计算机科学
热保护
领域(数学)
传热
热的
材料科学
核工程
机械
热力学
复合材料
物理
数学
工程类
纯数学
作者
Yun Chen,Qiang Chen,Han Ma,Shaowei Chen,Qingguo Fei
标识
DOI:10.1016/j.ijheatmasstransfer.2025.126785
摘要
• The PINN model obtained based on the optimal fine-tuning strategy is chosen to complete the temperature field reconstruction and thermophysical parameter recognition. • The complex problem of heat transfer through different material layers and heat flow conditions can be solved by the proposed method. • The training efficiency of the model is improved by more than 7 times through transfer learning . Thermal protection structures are key components of reusable launch vehicles. As an important basis for monitoring the health status of the vehicle, it is necessary to timely and accurately predict the full-field temperature response of the thermal protection structure. In this work, a novel model is proposed for solving this problem based on physical information neural network (PINN) and transfer learning techniques, in which both the direct and inverse heat conduction problems are involved. A thermal protection structure (TPS) is taken as the research object. The corresponding simulation model is obtained based on the experimental model, which is used to train the PINN pre-model and to verify the validity and accuracy of the pre-model. Combining pre-model and limited experimental data, three different fine-tuning strategies are utilized for transfer learning. Furthermore, the PINN model obtained based on the optimal fine-tuning strategy is chosen to complete the temperature field reconstruction and thermophysical parameter recognition. Results demonstrate that the proposed method not only solves the complex problem of heat transfer across material layers but also performs well in the face of complex heat flow conditions. The experimental model obtained under the fine-tuning strategy of freezing the first two fully connected layers not only performs better in terms of accuracy and efficiency but also has the best stability during training. The training efficiency of the model is improved by more than 7 times through transfer learning. This suggests the desirability of combining transfer learning and PINN to construct experimental models dealing with direct and inverse heat conduction problems.
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