Applied Sciences (May 2024)

Multidisciplinary Design Optimization of Cooling Turbine Blade: An Integrated Approach with R/ICSM

  • Wenjun Wang,
  • Lan Xiang,
  • Enzi Kang,
  • Jiahao Xia,
  • Shanguang Shi,
  • Cunfu Wang,
  • Cheng Yan

DOI
https://doi.org/10.3390/app14114559
Journal volume & issue
Vol. 14, no. 11
p. 4559

Abstract

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This paper presents an efficient integrated multidisciplinary design optimization method for shaping a high-pressure cooling turbine blade in aero engines. This approach utilizes a novel regression/interpolation combination surrogate model (R/ICSM), facilitating comprehensive design optimization through collaborative coupling feature parameterization modeling and numerical simulation analysis across various disciplines. The optimized blade adjusts the load distribution on its surface, effectively eliminating flow separation at the tip and trailing edge. Notably, the optimized blade achieves a 0.69% increase in isentropic efficiency while satisfying aerodynamic, strength, and structural constraints. This highlights the effectiveness and progressiveness of the multidisciplinary design optimization method for a cooling turbine blade based on the R/ICSM in enhancing overall performance. It offers a novel and feasible approach for turbine blade design optimization and provides valuable insights for future research and applications.

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