Prediction of heavy-section ductile iron fracture toughness based on machine learning

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Abstract

The preparation process and composition design of heavy-section ductile iron are the key factors affecting its fracture toughness. These factors are challenging to address due to the long casting cycle, high cost and complex influencing factors of this type of iron. In this paper, 18 cubic physical simulation test blocks with 400 mm wall thickness were prepared by adjusting the C, Si and Mn contents in heavy-section ductile iron using a homemade physical simulation casting system. Four locations with different cooling rates were selected for each specimen, and 72 specimens with different compositions and cooling times of the heavy-section ductile iron were prepared. Six machine learning-based heavy-section ductile iron fracture toughness predictive models were constructed based on measured data with the C content, Si content, Mn content and cooling rate as input data and the fracture toughness as the output data. The experimental results showed that the constructed bagging model has high accuracy in predicting the fracture toughness of heavy-section ductile iron, with a coefficient of coefficient (R 2 ) of 0.9990 and a root mean square error (RMSE) of 0.2373. Therefore, the design requirements of high fracture toughness heavy-section ductile iron, such as nuclear spent fuel storage and transportation containers, wind power generation bases and high-speed railroads, are satisfied.

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last seen: 2026-05-19T01:45:01.086888+00:00