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Knowledge enhanced modeling of low-pressure turbine profile loss by combining physical-based and data-driven methods

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  • Liu, Changxing
  • Zou, Zhengping
  • Fu, Chao
  • Zeng, Jun
  • Li, Wei

Abstract

Appropriate modeling methods are essential for establishing models of energy systems, especially when the physical mechanisms are complex. A modeling method organically combined physical-based and data-driven is developed to ensure accuracy, generalization and interpretability while keeping a reasonable amount of required data. Utilizing the method, a comprehensive loss model for low-pressure turbine profile is established. The model considers freestream turbulence intensity and periodic wakes and accounts for flow modes of separation-reattachment and separation-non-reattachment. The model not only predicts loss at design and off-design points but also provides transition and reattachment locations. For physics-based modeling, the flow is spatially and temporally divided and modeled. In the data-driven part, over 450 sets of experimental data are utilized for coefficients optimization and validation. The model demonstrates high accuracy, with a relative error of less than 8 % for trailing edge momentum thickness and less than 3 % and 4 % for transition and reattachment locations, respectively. In the context of low-pressure turbine profile design guidelines, a front-loaded and high leading-edge load design is recommended. However, excessive leading-edge load can lead to increased loss, the leading-edge load integral (LEI) is suggested not to exceed 0.6. An appropriate front-loaded and high LEI design can achieve optimal performance.

Suggested Citation

  • Liu, Changxing & Zou, Zhengping & Fu, Chao & Zeng, Jun & Li, Wei, 2025. "Knowledge enhanced modeling of low-pressure turbine profile loss by combining physical-based and data-driven methods," Energy, Elsevier, vol. 320(C).
    • Handle: RePEc:eee:energy:v:320:y:2025:i:c:s036054422500756x
    DOI: 10.1016/j.energy.2025.135114
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    References listed on IDEAS

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    1. Dong, Xianzhou & Guo, Weiyong & Zhou, Cheng & Luo, Yongqiang & Tian, Zhiyong & Zhang, Limao & Wu, Xiaoying & Liu, Baobing, 2024. "Hybrid model for robust and accurate forecasting building electricity demand combining physical and data-driven methods," Energy, Elsevier, vol. 311(C).
    2. Zhang, Ce & Hou, Beiran & Li, Minxia & Dang, Chaobin & Tong, Huan & Li, Xiuming & Han, Zongwei, 2024. "Refrigerant charge estimation method based on data-physic hybrid-driven model for the fault diagnosis of transcritical CO2 heat pump system," Energy, Elsevier, vol. 309(C).
    3. Liu, Changxing & Zou, Zhengping & Xu, Pengcheng & Wang, Yifan, 2024. "Development of helium turbine loss model based on knowledge transfer with neural network and its application on aerodynamic design," Energy, Elsevier, vol. 297(C).
    4. Zhou, Jun & Qin, Can & Fu, Tiantian & Liu, Shitao & Liang, Guangchuan & Li, Cuicui & Hong, Bingyuan, 2024. "Automatic response framework for large complex natural gas pipeline operation optimization based on data-mechanism hybrid-driven," Energy, Elsevier, vol. 307(C).
    5. Liu, Yi & Wang, Ranpeng & Gu, Yin & Li, Congjian & Wang, Gangqiao, 2024. "Physics-inspired and data-driven two-stage deep learning approach for wind field reconstruction with experimental validation," Energy, Elsevier, vol. 298(C).
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