Development of machine learning models for the prediction of the compressive strength of calcium-based geopolymers

Compressive strength is an important mechanical index that determines the mixture design of geopolymer, and its accurate prediction is essential. The existing experiment-based and statistical methods are time-consuming, labor-intensive and inaccurate. This study aims to develop an effective, reliabl...

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Vydáno v:Journal of cleaner production Ročník 380; s. 135159
Hlavní autoři: Huo, Wangwen, Zhu, Zhiduo, Sun, He, Ma, Borui, Yang, Liu
Médium: Journal Article
Jazyk:angličtina
Vydáno: Elsevier Ltd 20.12.2022
Témata:
algorithms
calcium oxide
Calcium-based geopolymer
compression strength
Compressive strength
Machine learning
Oxide composition
polymers
Prediction
raw materials
SHapley additive exPlanations
temperature
wastes
SHapley additive exPlanations
Calcium-based geopolymer
Oxide composition
Compressive strength
Prediction
Machine learning
ISSN:0959-6526, 1879-1786
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Shrnutí:Compressive strength is an important mechanical index that determines the mixture design of geopolymer, and its accurate prediction is essential. The existing experiment-based and statistical methods are time-consuming, labor-intensive and inaccurate. This study aims to develop an effective, reliable and interpretable machine learning (ML) model for predicting the compressive strength of calcium-based geopolymers. Feature engineering was constructed with molar ratios of raw material oxide composition, curing system, and mixing design. A total of eight algorithms in three types, traditional ML algorithms, integrated tree-based ML algorithms, and deep neural network algorithm, were employed to predict the compressive strength, and their differences, advantages, and disadvantages were compared. The importance of input variables in model training was evaluated. The contribution and influence pattern of input features on the development of compressive strength were revealed using the SHapley Additive exPlanations (SHAP) and inverse prediction. The results demonstrate that among the eight models proposed, the XGB model had the highest prediction accuracy (91%) and the lowest root mean squared error (3.85 MPa). Based on the importance analysis and the SHAP value, the parameters that had the greatest impact on the compressive strength were curing age, n(H2O)/n(Na2O), curing temperature, n(SiO2)/n(CaO) and the mass ratio of alkali activation solution to solid powder (L/S). The effects of input features on the compressive strength development of calcium-based geopolymers captured by SHAP and inverse predictions based on the best predictive model were consistent with the experimental results and theoretical understanding. The research in this paper facilitates the rapid prediction, improvement and optimization of the proportioning design and application of calcium-based geopolymers, and also provides a theoretical basis for the utilization of industrial and construction waste, in line with sustainable and low-carbon development strategies. [Display omitted] •A chemical engineering-based dataset was constructed to predict the compressive strength of calcium-based geopolymers.•The XGB model was the optimal prediction model with the highest prediction accuracy.•The variables that had a greater impact on the compressive strength of calcium-based geopolymers were determined.•The effects of input features on the compressive strength development captured by SHAP and inverse predictions were consistent with the experimental results and theoretical understanding.
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ISSN:0959-6526
1879-1786
DOI:10.1016/j.jclepro.2022.135159