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Wing Planform Optimization via an Adjoint Method

Wing Planform Optimization via an Adjoint Method. Kasidit Leoviriyakit Department of Aeronautics and Astronautics Stanford University, Stanford CA Stanford University Stanford, CA June 28, 2005. History: Adjoint for Transonic Wing Design.

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Wing Planform Optimization via an Adjoint Method

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  1. Wing Planform Optimization via an Adjoint Method Kasidit Leoviriyakit Department of Aeronautics and Astronautics Stanford University, Stanford CA Stanford University Stanford, CA June 28, 2005

  2. History: Adjoint for Transonic Wing Design Redesign for a shock-free wing by modify the wing sections (planform fixed ) – Jameson 1995 - Cp Baseline 747, CD 117 counts Redesigned, CD 103 counts

  3. Break Down of Drag Boeing 747 at CL ~ .52 (including fuselage lift ~ 15%) Induced Drag is the largest component

  4. Key Concept Use “shock-free” concept to drive the planform design. • Conventionally the wing is swept to weaken the shock. • With the “shock-free” wing capability, it allows more configurations that was previously prohibited by the strong shock.

  5. Aerodynamic Design Tradeoffs If we want to have large drag reduction, we should target the induced drag. Change span by changing planform Design dilemma Di decreases Increase b WO increases

  6. Can we consider only pure Aerodynamic design? • Pure aerodynamic design leads to unrealistic results • Constraints sometimes prevent optimal results • Example 1: Vary b to minimize drag I = CD As span increases, vortex drag decreases.  Infinitely long span • Example 2: Add a constraint;  b =bmax There is no need for optimization • Also true for the sweep variation

  7. Wing planform modification can yield larger improvements BUT affects structural weight. Cost Function Simplified Planform Model Can be thought of as constraints

  8. Choice of Weighting Constants Minimizing Maximizing Range using

  9. Structural Model for the Wing • Assume rigid wing • (No dynamic interaction between Aero and Structure) • Use fully-stressed wing box to estimate the structural weight • Weight is calculated from material of the skin

  10. Design Parameters Using 4224 mesh points on the wing as design variables Boeing 747 Plus 6 planform variables Use Adjoint method to calculate both section and planform sensitivities

  11. Optimization and Design using Sensitivities Calculated by the Finite Difference Method f(x)

  12. Disadvantage of the Finite Difference Method The need for a number of flow calculations proportional to the number of design variables Using 4224 mesh points on the wing as design variables 4231 flow calculations ~ 30 minutes each (RANS) Too Expensive Boeing 747 Plus 6 planform variables

  13. Application of Control Theory (Adjoint) GOAL : Drastic Reduction of the Computational Costs Drag Minimization Optimal Control of Flow Equations subject toShape(wing) Variations (for example CDat fixed CL) (Euler & RANS in our case)

  14. Application of Control Theory 4230 design variables One Flow Solution + One Adjoint Solution

  15. Flow solution Adjoint solution Gradient calculation Repeated until Convergence to Optimum Shape Sobolev gradient Shape & Grid Modification Outline of the Design Process • Design Variables • 4224 surface mesh points • for the NS design • (or 2036 for the Euler design) • 6 planform parameters • -Sweep • -Span • -Chord at 3span –stations • -Thickness ratio

  16. Design using the Navier-Stokes Equations

  17. Adjoint Equations

  18. Adjoint Boundary Condition

  19. Viscous Gradient Comparison: Adjoint Vs Finite Difference Sweep croot Sweep Span croot cmid ctip t cmid ctip t Span • Adjoint gradient in red • Finite-different gradient in blue

  20. Key issue for successful implementation of the Continuous adjoint method. Sobolev Gradient Continuous descent path

  21. Viscous Results B747 MD11 BAe MDO Datum

  22. B747 Planform Changes Mach .85 Fixed CL .45 baseline redesigned

  23. B747 @ Mach .85, Fixed CL .45 Viscous-Redesigned using Syn107 (RANS Optimization) Baseline

  24. Design Short-Cut Use Euler planform optimization as a starting point for the Navier-Stokes Optimization Euler Optimized NS Optimized

  25. Redesigned Planform of Boeing 747 • Longer span reduces the induced drag • Less sweep and thicker wing sections reduce the structural weight • Section modification keeps the shock drag minimum • Overall: Drag and Weight Savings • No constraints posted on planform, but we still get a finite wing with less than 90 degrees sweep.

