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Published byBeverly Francis Modified over 6 years ago
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Delta-Wing Vortex Lift Enhancement Using Oblique Channel Distribution
Advisor: Dr. McClain Project Manager: Meag McNary Ruben Nunez Adam Eaker Ryan Parker Drew Waggoner ME LAB Final Presentation
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Overview Initial Objective Final Objective Theory Experimentation
Schedule Summary Results Significance Summary Recommendations Questions
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Initial Objective Quantify the steady flow effects of oblique element distributions interacting with vortical structures attached to a delta wing micro unmanned air vehicle Areas of interest: High angle of attack Roughness elements Lift and Drag
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Final Objective Quantify the steady flow effects of obliquely aligned channels interacting with vortical structures on a delta wing micro unmanned air vehicle Areas of interest: High angles of attack Low Reynolds Numbers Obliquely aligned channels Lift and Drag
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Theory – Delta Wing Seen in fighter aircraft where maneuverability and stability are crucial Highly swept wing Triangular planform Able to achieve higher angles of attack without stall At moderate to high angles of attack can generate increased lift with better aircraft stability and control Constraining mechanism to this effectiveness is the vortical flow at leading edge of wing
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Theory – Vortex Behavior
Unpredictable behavior Leading-edge vortices Induces additional lift by pressure decrease on suction surface Vortex breakdown Vortex expands into highly fluctuating structure Induced by high angles of attack or pressure rise Vortex separates from wing Disadvantages: Wing fluttering Loss of performance Decrease in lift Vortex Behavior is unpredictable. Understanding of vortex flow physics allows prediction techniques for macro and micro-electromechanical systems Counter-Rotating leading edge vortices Increase lift Vortex Breakdown
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Theory – Vortex Breakdown Control
Delay bursting of vortices Increases performance Controlled by increasing ωθ and induce secondary flow Methods: Mechanical Local action by contouring surface Pneumatic Introduce perturbations through air flow VL Vθ Leading-edge separation line Vortex separation line reattachment line Control element region Obliquely aligned elements Delta wing vortices at low Reynolds numbers are very relevant to micro-air vehicles and reconnaissance Elements prevent breakdown of vortices by directing air flow and produce high lift forces Elements prevent buffeting and oscillations, and thus limit drag forces
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Jet Flaps Leading or Trailing edge Can be difficult to implement.
Leading edge: + large increase on lift, - large increase on drag. Trailing edge: + increase stability - small increase on lift,
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Piezoelectric Strips Bonded on delta wing for active control of oscillations. Serve as sensors and actuators. Voltages applied across strips create forces to counter oscillations. Lightweight, cheap, and easy to manufacture.
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Obliquely Aligned Elements
Elements prevent breakdown of vortices by directing air flow and produce high lift forces. Elements also prevent buffeting and oscillations. Moderate drag penalty. Leading-edge separation line Vortex separation line reattachment line Control element region Oscillations caused by asymmetrical vortical breakdown which cause oscillations
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Obliquely Aligned Channels
Designed to stabilize the vortical flow. Restrict pressure rises that precipitate breakdown. Increase ωθ and induce secondary flow Promote Reattatchment
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Experimentation Set up to determine the lift and drag coefficients on a Delta Wing with varying angles of attack Measurements: Data Acquisition LABVIEW Angle of Attack (0° to 45°) Using a set screw to adjust attack angle in 5° increments Lift and Drag Force Force Balance Static Pressure Difference Using a Pitot-Static Tube and the PCL2A Delta Wing Wind Direction Test Section WIND TUNNEL Figure 1: Wind tunnel experiment set-up to determine lift and drag coefficients on a Delta Wing with a fixed wind velocity.
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Initial Schedule Summary
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Final Schedule Summary
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Results
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Results
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Results Overall trend is the same for both wings
Lift and drag are less in the channeled Increased difference in lift just before stall Stall occurred at approximately 35° Lift after stall was greater for the channeled
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Significance Oblique channels do not increase performance
The effects after stall might suggest improvement is possible
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Summary There are multiple ways to manipulate the vortical breakdown
Mechanical Pneumatic Channeled wing does not drastically increase performance Lift force reduced Drag force reduced
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Recommendations Improvements in the channeled design might allow for better performance than current model Test at higher Reynolds numbers Resume original test criteria Oblique elemental distributions Arrangement of the
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Questions?
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