Anti-icing And De-icing System
✈ATA-30
✈Negative Effects of Ice Buildup
☂Negative effects of ice buildup
☂Destroys smooth flow of air over wing, leading to severe decrease in lift and increase in drag forces.
☂Can change pitching moment
☂ As angle of attack is increased to compensate for decreased lift, more accumulation can occur on lower wing surface.
☂Causes damage to external equipment such as antennae and can clog inlets,
and cause impact damage to fuselage and engines
☂Considered a cumulative hazard because as ice builds up on the wing, it increasingly changes the flight characteristics.
✈Causes of Icing
There is three cause;
✈Causes of Icing
There is three cause;
✈Effects of Icing
✈Types of Ice
☂Rime: Has a rough milky white appearance and generally follows the surface closely.
A milky white colored or opaque ice that deposits on the surface of the aircraft when it's flying through filmy clouds is classified as rime ice. It is usually formed because of small supercooled droplets when the rate of catch is low. Rime ice accumulates on the wings' leading edges and on pilot heads, antennas, etc.
☂Clear/Glaze: Clear and smooth but usually contain some air pockets that result in a lumpy translucent appearance, denser, harder and more difficult to break than rime ice
Clear ice or glaze ice is a heavy coating of glassy ice which forms when flying in areas with high concentration of large supercooled water droplets, such as cumuliform clouds and freezing rain. It spreads, often unevenly, over wing and tail surfaces, propeller blades, antennas, etc.
☂Mixed: It forms when both small and large supercooled droplets are present. The appearance of mixed ice is irregular, rough and whitish. Favorable conditions for forming of this type of aircraft ice include frozen and liquid particles present in the wet snowflakes and cumuliform cloud's colder portion.
✈Ice Prevention Methods
☂Heating surfaces using hot air
☂ Heating by electrical elements
☂ Breaking up ice formations, usually by inflatable boots
☂Alcohol spray.
✈Methods of Ice Control
Location of Ice ✈ Method of control
☂Leading edge of the wing >Pneumatic, Thermal
☂L/E of Horizontal & vertical stabilizer> Pneumatic,Thermal
☂Windshields, windows, radomes> Electrical, Alcohol
☂Heater & Engine air inlet> Electrical
☂Stall Warning Transmitters> Electrical
☂Pitot tubes> Electrical
☂Flight controls > Pneumatic, Thermal
☂L/E of propeller blade> Electrical,
Alcohol
☂Carburetors> Thermal, Alcohol
☂Lavatory drains>Electrical.
✈Types of Ice Removal
☂Anti-Icing
•Preemptive, turned on before the flight enters icing conditions
•Includes: thermal heat, prop heat, pitot heat, fuel vent heat, windshield heat, and fluid surface de-icers.
☂De-Icing
•Reactive, used after there has been significant ice build up
•Includes surface de-ice equipment such as boots, weeping wing systems, and heated wings.
✈Propeller Anti-Icers
☂Ice usually appears on propeller before it forms on the wing
☂Can be treated with chemicals from slinger rings on the prop hub
☂Graphite electric resistance heaters on leading edges of blades can also be used.
✈Windshield Anti-Icers
☂Usually uses resistance heat to clear windshield or chemical sprays while on the ground
☂Liquids used include: ethylene glycol, propylene glycol, Grade B Isopropyl alcohol, urea, sodium acetate, potassium acetate, sodium formate, and chloride salts
☂Chemicals are often bad for the environment.
☂Usually uses resistance heat to clear windshield or chemical sprays while on the ground
☂Liquids used include: ethylene glycol, propylene glycol, Grade B Isopropyl alcohol, urea, sodium acetate, potassium acetate, sodium formate, and chloride salts
☂Chemicals are often bad for the environment.
✈Thermal Heat
Air Heated
☂Bleed air from engine heats inlet cowls to keep ice from forming
☂ Bleed air can be ducted to wings to heat wing surface as well
☂Ice can also build up within engine, so shutoff valves need to be incorporated in design
☂ Usually used to protect leading edge slat, and engine inlet cowls Resistance heater
☂ Used to prevent ice from forming on pitot tubes, stall vanes, temperature probes, and drain masts.
✈Boots
☂Inflatable rubber strips that run along the leading edge of wing and tail surfaces
☂When inflated, they expand knocking ice off of wing surface
☂After ice has been removed, suction is applied to boots, returning them to the original shape for normal flight
☂Usually used on smaller planes.
✈Weeping Wing
☂Fluid is pumped through mesh screen on leading edge of wing and tail
☂Chemical is distributed over wing surface, melting ice
☂Can also be used on propeller blades windshields.
✈Typical Anti-Icing
C-130:
☂Engine bleed air used for anti-icing wing and empennage leading edges, radome, and engine inlet air ducts.
☂Electrical heat provides anti-icing for propellers, windshield, and pitot tubes.
777:
☂Engine bleed air used to heat engine cowl inlets. If leak is detected in Anti-Ice duct, affected engine Anti-Ice valves close.
☂Wing Anti-Ice System provides bleed air to three leading edge slats on each wing. Wing Anti-Ice is only available in flight.
✈ You can watch this https://youtu.be/JpvSEiPyIZM
