Neural network prediction of the effect of thermomechanical controlled processing on mechanical properties

Machine learning with applications Pub Date : 2024-02-05 DOI:10.1016/j.mlwa.2024.100531

Sushant Sinha , Denzel Guye , Xiaoping Ma , Kashif Rehman , Stephen Yue , Narges Armanfard

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Abstract

The as-rolled mechanical properties of microalloyed steels result from their chemical composition and thermomechanical processing history. Accurate predictions of the mechanical properties would reduce the need for expensive and time-consuming testing. At the same time, understanding the interplay between process variables and alloy composition will help reduce product variability and facilitate future alloy design. This paper provides an artificial neural network methodology to predict lower yield strength (LYS) and ultimate tensile strength (UTS). The proposed method uses feature engineering to transform raw data into features typically used in physical metallurgy to better utilize the artificial neural network model in understanding the process. SHAP values are used to reveal the effect of thermomechanical controlled processing, which can be rationalized by physical metallurgy theory.

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神经网络预测热机械控制加工对机械性能的影响

微合金钢的轧制机械性能源于其化学成分和热机械加工历史。对机械性能的准确预测将减少对昂贵且耗时的测试的需求。同时，了解工艺变量和合金成分之间的相互作用将有助于减少产品变异性，促进未来的合金设计。本文提供了一种预测低屈服强度（LYS）和极限抗拉强度（UTS）的人工神经网络方法。所提出的方法利用特征工程将原始数据转换为物理冶金学中常用的特征，以便更好地利用人工神经网络模型理解工艺过程。SHAP 值用于揭示热机械受控加工的效果，而物理冶金理论可以合理地解释这种效果。

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Machine learning with applications Management Science and Operations Research, Artificial Intelligence, Computer Science Applications

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98 days