Adaptive prediction of turbine profile loss and multi-objective optimization in a wide incidence range

To rapidly and accurately predict turbine rotor blade losses within a wide range of incidences (−50–30 deg), graph neural networks (GNNs) are utilized to predict the aerodynamic parameters of two-dimensional turbine blades based on a small-scale experimental dataset. By comparing the backpropagation neural network (BPnn) model and computational fluid dynamics (CFD) results, it is demonstrated that GNNs with appropriately designed graph structures can accurately and quickly predict high-fidelity aerodynamic parameters based on limited experimental data. Unlike traditional data-driven modeling approaches, two innovative methods for improving blade profiles into graph structures are proposed. Relatively few input features are used to comprehensively and effectively represent the turbine blade profile by applying blade profile features in the GNN. The research findings indicate that due to the graph structure, which divides the turbine blade profile into five nodes based on five key points, coupled with high-fidelity experimental data and the unique weight updating mechanism of the graph attention network (GAT) model, the GAT-5 model exhibits the best performance among the studied models. Additionally, when assessing unknown validation blade profiles, the GAT-5 model maintains an absolute error below 6% at an incidence angle of 30 deg compared to the experimental results.

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Investigating endwall flow mechanisms and improving the loss model under diverse operating conditions

Wang,

Zhang,

Yin

et al. 2024

Proceedings of the Institution of Mechanical Engineers, Part A:

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Accurate prediction and comprehension of off-design turbine performance hold paramount importance in the development of highly efficient turbines capable of operating across a diverse range of conditions. This research concentrates on a highly loaded turbine cascade endwall flow and endeavors to scrutinize the impact of both incidence angle and inlet free stream turbulence intensity (FSTI). The investigation involves a meticulous analysis leading to substantial improvements in the existing endwall loss model (the Benner model correlated with the Moustapha incidence loss correction model), tailored for off-design scenarios. The findings underscore the pronounced influence of both incidence angle and FSTI on the dynamics of the endwall flow. Notably, alterations in the incidence angle have been identified as exerting a discernible impact on the flow structure, particularly when encountering large positive incidence angles. At an incidence angle of +20°, a distinctive vortex known as the Concentrated Shedding Vortex emerges as a pivotal factor in shaping the endwall flow structure, resulting in a substantial escalation in endwall losses. Furthermore, variations in FSTI predominantly affect the intensity of secondary vortices, thereby influencing endwall loss. Leveraging these discernments, an expressive formulation for endwall loss is derived by refining the higher-order terms of the incidence loss correction model and introducing a corrective term associated with FSTI. It has been validated that the proposed model controls the prediction error of endwall loss within a margin of ±0.02.

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Adaptive prediction of turbine profile loss and multi-objective optimization in a wide incidence range

Cited by 3 publications

References 40 publications

Toward high-lift low-solidity design for incidence tolerant gas turbine blade profile

Toward high-lift low-solidity design for incidence tolerant gas turbine blade profile

Aerodynamic Performance Prediction for Wide-Incidence Turbines Using Graph Neural Network Models Driven by Small-Scale Experimental Data

Investigating endwall flow mechanisms and improving the loss model under diverse operating conditions

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