海洋高强韧钢热变形流变应力的Arrhenius本构方程和人工神经网络模型

IF 2.9 4区材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY

Materials Technology Pub Date : 2023-10-16 DOI:10.1080/10667857.2023.2264670

Li Fangpo, Li Ning, Ren Xiaojian, Qiao Song, Lu Caihong, Wang Jianjun, Xu Yang, Wang Bin

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引用次数: 0

摘要

在本研究中，通过热压缩实验研究了一种高强度近海钢在不同温度和速率下的热变形行为。针对更为复杂的变形特征，建立了Arrhenius本构模型和BP-ANN反传播人工神经网络(BP-ANN)。采用相关系数(R)和平均绝对相对误差(AARE)等标准统计参数对两种模型的性能进行评价。结果表明，两种模型均能准确预测变形过程中产生的流变应力。BP-ANN的拟合相关系数大于99.9%，相对误差小于0.8%，优于Arrhenius方程模型。在应变速率为0.01 s−1和10 s−1时，与Arrhenius本构方程相比，人工神经网络的准确性略有下降，因为它超出了训练集的应变速率范围，因为这些预测更准确。

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Arrhenius constitutive equation and artificial neural network model of flow stress in hot deformation of offshore steel with high strength and toughness

In this study, the thermal deformation behaviour of a high strength offshore steel at different temperatures and rates was investigated through thermal compression experiments.An Arrhenius constitutive model and a back propagation artificial neural network (BP-ANN) were established to address more complex deformation characteristics. The performances of both models were was evaluated using standard statistical parameters such as the correlation coefficient (R) and average absolute relative error (AARE). The results showed that both models can accurately predict the rheological stresses generated during deformation.The BP-ANN outperforms the Arrhenius equation model with correlation coefficients of fit greater than 99.9% and less than 0.8% relative error. At a strain rate of 0.01 s−1 and 10 s−1, the accuracy of the ANN decreases slightly due to the fact that it exceeds the strain rate range of the training set, as compared to the Arrhenius constitutive equations as these are more accurately predicted.

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来源期刊

Materials Technology 工程技术-材料科学：综合

CiteScore

6.00

自引率

9.70%

发文量

105

审稿时长

8.7 months

期刊介绍： Materials Technology: Advanced Performance Materials provides an international medium for the communication of progress in the field of functional materials (advanced materials in which composition, structure and surface are functionalised to confer specific, applications-oriented properties). The focus is on materials for biomedical, electronic, photonic and energy applications. Contributions should address the physical, chemical, or engineering sciences that underpin the design and application of these materials. The scientific and engineering aspects may include processing and structural characterisation from the micro- to nanoscale to achieve specific functionality.