boneh3ad,
Thanks for the correction.
My my previous comment is full of errors and and over-simplified. It's been a while since I did any work with High Speed Aerodynamics for I have been working with Electrical & Piston Powerplants for the longest time.
Tell me what you think of the following below.
I will just quote aerodynamics text directly from my 'Jeppesen Airframe & Powerplant General Textbook' (1997) in the High Speed Aerodynamics Chapter; Sections: Normal Shock Waves, Expansion Waves and High-Speed Airfoils.
NORMAL SHOCK WAVES: If a blunt airfoil passes through the air at a supersonic velocity, the shock wave cannot attach to the leading edge. Instead, the shock wave forms ahead of the airfoil and perpendicular to the airstream.
When the airstream passes through a normal shock wave, its direction does not change. However, the airstream does slow down to a subsonic speed with a large increase in its static pressure and density. A normal shock wave forms the boundary between supersonic and subsonic airflow when there is no change in direction of air as it passes through the wave.
In addition to forming in front of the leading edge, normal shock waves also form on an airfoil in transonic flight. For example, as an airfoil is forced through the air at a high subsonic speed, the air passing over the top of the wing speeds up to a supersonic velocity and normal shock wave forms. Once the shock wave forms, it slows the airflow beyond the wave to a subsonic speed. These shock waves form on top of the airfoil first and then on the bottom. As airspeed increases beyond the transonic range, both shock waves move aft and attach to the wing's trailing edge to form an oblique shock wave.
EXPANSION WAVES: When a supersonic stream of air turns away from its direction of flow to follow the surface of an airfoil, its speed increases and both static pressure and density decrease. Since an expansion wave is not a shock wave, no energy in the airstream is lost.
HIGH SPEED AIRFOILS: Transonic flight displays the greatest airfoil design problems because only a portion of the airflow passing over the wing is supersonic. When an airfoil moves through the air at a speed below its critical Mach number, all of the airflow is subsonic and the pressure distributions are as your would expect. However, as flight speed exceeds the critical Mach number for an airfoil, the airflow over the top of the wing reaches supersonic velocity and a normal shock wave forms. Normally, the airflow over the top of a wing creates an area of low pressure that pulls the air to the wing's surface. However, when a shock wave forms on the top of the wing, airflow passing through it slows causing the air's static pressure to increase. This destroys the area of low pressure above the wing and allows the air to separate from the surface. This shock-induced separation causes a loss of lift and can reduce control effectiveness.
Because the supersonic flow is a local condition, its effects can be reduced by the use of vortex generators. A vortex generator is a small airfoil mounted ninety degrees to the surface of the wing. It has a low aspect ratio and produces a strong vortex or flow of controlled air that moves high energy air from the airstream into the boundary layer. This vortex delays airflow separation. To obtain maximum benefit, vortex generators are mounted in pairs so the vortices are combined. Although they actually add drag at low speed, the benefit at high speed is a good tradeoff.
Airfoil sections designed for for supersonic flight are typically a double wedge or biconvex shape with sharp leading and trailing edges. Their maximum thickness is at the 50% chord position. As soon as either of these airfoil sections pass through the transonic range, oblique shock waves attach to the leading and trailing edges. The expansion waves form at the point where the airflow must deflect to follow the surface. Since there are no normal shock waves on either airfoil section, there is no subsonic airflow.
Regards,
- MisterDynamics -
January 08, 2014
