Download presentation
Presentation is loading. Please wait.
1
1 ERIC WHITNEY (USYD) FELIPE GONZALEZ (USYD) Applications to Fluid Mechanics @ Inaugural Workshop for FluD Group : 28th Oct 2003. AMME Conference Room Supervisor: K. Srinivas Dassault Aviation: J. Périaux
2
2 Overview Aim: Develop modern numerical and evolutionary optimisation techniques for number of problems in the field of Aerospace, Mechanical and Mechatronic Engineering. In Fluid Mechanics we are particularly interested in optimising fluid flow around different aerodynamic shapes: Single and multi-element aerofoils. Wings in transonic flow. Propeller blades. Turbomachinery aerofoils. Full aircraft configurations. We use different structured and unstructured mesh generation and CFD codes in 2D and 3D ranging from full Navier Stokes to potential solvers.
3
3 CFD codes q Developed at the school MSES/MSIS - Euler + boundary layer interactive flow solver. The external solver is based on a structural quadrilateral streamline mesh which is coupled to an integral boundary layer based on a multi layer velocity profile representation. m HDASS : A time marching technique using a CUSP scheme with an iterative solver. m Vortex lattice method m Propeller Design q Requested to the author m MSES/MSIS - Euler + boundary layer interactive flow solver. The external solver is based on a structural quadrilateral streamline mesh which is coupled to an integral boundary layer based on a multi layer velocity profile representation m ParNSS ( Parallel Navier--Stokes Solver) m FLO22 ( A three dimensional wing analysis in transonic flow suing sheared parabolic coordinates, Anthony Jameson) m MIFS (Multilock 2D, 3D Navier--Stokes Solver) q Free on the Web m nsc2kec : 2D and AXI Euler and Navier-stokes equations solver m vlmpc : Vortex lattice program
4
4 Evolutionary Algorithms What are Evolutionary Algorithms? Computers can be adapted to perform this evolution process. Crossover Mutation Fittest Evolution EAs are able to explore large search spaces and are robust towards noise and local minima, are easy to parallelise. EAs are known to handle approximations and noise well. EAs evaluate multiple populations of points. EAs applied to sciences, arts and engineering. Populations of individuals evolve and reproduce by means of mutation and crossover operators and compete in a set environment for survival of the fittest.
5
Model 1 precise model Model 2 intermediate model Model 3 approximate model Exploration Exploitation qWe use a technique that finds optimum solutions by using many different models, that greatly accelerates the optimisation process. Interactions of the 3 layers: solutions go up and down the layers. qTime-consuming solvers only for the most promising solutions. qParallel Computing-BORGS Evolution Algorithm Evaluator HIERARCHICAL ASYNCHRONOUS PARALLEL EVOLUTION ALGORITHMS (HAPEA)
6
6 Current and Ongoing CFD Applications Transonic Viscous Aerodynamic Design Multi-Element High Lift Design Propeller Design Formula 3 Rear Wing Aerodynamics Problem Two Element Aerofoil Optimisation Problem Transonic Wing Design Aircraft Design and Multidisciplinary Optimisation UAV Aerofoil Design 2D Nozzle Inverse Optimisation
7
7 Outcomes of the research qThe new technique with multiple models: Lower the computational expense dilemma in an engineering environment (at least 3 times faster than similar approaches for EA) qThe new technique is promising for direct and inverse design optimisation problems. qAs developed, the evolution algorithm/solver coupling is easy to setup and requires only a few hours for the simplest cases. qA wide variety of optimisation problems including Multi-disciplinary Design Optimisation (MDO) problems could be solved. qThe benefits of using parallel computing, hierarchical optimisation and evolution algorithms to provide solutions for multi-criteria problems has been demonstrated.
Similar presentations
© 2024 SlidePlayer.com. Inc.
All rights reserved.