Applications
Multi-Objective Optimisation of a Centrifugal Pump Stage by Means of Design of Experiment Coupled with Inverse Design Method
Design High Performance Axial Turbine Stages with More Uniform Exit Flow
Design of an Automobile Torque Converter
Design Optimisation of a Strongly Interacting Diffuser Pump Stage
Design of a Double-Suction Fan Stage
Design of a Double-Suction Volute Pump
Design of a 3 Stage Axial LP Turbine for Aeroengine Applications
Design High Performance Centrifugal Compressor Vaned Diffusers
Design of High Performance Pump Stage
Design of a Cooling Fan
Redesign of an Industrial Compressor Stage
Design of Refrigeration Compressor Stage in R134a
Hydraulic Design Optimisation of a Torque Converter
Design of an Inducer Pump with High Suction Performance and Backflow Control
Design High Efficiency Impellers with Splitter Blades
Design High Performance Centrifugal Compressor Impellers
Publications
- Hydraulic development of high specific-speed Pump-turbines by means of an inverse design method, numerical flowsimulation (CFD) and model testing
- Suppression of Cavitation in a Francis Turbine Runner By Application of 3D Inverse Design Method
- An Inverse Design Based Methodology for Rapid 3D Multi-Objective / Multi-Disciplinary Optimisation of Axial Turbines
- Choice of Optimum Blade Loading in Application of 3D Inverse Design to Design of Pumps and Fans.
- Suppression of Secondary Flows in a Turbine Nozzle with Controlled Stacking Shape and Exit Circulation by 3D Inverse Design Method
Case Studies
- Application of TURBOdesign1 to the Development of an In-line Type Hydraulic Turbine for Micro Power Generation - KUBOTA
- Design of a Compact Reactor Coolant Pump with Higher Efficiency and Cavitation Performance by using TURBOdesign1
- TURBOdesign1 is Extensively Used at Voith Turbo for the Design of Hydrodynamic Torque Converters
- Design of a Second Stage Hydrogen Rocket Turbopump by TURBOdesign1
- Design of Mixed Flow Pump Stage Using TURBOdesign1 and CFD Code, Hyosung-Ebara
Parametric Design of a Francis Turbine Runner by Means of a Three-Dimensional Inverse Design Method
Abstract. The present paper describes the parametric design of a Francis turbine runner. The
runner geometry is parameterized by means of a 3D inverse design method, while CFD
analyses were performed to assess the hydrodymanic and suction performance of different
design configurations that were investigated. An initial runner design was first generated and
used as baseline for parametric study. The effects of several design parameter, namely stacking
condition and blade loading was then investigated in order to determine their effect on the
suction performance. The use of blade parameterization using the inverse method lead to a
major advantage for design of Francis turbine runners, as the three-dimensional blade shape is
describe by parameters that closely related to the flow field namely blade loading and stacking
condition that have a direct impact on the hydrodynamics of the flow field. On the basis of this
study, an optimum configuration was designed which results in a cavitation free flow in the
runner, while maintaining a high level of hydraulic efficiency. The paper highlights design
guidelines for application of inverse design method to Francis turbine runners. The design
guidelines have a general validity and can be used for similar design applications since they are
based on flow field analyses and on hydrodynamic design parameters.