The pressurization system in the Airbus A320 is designed to maintain a comfortable cabin environment by controlling the air pressure inside the aircraft. It compensates for the decrease in atmospheric pressure at higher altitudes, keeping the cabin pressure at a safe and comfortable level for passengers and crew.
Air Supply Source
The pressurization system uses bleed air taken from the aircraft’s engines:
- Bleed air is extracted from the compressor stages of the engines (typically from the intermediate or high-pressure stages). This air is hot and pressurized, so it must be conditioned before being introduced into the cabin.
- Alternatively, bleed air can come from the Auxiliary Power Unit (APU) on the ground or during emergency operations.
Air Conditioning Packs
The bleed air is sent to the Air Conditioning Packs, where it is cooled and conditioned before being sent to the cabin: - Air Conditioning Packs regulate the temperature and flow of air.
- The two packs work together to ensure that the right amount of air, at the correct temperature, enters the cabin.
Cabin Pressure Controllers (CPCs)
The A320 has two Cabin Pressure Controllers (CPCs) that work redundantly to control cabin pressurization. Only one CPC operates at a time, with an automatic switchover to the other in case of failure. These controllers receive data from various sensors, including: - Cabin altitude sensors: Measure the cabin pressure equivalent to an altitude.
- Rate of climb/descent sensors: Track how fast the cabin pressure is changing.
- Ambient pressure sensors: Measure the external (outside) air pressure.
The CPCs continuously monitor these parameters to ensure the pressurization system maintains safe cabin pressure. - Outflow Valve
The pressurization system maintains cabin pressure by controlling the Outflow Valve located at the rear of the fuselage. The Outflow Valve is electronically controlled and adjusts automatically to regulate the pressure: - It opens or closes to release or retain air in the cabin.
- In normal operation, the valve modulates continuously to maintain a pressure differential between the cabin and the outside air.
There are safety limits on how much the pressure differential can be:
- The maximum normal pressure differential is approximately 8.06 psi (pounds per square inch).
- A typical cabin altitude is maintained at around 6,000–8,000 feet when the aircraft is cruising at higher altitudes (such as 35,000 feet).
Safety Valves
In addition to the main outflow valve, the A320 is equipped with two safety pressure relief valves:
- Positive Pressure Relief Valves: These open automatically if the cabin pressure exceeds the safe limit.
- Negative Pressure Relief Valves: These prevent the cabin pressure from dropping below external air pressure (which could cause structural damage).
Modes of Operation
The pressurization system operates in different modes, including:
- Automatic Mode: The system is controlled by the CPCs. This is the normal mode of operation, where all actions, including the pressurization schedule, outflow valve control, and transitions between flight phases, are automatic.
- Manual Mode: If both CPCs fail, the system can be operated manually by the flight crew using a switch on the overhead panel. In this mode, the crew can control the outflow valve directly.
Cabin Pressurization Schedule
The system follows a predefined pressurization schedule, based on the phases of flight:
-Ground: Before takeoff and 55 seconds after landing, the outflow valve fully opens to ensure no residual cabin pressure. At touchdown, any remaining cabin pressure is released at a cabin vertical speed of 500 ft/min. After each landing, the systems are automatically transferred.
- Takeoff: The system begins pressurizing the cabin as the aircraft accelerates for takeoff. This avoids sudden pressure changes and discomfort.
- Climb: The cabin altitude increases gradually as the aircraft ascends, maintaining a differential pressure below the structural limits.
- Cruise: Once at cruise altitude, the cabin altitude is maintained at a constant level, even though the external pressure is much lower.
- Descent: As the aircraft descends, the cabin altitude decreases gradually. The system ensures that the cabin pressure descent rate is comfortable for passengers, avoiding rapid changes.
- Abort: If the aircraft does not climb after takeoff or aborts the mission, the abort mode prevents the cabin altitude from climbing. Cabin pressure is set to the takeoff altitude + 1 psi.
System Monitoring and Alarms
The A320 pressurization system is equipped with several alerts and protections:
- CABIN ALT warning: A warning is triggered if the cabin altitude exceeds 9,550 feet, signaling a possible depressurization.
- Pressure Differential Warnings: If the pressure differential between the cabin and the outside air exceeds safe limits, an alert is triggered, and safety valves automatically operate.
- Failure Indications: Any failure in the CPCs or other components triggers alerts for the flight crew. If a CPC fails, the other one takes over automatically without interrupting pressurization.
Landing and Depressurization
At landing, the cabin pressure is gradually equalized with the ambient pressure. The outflow valve opens fully after touchdown, allowing the cabin to depressurize completely.
The A320 pressurization system is highly automated and designed with redundancy to ensure safe and comfortable flight conditions.
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