Multi-Objective Design Optimization of Cooling Turbine Blade Based on Kriging Model

Liang Bo Ao; Lei Li; Yuan Sheng Li; Zhi Xun Wen; Zhu Feng Yue

doi:10.4028/www.scientific.net/AMM.184-185.316

Paper Titles

Measurement and Calibration of the Displacement and Pressure in Automatic Wheelset Assembly Machine
p.296

Mechanical Analysis of Disc Cam Mechanisms with Negative Radius Roller Translating Follower
p.301

Modal Analysis of Eccentric Rotor for Multi-Layer Leather High-Speed Cutting Machine Based on Bond Graph Method
p.307

Modeling and Algorithm of Adaptive Gas Cooling Subsystem for Direct Metallic Component Manufacturing
p.312

Multi-Objective Design Optimization of Cooling Turbine Blade Based on Kriging Model
p.316

Non-Uniform Motion Mechanisms Utilized in a Twin-Rotor Piston Engine
p.320

Numerical Analysis of Axisymmetric Nozzle Aerodynamic Characteristics
p.324

Numerical Analysis of Fluid-Structure Interaction during Ignition Process for Solid Rocket Motor with Stress-Reliver
p.328

Numerical Simulation and Optimization of Cooling Ducts Layout in Hot Stamping Die
p.333

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 184-185Multi-Objective Design Optimization of Cooling...

Multi-Objective Design Optimization of Cooling Turbine Blade Based on Kriging Model

Abstract:

The multi-objective design optimization of cooling turbine blade is studied using Kriging model. The optimization model is created, with the diameter of pin fin at the trailing edge of cooling turbine blade and the location, width, height of rib as design variable, the blade body temperature, flow resistance loss and aerodynamic efficiency as optimization object. The sample points are selected using Latin hypercube sampling technique, and the approximate model is created using Kriging method, the set of Pareto-optimal solutions of optimization objects is obtained by the multi-object optimization model using elitist non-dominated sorting genetic algorithm (NSGA-Ⅱ) based on the approximate model. The result shows that the conflict among all optimization objects is solved effectively and the feasibility of the optimization method is improved.