material in concrete, causes 7% of the total CO2 emissions and consumes around 15% of the total energy used by industries [11,12,13]. The demand for cement can only be reduced if construction industries adopt alternative environmentally friendly binding materials [14,15]
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