CFD-based blade shape optimization of MGT-70(3)axial flow compressor

Purpose This study aims at enhancing the performance of a 16-stage axial compressor and improving the operating stability. The adopted approaches for upgrading the compressor are artificial neural network, optimization algorithms and computational fluid dynamics. Design/methodology/approach The proc...

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Bibliographic Details
Published in:International journal of numerical methods for heat & fluid flow 2020-05, Vol.30 (6), p.3307-3321
Main Authors: Pakatchian, Mohammad Reza, Saeidi, Hossein, Ziamolki, Alireza
Format: Article
Language:English
Subjects:
Algorithms
Artificial neural networks
Automation
Compressors
Computational fluid dynamics
Design
Design optimization
Design parameters
Design techniques
Efficiency
Electricity generation
Fluid dynamics
Gas turbines
Genetic algorithms
Geometry
Hydrodynamics
Mathematical models
Methods
Numerical analysis
Parameterization
Reynolds number
Shape
Shape optimization
Simulation
Static pressure
Turbine engines
Turbocompressors
Turbulence models
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Summary:Purpose This study aims at enhancing the performance of a 16-stage axial compressor and improving the operating stability. The adopted approaches for upgrading the compressor are artificial neural network, optimization algorithms and computational fluid dynamics. Design/methodology/approach The process starts with developing several data sets for certain 2D sections by means of training several artificial neural networks (ANNs) as surrogate models. Afterward, the trained ANNs are applied to the 3D shape optimization along with parametrization of the blade stacking line. Specifying the significant design parameters, a wide range of geometrical variations are considered by implementation of appropriate number of design variables. The optimized shapes are analyzed by applying computational fluid dynamic to obtain the best geometry. Findings 3D optimal results show improvements, especially in the case of decreasing or elimination of near walls corner separations. In addition, in comparison with the base geometry, numerical optimization shows an increase of 1.15 per cent in total isentropic efficiency in the first four stages, which results in 0.6 per cent improvement for the whole compressor, even while keeping the rest of the stages unchanged. To evaluate the numerical results, experimental data are compared with obtained data from simulation. Based on the results, the highest absolute relative deviation between experimental and numerical static pressure is approximately 7.5 per cent. Originality/value The blades geometry of an axial compressor used in a heavy-duty gas turbine is optimized by applying artificial neural network, and the results are compared with the base geometry numerically and experimentally.
ISSN:0961-5539
0961-5539
1758-6585
DOI:10.1108/HFF-10-2018-0603