Machine Learning-Based Research on Tensile Strength of SiC-Reinforced Magnesium Matrix Composites via Stir Casting

doi:10.1007/s40195-024-01673-5

Abstract

Abstract:

SiC is the most common reinforcement in magnesium matrix composites, and the tensile strength of SiC-reinforced magnesium matrix composites is closely related to the distribution of SiC. Achieving a uniform distribution of SiC requires fine control over the parameters of SiC and the processing and preparation process. However, due to the numerous adjustable parameters, using traditional experimental methods requires a considerable amount of experimentation to obtain a uniformly distributed composite material. Therefore, this study adopts a machine learning approach to explore the tensile strength of SiC-reinforced magnesium matrix composites in the mechanical stirring casting process. By analyzing the influence of SiC parameters and processing parameters on composite material performance, we have established an effective predictive model. Furthermore, six different machine learning regression models have been developed to predict the tensile strength of SiC-reinforced magnesium matrix composites. Through validation and comparison, our models demonstrate good accuracy and reliability in predicting the tensile strength of the composite material. The research findings indicate that hot extrusion treatment, SiC content, and stirring time have a significant impact on the tensile strength.

Key words: Machine learning, Stirring casting, Magnesium matrix composite, Tensile strength

Zhihong Zhu, Wenhang Ning, Xuanyang Niu, Yuhong Zhao. Machine Learning-Based Research on Tensile Strength of SiC-Reinforced Magnesium Matrix Composites via Stir Casting[J]. Acta Metallurgica Sinica (English Letters), 2024, 37(3): 453-466.

Figures/Tables 11

Fig. 1 Scatter plot of SiC volume fraction and size versus tensile strength

Fig. 2 Scatter plot of stirring speed and stirring time against tensile strength

Fig. 3 Pearson correlation coefficient plot of features

Fig. 4 Artificial neural network structure

Table 1 Optimal hyperparameters of the model

Model	Parameters
SVR	C = 100, gamma = 0.001, kernel = ‘linear’
RF	max_features = 2, min_samples_leaf = 1, n_estimators = 20
Ridge	Alpha = 0.1, fit_intercept = True
DT	max_depth = 9, min_samples_spilt = 8, max_features = ‘sqrt’
XGBoost	eta = 0.6, n_estimators = 50

Table 2 Performance indexes of the model for tensile strength

Model	R²	MSE	RMSE
SVR	0.88	520.04	22.80
RF	0.89	513.19	22.65
DT	0.81	884.71	29.74
Ridge	0.82	852.78	29.20
XGBoost	0.76	1040.65	32.59
ANN	0.95	426.30	20.64

Fig. 5 Scatter plot of SVR, RF, DT, Ridge model true values and model predicted values

Fig. 6 Scatter plot of predicted and true values of ANN model on different datasets

Fig. 7 Histogram of predicted and true values

Fig. 8 Error histogram of ANN model

Fig. 9 Importance of features in tensile strength model

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