Applications
Design of an Automobile Torque Converter
Design High Performance Centrifugal Compressor Vaned Diffusers
Design High Performance Axial Turbine Stages with More Uniform Exit Flow
Redesign of an Industrial Compressor Stage
Design High Efficiency Impellers with Splitter Blades
Design High Performance Centrifugal Compressor Impellers
Design of High Performance Pump Stage
Design of Refrigeration Compressor Stage in R134a
Design of a 3 Stage Axial LP Turbine for Aeroengine Applications
Design Optimisation of a Strongly Interacting Diffuser Pump Stage
Design of an Inducer Pump with High Suction Performance and Backflow Control
Design of a Cooling Fan
Design of a Double-Suction Fan Stage
Design of a Double-Suction Volute Pump
Multi-Objective Optimisation of a Centrifugal Pump Stage by Means of Design of Experiment Coupled with Inverse Design Method
Hydraulic Design Optimisation of a Torque Converter
Publications
- Investigation of an Inversely Designed Centrifugal Compressor Stage - Part II: Experimental Investigations
- Optimization of 6.2:1 Pressure Ratio Centrifugal Compressor Impeller by 3D Inverse Design
- On the Role of Three-Dimensional Inverse Design Methods in Turbomachinery Shape Optimization
- Suppression of Secondary Flows in a Turbine Nozzle with Controlled Stacking Shape and Exit Circulation by 3D Inverse Design Method
- On the Coupling of Inverse Design and Optimization Techniques for the Multiobjective, Multipoint Design of Turbomachinery Blades
Case Studies
- Improving Turbocharger Centrifugal Compressor Efficiency by TURBOdesign1 - Cummins Turbo
- TURBOdesign1 is Extensively Used at Voith Turbo for the Design of Hydrodynamic Torque Converters
- Inverse Design of Aeronautical Turbines in Avio S.p.A Design Process
- Design of a Compact Reactor Coolant Pump with Higher Efficiency and Cavitation Performance by using TURBOdesign1
- Design of a Second Stage Hydrogen Rocket Turbopump by TURBOdesign1
Investigation of an Inversely Designed Centrifugal Compressor Stage - Part I: Design and Numerical Verification
In this paper the three-dimensional inverse design code TURBOdesign1 is applied to the design of the blade geometry of a centrifugal compressor impeller with splitter blades. In the design of conventional impellers the splitter blades normally have the same geometry as the full blades and are placed at mid-pitch location between the two full blades, which can usually result in a mismatch between the flow angle and blade angles at the splitter leading edge. In the inverse design method the splitter and full blade geometry is computed independently for a specified distribution of blade loading on the splitter and full blades. In this paper the basic design methodology is outlined and then the flow in the conventional and inverse designed impeller is compared in detail by using computational fluid dynamics (CFD) code TASCflow. The CFD results confirm that the inverse design impeller has a more uniform exit flow, better control of tip leakage flow and higher efficiency than the conventional impeller. The results also show that the shape of the trailing edge geometry has a very appreciable effect on the impeller Euler head and this must be accurately modeled in all CFD computations to ensure closer match between CFD and experimental results. Detailed measurements are presented in part II of the paper.
Part II of this paper is available here: Investigation of an Inversely Designed Centrifugal Compressor Stage - Part II: Experimental Investigations