引气 (Bleed Air)
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Definition
从发动机压气机级抽取的高压高温空气,用于客舱增压、空调、机翼除冰等飞机系统。
什么是引气?
Bleed air is compressed, hot air extracted from intermediate or high-pressure compressor stages of a gas turbine engine. At those stages, air has been compressed to pressures of 30–45 psi and temperatures of 200–250 °C — energetic enough to run cabin pressurization, heating, anti-icing systems, and engine starting without additional pumps or heaters. Extracting bleed air reduces available engine thrust and efficiency, which is why some aircraft have eliminated bleed air entirely.
工作原理
Bleed air is tapped at one of two compressor stages depending on flight conditions:
- Intermediate pressure (IP) port: Lower-energy air used at high power settings where the engine compresses air sufficiently at intermediate stages.
- High pressure (HP) port: Used at low power settings (descent, idle) when IP stage pressure is insufficient. Automatically switches via Pressure Regulating Shutoff Valves (PRSOV).
After extraction, bleed air travels through the Pneumatic Distribution System to:
- Air Conditioning Packs: Air cycle machines cool and regulate bleed air for cabin distribution
- Pressurization: Maintains cabin altitude (typically 6,000–8,000 ft equivalent) by pressurizing the fuselage
- Wing and engine inlet anti-icing: Hot bleed air flows through leading edge D-sections to prevent ice accumulation
- Engine starting: Bleed air from the APU or a ground cart spins the starter turbine to accelerate the engine to self-sustaining speed
- Hydraulic reservoir pressurization and potable water tank pressurization
性能参数
- Efficiency penalty: Bleed air extraction costs 1–3% fuel burn on a typical flight
- Pressure: Delivered to packs at approximately 30–45 psi after regulation
- Temperature: Pre-cooled by fuel-air heat exchangers to ~200 °C before distribution
- Flow rate: Up to 2 lb/sec per engine on large twins at maximum bleed demand
飞机案例
- Airbus A320: Conventional bleed air from CFM56/LEAP engines — industry-standard architecture
- Boeing 787 Dreamliner (bleedless): No bleed air extracted from engines. Instead, electric compressors (powered by generators) provide all pressurization and anti-icing — saving 2–3% fuel burn and improving cabin air quality (no risk of engine oil contamination)
- Airbus A350 (partial bleedless): Uses bleed air for cabin conditioning but electric wing anti-icing (hybrid approach)
- Boeing 737 / Airbus A320: APU provides bleed air for engine starting and ground air conditioning before main engines start
Bleed air management is controlled automatically by FADEC in coordination with the aircraft's pneumatic and environmental control systems.
Related Terms
全权限数字发动机控制(FADEC)
对所有发动机参数拥有完全控制权的计算机系统,无机械备份,可优化性能并防止发动机损坏。
压缩机级
喷气发动机内在燃烧前逐级压缩进气的旋转和静止翼型组合。
无引气架构
Boeing 787率先采用的现代飞机设计理念,完全取消发动机引气,用电动压缩机、泵和加热元件取代气动系统,提升燃油效率和可靠性。
气动系统
通常使用从发动机压缩机级提取的引气,用于客舱增压、防冰、发动机启动和液压油箱加压的飞机系统。
涡扇发动机
使用大型风扇产生大部分推力的商用航空中最常见的喷气发动机类型。
燃烧室
喷气发动机中压缩空气与燃料混合点燃、产生驱动涡轮的高能燃气的区段。
环境控制系统(ECS)
通过调节发动机引气或电动压缩空气来维持客舱温度、压力和空气质量的集成系统,确保旅客和机组人员的舒适与安全。
辅助动力装置(APU)
当主发动机关闭时提供电力和空调的位于尾部的小型发动机。
防冰系统
采用热力、机械或化学方法防止或清除机翼前缘、发动机进气道、皮托管和风挡等关键飞机表面积冰的系统。