Development of Advanced Compressor Airfoils for Heavy-Duty Gas Turbines: Part I — Design and Optimization

Köller, Ulf D.; Mönig, Reinhard; Küsters, Bernhard; Schreiber, H. A.

doi:10.1115/99-gt-095

Cited by 38 publications

(31 citation statements)

References 18 publications

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“…Equation 2 , and w 3 are the weights of each term at the objective function. These weights were used to dictate design philosophies to the design system [16].…”

Section: Problem Descriptionmentioning

confidence: 99%

“…Blade curvature distribution can be changed using the weight function, H (x), which has been defined as a linear combination of three sinusoidal-shape function illustrates by Eq. (16). The weighing coefficients, y i , are the outer-loop variables which are determined through multi-level optimization process.…”

Section: Firs-level Optimization By Curvature Distribution Assessmentmentioning

confidence: 99%

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Multi-Level Multi-Objective Multi-Point Optimization System for Axial Flow Compressor 2D Blade Design

Fathi

Shadaram

2013

Arab J Sci Eng

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This paper introduces a multi-level framework to perform a multi-objective multi-point aerodynamic optimization of the axial compressor blade. This framework results in a considerable speed-up of the design process by reducing both the design parameters and the computational effort. To reduce the computational effort, optimization procedure is working on two levels of sophistication. Fast but approximate prediction methods has been used to find a near-optimum geometry at the firs-level, which is then further verified and refined by a more accurate but expensive Navier-Stokes solver. Surface curvature optimization was carried out in a first-level as a meta-function. Genetic algorithm and gradient-based optimization were used to optimize the parameters of first-level and second-level, respectively. This procedure considers both the aerodynamic and mechanical constraints. An initial blade has been optimized with three different design targets to highlight the ability of the design method and to develop design know-how. Leading-edge shape and curvature distributions of pressure and suction surface had major effects on the design philosophies of the blades. The result shows about −22.5 % reductions in pressure-loss coefficient at design condition and 23.6 % improvement in the allowable incidence-angle range at offdesign conditions compared to the initial blade.

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“…Equation 2 , and w 3 are the weights of each term at the objective function. These weights were used to dictate design philosophies to the design system [16].…”

Section: Problem Descriptionmentioning

confidence: 99%

Section: Firs-level Optimization By Curvature Distribution Assessmentmentioning

confidence: 99%

Multi-Level Multi-Objective Multi-Point Optimization System for Axial Flow Compressor 2D Blade Design

Fathi

Shadaram

2013

Arab J Sci Eng

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“…On the right hand side, the loss-incidence characteristics show The profile section isentropic Mach number distribution is shown in Figure 7, left. It can be seen that the DLR airfoil shows a more frontloaded design, often seen in new airfoil development projects, such as Siemens HPA-Airfoils (see Köller et al [25] and Küsters et al [26]). It is still subsonic in OP0.…”

Section: Airfoil Optimizationmentioning

confidence: 99%

Advanced Endwall Contouring for Loss Reduction and Outflow Homogenization for an Optimized Compressor Cascade

Reutter

Rozanski

Hergt

et al. 2017

IJTPP

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Abstract:The following paper deals with the development of an optimized non-axisymmetric endwall contour for reducing the total pressure loss and for homogenizing the outflow of a highly-loaded compressor cascade. In contrast to former studies using a NACA-65 K48 cascade airfoil this study starts with the design of a new high-performance airfoil which is based on the aerodynamic boundary conditions of the NACA-65 K48 cascade. This new airfoil is then used as a basis. Optimizations of the airfoil and of the endwall contour are performed using the German Aerospace Center (DLR) in-house tool AutoOpti and the RANS (Reynolds-averaged Navier-Stokes)-solver TRACE (Turbomachinery Research Aerodynamic Computational Environment). Three operating points at an inflow Mach number of 0.67 with different inflow angles are used to secure a wide operating range. The optimized endwall contour changes the secondary flow in such a way that the corner stall is reduced which, in turn, significantly reduces the total pressure loss. The endwall contour in the outflow region leads to a considerable homogenization of the outflow in the near wall region. Using non-axisymmetric endwall shaping demonstrates a valuable measure to further improve highly-efficient compressor blading on the vane level.

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“…Meanwhile, much attention has been paid to the study of numerical optimization in design optimization of turbomachinery, and successful applications can be seen in literature [4][5][6].…”

Section: Introductionmentioning

confidence: 99%

New response surface model and its applications in aerodynamic optimization of axial compressor blade profile

Xiao-jia

Ning

2008

Front. Energy Power Eng. China

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A parametric method for the axial compressor 2D blade profiles is proposed in which the blade geometries are defined with the parameters commonly used for blade definition, which ensures that the geometric significance is clear and an unreasonable blade profile is not generated. Several illustrations are presented to show the fitting precision of the method. A novel response surface model is proposed which regards the objective distribution function in the vicinity of a sample as normal school, and then generates the response surface function in the whole design space by a linear combination of distribution functions of all the samples. Based on this model, a numerical aerodynamic optimization platform for the axial compressor 2D blade profiles is developed, by which aerodynamic optimization of two compressor blade profiles are presented.

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Development of Advanced Compressor Airfoils for Heavy-Duty Gas Turbines: Part I — Design and Optimization

Cited by 38 publications

References 18 publications

Multi-Level Multi-Objective Multi-Point Optimization System for Axial Flow Compressor 2D Blade Design

Multi-Level Multi-Objective Multi-Point Optimization System for Axial Flow Compressor 2D Blade Design

Advanced Endwall Contouring for Loss Reduction and Outflow Homogenization for an Optimized Compressor Cascade

New response surface model and its applications in aerodynamic optimization of axial compressor blade profile

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