  26. MD11 Planform ChangesMach .83, Fixed CL .50 baseline redesigned

  27. MD11 @Mach .83, Fixed CL .5 • “Same Trend” • Span increases • Sweep decreases • t/c increases • Shock minimized Redesign Baseline

  28. BAe Planform ChangesMach .85 Fixed CL .45 baseline redesigned

  29. BAe MDO Datum @ Mach .85, Fixed CL .45 “Same Trend” but not EXTREME Redesign Baseline

  30. Pareto Front: “Expanding the Range of Designs” • The optimal shape depends on the ratio of a3/a1 • Use multiple values a3/a1to capture the Pareto front • (An alternative to solving the optimality condition)

  31. Pareto Front of Boeing 747

  32. Appendix

  33. ConstraintsEnforced in SYN107 and SYN88 • For drag minimization • Fixed CL • Fixed span load • Keep out-board CL low enough to prevent buffet • Fixed root bending moment • Maintain specified thickness • Sustain root bending moment with equal structure weight • Maintain fuel volume • Smooth curvature variations via Sobolev gradient

  34. Point Gradient Calculation for the wing sections • Use the surface mesh points as the section design variable • Perturb along the mesh line  Avoid mesh crossing over

  35. Planform Gradient Calculation E.g.. Gradient with respect to sweep change

  36. Planform Gradient Calculation Surface Domain

  37. References • Leoviriyakit, K.,"Wing Planform Optimization via an Adjoint Method," Ph.D. Dissertation, Stanford University, March 2005. • Leoviriyakit, and Jameson, A., "Multi-point Wing Planform Optimization via Control Theory", 43rd Aerospace Sciences Meeting and Exhibit, AIAA Paper 2005-0450, Reno, NV, January 10-13, 2005 • Leoviriyakit, K., Kim, S., and Jameson, A., "Aero-Structural Wing Planform Optimization Using the Navier-Stokes Equations", 10th AIAA/ISSMO Multidisciplinary Analysis and Optimization Conference, AIAA Paper 2004-4479, Albany, New York, 30 August - 1 September 2004 • Leoviriyakit, K., and Jameson, A., "Case Studies in Aero-Structural Wing Planform and Section Optimization", 22nd Applied Aerodynamics Conference and Exhibit, AIAA Paper 2004-5372, Providence, Rhode Island, 16-19 August 2004 • Leoviriyakit, K. and Jameson, A., "Challenges and Complexity of Aerodynamic Wing Design ", International Conference on Complex Systems (ICCS2004), Boston, MA, May 16-21, 2004. • Leoviriyakit, K., and Jameson, A., "Aero-Structural Wing Planform Optimization", 42nd AIAA Aerospace Sciences Meeting and Exhibit, AIAA Paper 2004-0029, Reno, Nevada, 5-8 January 2004 • Leoviriyakit, K., Kim, S., and Jameson, A., "Viscous Aerodynamic Shape Optimization of Wings Including Planform Variables", 21st Applied Aerodynamics Conference, AIAA Paper 2003-3498 , Orlando, Florida, 21-22 June 2003 • Kim, S., Leoviriyakit, K., and Jameson, A., "Aerodynamic Shape and Planform Optimization of Wings Using a Viscous Reduced Adjoint Gradient Formula", Second M.I.T. Conference on Computational Fluid and Solid Mechanics at M.I.T., Cambridge, MA, June 17-20, 2003 • Leoviriyakit, K. and Jameson, A., "Aerodynamic Shape Optimization of Wings including Planform Variations", 41st AIAA Aerospace Sciences Meeting and Exhibit, AIAA Paper 2003-0210, Reno, NV, January 6-9, 2003.

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