Development of Advanced Compressor Airfoils for Heavy-Duty Gas Turbines: Part II — Experimental and Theoretical Analysis

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

doi:10.1115/99-gt-096

Cited by 23 publications

(14 citation statements)

References 11 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In contrary, it is better to have a strong acceleration and deceleration close to the leading edge where the turbulent boundary layer is thin and to reduce the deceleration towards the trailing edge where the boundary layer is thicker. Airfoil shapes which are similar to the obtained designs were investigated numerically and experimentally by and Küsters et al (2000). The profiles were also highly front-loaded and showed an early transition.…”

Section: Optimization Resultsmentioning

confidence: 62%

Automated Design Optimization of Compressor Blades for Stationary, Large-Scale Turbomachinery

̈che

Guidati

Stoll

2003

Volume 6: Turbo Expo 2003, Parts a and B

View full text Add to dashboard Cite

An automated, multi-disciplinary optimization procedure for sub-sonic gas turbine compressor blades is presented. Evolutionary optimization algorithms are coupled with existing tools for geometry generation, mechanical integrity analysis and Q3D flow analysis for design and off-design conditions. Aerodynamic and mechanical objectives and constraints are formulated based on the standard design criteria. The feasibility of the approach is tested by automatically designing different rotor blades for the subsonic compressor region. First results are promising. All rotor blades show similar profile shapes, which underlines the robustness of the optimization procedure. The blades are characterized by a pronounced front loading which leads to a large (predicted) operating range. A special focus in this paper is on a 3D-blade parameterization, which by default leads to smooth blades, and on the assessment of the off-design behavior. The considered optimization algorithm shows a fast and robust convergence even from randomly initialized blades.

show abstract

Section: Optimization Resultsmentioning

confidence: 62%

Automated Design Optimization of Compressor Blades for Stationary, Large-Scale Turbomachinery

̈che

Guidati

Stoll

2003

Volume 6: Turbo Expo 2003, Parts a and B

View full text Add to dashboard Cite

show abstract

“…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

View full text Add to dashboard Cite

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.

show abstract

“…Pierret, 1999 used an artificial neural network coupled with a Navier-Stokes solver to maximize the efficiency and/or operating range of two-dimensional compressor cascades and then staggered them in radial direction to obtain the three dimensional blade. Köller et al, 2000 andKüsters et al, 2000 developed a new family of compressor airfoils, characterized by low total pressure losses and larger operating range with respect to standard Controlled Diffusion Airfoils (CDA), using a gradient optimization method and an inviscid/viscous code. Until today, the use of evolutionary techniques in combination with CFD codes for solving multi-objective optimization problems in compressor aerodynamics has been limited by the tremendous computational effort required.…”

Section: Direct Methodsmentioning

confidence: 99%

Advances in Aerodynamic Design of Gas Turbines Compressors

Benini¹

2010

Gas Turbines

View full text Add to dashboard Cite

Development of Advanced Compressor Airfoils for Heavy-Duty Gas Turbines: Part II — Experimental and Theoretical Analysis

Cited by 23 publications

References 11 publications

Automated Design Optimization of Compressor Blades for Stationary, Large-Scale Turbomachinery

Automated Design Optimization of Compressor Blades for Stationary, Large-Scale Turbomachinery

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

Advances in Aerodynamic Design of Gas Turbines Compressors

Contact Info

Product

Resources

About