A novel wasserstein autoencoder-enhanced thermo-mechanical coupled reduced-order model for high pressure turbine blades life monitoring

To facilitate effective assessment of loads (e.g., temperature and stress) and life management of high-pressure turbine (HPT) blades, a wasserstein autoencoder (WAE)-enhanced thermodynamically coupled reduced-order model (ROM) is proposed in this paper. The advanced ROM for the nonlinear thermomecha...

Full description

Saved in:
Bibliographic Details
Published in:Engineering applications of artificial intelligence Vol. 152; p. 110819
Main Authors: Wang, Rongqiao, Chen, Ruoqi, Zhao, Yan, Shen, Tianbao, Chen, Gaoxiang, Hu, Dianyin, Jiang, Zhimin, Wang, Xuemin
Format: Journal Article
Language:English
Published: Elsevier Ltd 15.07.2025
Subjects:
High-pressure turbine blade
Lifetime monitoring
Loading calculation
Reduced order model
Wasserstein autoencoder
Wasserstein autoencoder
Loading calculation
High-pressure turbine blade
Lifetime monitoring
Reduced order model
ISSN:0952-1976
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:To facilitate effective assessment of loads (e.g., temperature and stress) and life management of high-pressure turbine (HPT) blades, a wasserstein autoencoder (WAE)-enhanced thermodynamically coupled reduced-order model (ROM) is proposed in this paper. The advanced ROM for the nonlinear thermomechanical coupling fields is developed by introducing the deep learning model of WAE in the proper orthogonal decomposition (POD) method. The proposed method improves the prediction accuracy of loads in locally focused regions and generalization performance. The accuracy and efficiency of this method are validated through 30 sets of validation conditions. Results indicate that the proposed approach achieves higher accuracy and better generalization performance than traditional POD-based methods, with errors maintained within 10. Additionally, computational speed is improved by nearly 1400 times compared to conventional numerical methods. The WAE-enhanced ROM is applied for load and life assessment of the HPT blades throughout their service life. The evaluation time for a single aeroengine performance parameter is 1.7 s, and for a single flight evaluation, it is 67 s, which highlights the effectiveness of the proposed method in enabling the assessment of the loads and remaining life of HPT blades. •A novel WAE enhanced thermal coupling ROM is proposed for efficient HPT blade life assessment.•Through the WAE network, lots of POD modes are preserved and compressed into a low-dimensional latent variable space.•The ANN maps the performance parameters to the mode coefficients for fast and accurate temperature and stress evaluation.•The ROM is evaluated in 1.7 seconds for each operating condition and 67 seconds for each flight.
ISSN:0952-1976
DOI:10.1016/j.engappai.2025.110819