等离子体流动控制

DBD Plasma Actuator “Opportunities for Flow Control”

Thomas Corke

University of Notre Dame

Institute for Flow Physics and Control

Hessert Laboratory for Aerospace Research

Aerospace and Mechanical Engineering

Objective

“set the context in terms of applications and/or motivations for the continued exploration and/or development of DBD plasma actuators”

D. Smith, Feb. 4, 2010

Issues

What is behind the surge in interest of DBD flow control?

What are the properties of DBD plasma actuators that make it useful for flow control?

How do we marry these properties to flow control

applications?

What are the environmental sensitivities?

How good are predictive models?

Based on what we have learned, are there other applications of this technology?

Growing Interest

June 1, 2009:

AIAA Names Plasma Actuators as No 5. of the “Top Ten Emerging Aerospace Technologies”

What is the appeal of DBD plasma actuators?

No moving parts

Potential long life

Withstand high g-loading

High dynamic response

Ease of application and compactness

Can be placed at the most receptive locations

DBD actuator effect (body force) most easy to incorporate in CFD DBD actuators can also be sensors

Properties of DBD Actuators

•Ionized air in presence of electric field results in body force that acts on neutral exposed electrode

dielectric

covered electrode

substrate

Wall Jet?

air .

•Body force is mechanism of flow control.

“Wall Jet with Suction”

Complete Characteristics

DBD Plasma Actuators have proven to be excellent for separation control for a wide range of Mach numbers

Θ

Decreasing R

Not a simple function of Cµ

Flow Separation Applications

Fan

Retreating Blade

Stall

Dome Drag

Inter-turbine Duct

Inlets LPT Blades

HPT Tip/Gap

Wing

Fuselage

Aerodynamic Force

Vectoring High α

Improving DBD FC Performance

Increase Body Force: AC Waveform/Frequency, Dielectric, Geometry,

Combined DC/AC

Increase Receptivity:

Geometry Modifications,

Fluid Instabilities,

Unsteady Forcing Actuator

Performance

Environmental Effects:

Actuator Design: Jet-suction, SVGs, Vertical Jets, Roughness

Flow Physics

Metrics of Merit:

Flow Control,

Energy Budget Actuator

Requirements

P s,Moisture

Predictive Models Modeling/CFD are necessary for design of efficient flow control

systems

Requires efficient(semi-

empirical) DBD models

Models need to be validated

Need to agree on the level of validation

Time-averaged body

force vectors

Body force/Voltage

scaling

Time dependent body

force