Accelerating Finite Element Analysis of Dynamic Impact Response of TiN/Ti Multilayer Coatings Based on Small Sample Machine Learning
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摘要: 服役于极端环境下的发动机高压涡轮叶片,因长期承受高温燃气携带的沙尘颗粒的高速撞击,使役寿命会大幅降低。TiN/Ti多层涂层凭借其高硬、高韧的特性成为叶片表面涂层的首选材料。然而,其抗冲蚀性能与其结构参数紧密相关,传统的实验试错法与有限元模拟往往耗时耗力。为了解决这一困境,提出了一个基于小样本机器学习(machine learning,ML)与有限元分析融合的TiN/Ti多层涂层设计框架。评估了多种回归算法,并优选出高斯过程回归模型,实现了涂层在动态冲击下的层内最大应力与基体最大塑性应变的高精度预测(决定系数R2分别为0.88和0.85)。结合残差与不确定性分析,进一步强化了模型的拟合能力。此外,通过SHAP(shapley additive explanations)模型分析揭示各特征对目标的影响。最终设计了8种新的结构与冲击条件下的涂层仿真模型,并验证了ML模型预测结果的准确性。该框架为高维参数空间下涂层抗冲击设计提供了数据高效、计算经济的解决方案。
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关键词:
- TiN/Ti多层涂层 /
- 机器学习 /
- 有限元分析 /
- 动态冲击
Abstract: Engine high-pressure turbine blades operating in extreme environments, such as deserts, are subjected to long-term high-velocity impacts from sand particles carried by hot combustion gases, significantly reducing their service life. Owing to its high hardness and toughness, the TiN/Ti multilayer coating has emerged as a preferred surface coating material for such blades. However, its erosion resistance is highly dependent on structural parameters, and traditional experimental trial-and-error methods and finite element simulations are often time-consuming and labor-intensive. To address this challenge, this study proposes a TiN/Ti multilayer coating design framework that integrates small-sample machine learning (ML) with finite element analysis. Multiple regression algorithms were evaluated, and Gaussian process regression (GPR) was selected for its superior performance, enabling high-accuracy prediction of the maximum intralayer stress and the maximum plastic strain in the substrate under dynamic impact conditions (with R2 values of 0.88 and 0.85, respectively). The modelʼs fitting capability was further enhanced through residual and uncertainty analyses. Moreover, shapley additive explanations (SHAP) analysis was employed to elucidate the contribution of each feature to the target variables. Finally, eight new coating structures under varying impact conditions were designed and simulated to validate the predictive accuracy of the ML model. This framework offers a data-efficient and computationally economical solution for impact-resistant coating design in high-dimensional parameter spaces.-
Key words:
- TiN/Ti multilayer coating /
- machine learning /
- finite element analysis /
- dynamic impact
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图 3 不同算法针对目标建模精度(R2)的对比
Figure 3. Comparison of target modeling accuracy (R2) for different algorithms
图 4 6种不同算法建模结果的对比
Figure 4. Comparison of modeling results from six different algorithms
图 5 以层内最大应力为目标的GPR超参数优化建模结果及分析
Figure 5. Modeling results and analysis of GPR hyperparameter optimization targeting the maximum stress within a layer
图 6 以基体最大塑性应变为目标的GPR超参数优化建模结果及分析
Figure 6. Modeling results and analysis of GPR hyperparameter optimization targeting maximum plastic strain of the matrix
图 9 机器学习模型预测结果与真实值的对比
Figure 9. Comparison of machine learning model predictions with actual values
表 1 原始数据集
Table 1. Original dataset
Feature Target α/(°) v/(m·s−1) h/μm N $ \lambda $ σmax/GPa εmax 15 100 24 8 4 1.65 0.11 30 100 24 8 4 2.66 0.16 45 100 24 8 4 3.51 0.21 60 100 24 8 4 4.01 0.22 75 100 24 8 4 4.37 0.24 90 100 24 8 4 4.54 0.25 90 75 24 8 2 2.72 0.18 90 100 24 8 2 3.53 0.25 90 125 24 8 2 5.21 0.44 90 150 24 8 2 7.84 0.68 90 100 12 2 4 8.64 0.33 90 100 16 2 4 7.65 0.32 90 100 20 2 4 6.84 0.31 90 100 24 2 4 5.68 0.29 90 100 24 2 4 5.67 0.29 90 100 24 6 4 5.12 0.28 90 100 24 8 4 4.52 0.25 90 100 24 12 4 3.99 0.23 90 100 24 8 2 3.53 0.25 90 100 24 8 4 4.52 0.26 90 100 24 8 11 5.89 0.35 90 100 24 8 19 6.36 0.47 
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表 2 TiN/Ti多层涂层有限元建模结构参数及冲击条件设定
Table 2. Finite element modeling of TiN/Ti multilayer coating structural parameters and impact condition settings
Case α/(°) v/(m·s−1) h/μm N $ \lambda $ C1 30 100 24 48 2 C2 60 100 24 48 2 C3 90 100 24 48 2 C4 30 200 24 48 2 C5 60 200 24 48 2 C6 90 200 24 48 2 C7 90 200 24 24 2 C8 90 200 24 12 2
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表 3 Ti6Al4V、TiN、Ti和Al2O3的基本参数
Table 3. Basic parameters of Ti6Al4V, TiN, Ti, and Al2O3
Material ρ/(kg·m−3) E/GPa ν Ti6Al4V 4 428 113.8 0.34 TiN 5 400 480.0 0.27 Ti 4 500 110.0 0.33 Al2O3 3 970 344.0 0.20
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表 4 基体Ti6Al4V与Ti的J-C本构参数
Table 4. J-C constitutive parameters of the matrix Ti6Al4V and Ti
Material A/MPa B/MPa n0 C $ {\dot{\varepsilon }}_{0} $/s–1 D1 D2 D3 D4 D5 Ti6Al4V 1 098 1 092 0.93 0.014 1 –0.090 0.27 0.48 0.014 3.87 Ti 309 80 0.16 0.060 1 0.145 0.33 0.48 0.004 3.90
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表 5 8组涂层层内最大应力与基体最大塑性应变的真实值与预测值对比结果
Table 5. Comparison between the predicted and actual values of the maximum intralayer stress and the maximum plastic strain in the substrate for eight coating groups
Case σmax/GPa εmax True value Predicted value True value Predicted value C1 2.83 2.76 0.012 6 0.013 4 C2 3.42 3.51 0.017 4 0.018 9 C3 3.56 4.15 0.020 8 0.022 6 C4 6.12 6.19 0.018 4 0.019 7 C5 9.02 9.12 0.019 6 0.021 8 C6 11.41 12.52 0.023 4 0.026 1 C7 14.56 15.32 0.024 8 0.027 2 C8 17.37 16.81 0.029 9 0.030 3
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