Sistem Pneumatik (None: Pneumatic System)
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Definition
Sistem pesawat yang menggunakan udara terkompresi — biasanya diekstrak dari tahap kompresor mesin sebagai udara bleed — untuk pressurization kabin, anti-icing, starting mesin, dan pressurization reservoir hidrolik.
What Is an Aircraft Pneumatic System?
The pneumatic system is a compressed air distribution network that provides motive power for multiple aircraft systems simultaneously. Unlike hydraulic systems that use liquid, pneumatic systems transmit energy through compressed gas — almost universally bleed air extracted from engine compressor stages on conventional aircraft — distributing it to the cabin, wings, engine nacelles, and system reservoirs.
How It Works
Bleed air taps are located at the intermediate and high-pressure compressor stages of turbofan engines. Depending on altitude and power setting, the system selects the most fuel-efficient stage. A Pressure Regulating and Shut-off Valve (PRSOV) reduces bleed pressure from up to 45 bar (650 psi) at the engine to the pneumatic distribution pressure of approximately 3–4 bar (44–58 psi). Pre-coolers cool this air using fan bypass flow before it enters the distribution manifold.
The APU provides an independent bleed source for ground operations and as an airborne backup. Cross-bleed valves allow one engine's bleed air to supplement or replace another's, enabling single-engine taxi and engine-start-from-bleed procedures.
The pneumatic system feeds directly into the Environmental Control System for cabin conditioning, into the Ice Protection System for wing and nacelle anti-icing, and into hydraulic reservoir pressurization circuits to prevent pump cavitation. Engine starting on most turbofans is accomplished by a starter/generator motor driven by pneumatic air, spinning the core to light-off RPM before fuel introduction.
Key Components
- Bleed Air Valves: Stage-selector and shutoff valves controlling airflow from each compressor tap.
- Pre-Coolers: Fan-air heat exchangers reducing bleed temperature from 200+ °C to manageable levels.
- Distribution Manifold: High-temperature ducting routing conditioned bleed air to consuming systems.
- Overheat Detection: Pneumatic duct leak detection loops (typically Kidde or Fenwal systems) monitoring for hot air leaks.
- Cross-Bleed Duct: Connects left and right pneumatic manifolds for redundancy and engine starting.
Aircraft Examples
- Boeing 737 NG/MAX: Conventional two-engine bleed system; pneumatics power ECS packs, wing anti-ice, and hydraulic reservoirs.
- Airbus A330: Two engine bleeds plus APU; pneumatic manifold runs the length of the fuselage at temperatures up to 230 °C (446 °F).
- Boeing 787-9: No conventional pneumatic system — the first large commercial jet to eliminate engine bleed air, replacing pneumatics with electric systems throughout.
- Airbus A350: Partially reduced bleed extraction compared to A330; retains pneumatic ECS but uses electric anti-icing on some surfaces.
Related Terms
Arsitektur No-Bleed
Filosofi desain pesawat modern yang dipelopori Boeing 787 yang menghilangkan seluruh ekstraksi udara bleed mesin, menggantikan sistem pneumatik dengan kompresor, pompa, dan elemen pemanas elektrik untuk efisiensi bahan bakar dan keandalan yang lebih baik.
Sistem Kontrol Lingkungan
Sistem terintegrasi yang menjaga suhu, tekanan, dan kualitas udara kabin dengan mengkondisikan udara bleed mesin atau udara terkompresi secara elektris untuk kenyamanan dan keselamatan penumpang dan awak.
Sistem Perlindungan Es
Sistem yang mencegah atau menghilangkan akumulasi es pada permukaan pesawat kritis — termasuk tepi depan sayap, inlet mesin, tabung pitot, dan kaca depan — menggunakan metode termal, mekanis, atau kimia.
Udara Bleed
Udara bertekanan tinggi dan bersuhu tinggi yang disadap dari tahap kompresor mesin, digunakan untuk pressurization kabin, pendingin udara, de-icing sayap, dan sistem pesawat lainnya.
Unit Daya Bantu (APU)
Mesin kecil di bagian ekor yang menyediakan tenaga listrik dan pendingin udara saat mesin utama mati.