Buz Koruma Sistemi (IPS: Ice Protection System)
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Definition
Kanat ön kenarları, motor girişleri, pitot tüpleri ve ön camlar dahil kritik uçak yüzeylerinde buz birikmesini termal, mekanik veya kimyasal yöntemlerle önleyen veya gideren sistemler.
What Is an Ice Protection System?
The Ice Protection System (IPS) encompasses all systems designed to prevent ice from forming on critical aircraft surfaces (anti-icing) or to remove ice after it has accumulated (de-icing). Ice accretion on lifting surfaces, engine inlets, and sensing probes poses severe safety risks by altering aerodynamic characteristics, blocking airflow, and degrading instrument accuracy.
How It Works
Thermal anti-icing — the most common method on transport aircraft — uses heat to prevent ice formation. Bleed-air systems route hot bleed air (typically 200–250 °C / 392–482 °F) from the pneumatic system through piccolo tubes embedded in wing leading edge slats and engine nacelle lips. This continuous heating maintains surface temperatures above 0 °C (32 °F) even in icing conditions.
Electric resistance heating is used for pitot probes, static ports, angle-of-attack vanes, and windshields — where bleed air routing is impractical. The Boeing 787 extends electric heating to wing leading edge surfaces as part of its no-bleed architecture, using approximately 100 kW per wing in maximum icing conditions, drawing from its large 1 MVA electrical generation capacity.
Pneumatic de-icing boots — inflatable rubber surfaces along leading edges — are employed primarily on turboprops and regional aircraft. Boots inflate cyclically (every 60–120 seconds) using pneumatic system pressure to crack and shed accumulated ice. They are not used on swept-wing jets due to ice bridging risk at lower accumulation levels.
The Environmental Control System provides windshield heat as a secondary function, maintaining cockpit visibility in precipitation and icing conditions. Engine inlet cowl anti-icing activates automatically or via crew selection when icing conditions are detected by ice detectors or when outside air temperature and visible moisture conditions meet EASA/FAA icing certification criteria.
Key Components
- Wing Anti-Ice (WAI) Valves: Bleed air shutoff valves controlling flow to leading edge slat piccolo tubes.
- Engine Anti-Ice (EAI) Valves: Control bleed air to engine nacelle lips; typically auto-activated by engine control computers.
- Ice Detectors: Vibrating rod or ultrasonic sensors detecting ice accretion rates; signal crew and auto-activate systems.
- Pitot Heaters: Electrical elements maintaining pitot tube temperatures above 50 °C (122 °F) continuously in flight.
- Windshield Heat Panels: Conductive oxide coatings on cockpit windows providing uniform resistive heating.
Aircraft Examples
- Boeing 737 NG: Bleed-air wing anti-ice on leading edge slats only; tail surfaces not anti-iced (design limit speed constraints in icing).
- Airbus A320: Three-zone wing anti-ice using bleed air; automatic activation when ice detected below 10 °C (50 °F) with visible moisture.
- Boeing 787-9: Fully electric wing anti-ice system; 200 kW total capacity eliminating bleed air dependency.
- ATR 72: Pneumatic de-icing boots on wing and tail leading edges; certified for flight in known icing (FIKI).
Related Terms
Çevre Kontrol Sistemi
Yolcu ve ekip konforu ile güvenliği için motor bleed havasını veya elektriksel olarak sıkıştırılmış havayı koşullandırarak kabin sıcaklığını, basıncını ve hava kalitesini koruyan entegre sistem.
Kanama Havası
Motor kompresör kademelerinden alınan yüksek basınçlı, yüksek sıcaklıklı hava; kabin basınçlandırma, iklimlendirme, kanat buzlanma önleme ve diğer uçak sistemleri için kullanılır.
Pnömatik Sistem
Kabin basınçlandırma, buz giderme, motor çalıştırma ve hidrolik rezervuar basınçlandırması için tipik olarak motor kompresör kademelerinden bleed hava kullanan uçak sistemi.