A method and system limiting specific consumption of an aircraft by matching sizing of a power supply to actual power needs of a cabin pressure control system. The method optimizes overall efficiency of energy supplied onboard an aircraft including, in an environment near the cabin, at least one mai
A method and system limiting specific consumption of an aircraft by matching sizing of a power supply to actual power needs of a cabin pressure control system. The method optimizes overall efficiency of energy supplied onboard an aircraft including, in an environment near the cabin, at least one main power-generating engine, sized to serve as a single pneumatic energy-generating source for the cabin and as an at most partial propulsive, hydraulic, and/or electric energy-generating source for the rest of the aircraft. The method minimizes power differential between a nominal point of the power sources when the sources are operating, and a sizing point of non-propulsive energy contributions of the sources when the main engine has failed, by equally dividing power contributions of the main engines and the main power generator under nominal operating conditions and in an event of failure of a main engine.
대표청구항▼
1. A method for optimizing overall efficiency of energy supplied aboard an aircraft, the energy being propulsive or non-propulsive, the aircraft including a passenger cabin with regulated air flow, and power sources including at least two main engines, the method comprising: providing, in an environ
1. A method for optimizing overall efficiency of energy supplied aboard an aircraft, the energy being propulsive or non-propulsive, the aircraft including a passenger cabin with regulated air flow, and power sources including at least two main engines, the method comprising: providing, in an environment located near the cabin, at least one main engine-type power-generating unit sized to serve as a single other pneumatic energy-generating source for the cabin and at most partly as an other propulsive, hydraulic, and/or electric energy-generating source for a rest of the aircraft; andminimizing a power difference between a nominal point of the power sources when the power sources are functioning and a sizing point of non-propulsive energy contributions of the power sources in a situation of failure of a main engine;wherein the minimizing includes dividing the power under nominal operating conditions equally between the at least two main engines and the main engine-type power generating unit, anddividing the power in the event of the failure of the main engine equally between at least one main engine and the main engine-type power generating unit. 2. A main power unit in an aircraft, comprising: energy-consuming equipments;a cabin in which air is renewed and temperature and/or pressure of which is regulated by a regulation system;at least two main power-generating engines;a flight control unit; andan engine-type power unit including a gas generator and with a power turbine for driving equipments including a supercharger, the supercharger being coupled, via a regulation control that communicates with the control unit, with the regulation system to supply necessary pneumatic energy to the cabin, the engine-type power unit being built into a compartment which is insulated from other zones of the aircraft with a fireproof bulkhead and including an outside-air intake and an exhaust nozzle,wherein power sources include the at least two main engines and the engine-type power unit,wherein the flight control unit is configured to minimize a power difference between a nominal point of the power sources when the power sources are functioning and a sizing point of non-propulsive energy contributions of the power sources in a situation of failure of a main engine, andwherein minimizing the power difference includes dividing a power under nominal operating conditions equally between the at least two main engines and the engine-type power unit, and dividing the power in the event of the failure of the main engine equally between at least one main engine and the engine-type power generating unit. 3. The main power unit according to claim 2, coupled with a recovery structure that includes at least one energy-recovery turbine for driving the equipments with the power turbine and that is coupled, on an air-inlet side, with an outlet of the cabin to cool, on an air-outlet side, the equipments, the supercharger being built into this recovery structure as a supplier of pneumatic energy to the cabin. 4. The main power unit according to claim 3, in which the recovery turbine ejects, on an outlet side, an air flow into the compartment of the main power unit which, after it has cooled the equipments and auxiliary equipments contained in an aft compartment, is evacuated into an exhaust nozzle by a jet pump action resulting from efflux velocity of hot air flow coming out of the power turbine. 5. The main power unit according to claim 3, in which the recovery turbine is a centripetal turbine with a variable-pitch guide vane assembly including blades in which adjustment of which is servo-controlled by the regulation system. 6. The main power unit according to claim 3, further comprising means for transmitting power from the power and recovery turbines to mechanical, pneumatic, hydraulic, and/or electric equipments of the aircraft. 7. The main power unit according to claim 6, in which the power-transmission means is in a form of a power-transfer box. 8. The main power unit according to claim 3, in which the recovery structure comprises a heat exchanger including two heat-transfer circuits of: a primary circuit connected, on an inlet side, with a hot-air-flow outlet of the power turbine and, on an outlet side, with an exhaust nozzle; and a secondary circuit connected, on the inlet side, with an air-flow outlet of the cabin and, on the outlet side, with the recovery turbine. 9. The main power unit according to claim 2, in which the supercharger includes a variable-pitch air diffuser including blades, adjustment of which is servo-controlled by the regulation control, configured to strictly adjust air flow to a supply of pressure and flow rate required by the regulation system in every flight phase. 10. The main power unit according to claim 9, in which a variation in setting of the diffuser of the supercharger results in a variation in an air-flow rate with a substantially constant pressure ratio. 11. The main power unit according to claim 9, in which at least one pressure sensor regulates opening and closing of the blades of the diffuser and a guide vane assembly in connection with the regulation system. 12. The main power unit according to claim 11, in which a most open possible setting position of the blades can go beyond full opening into a radial position, at a zero position. 13. The main power unit according to claim 11, in which a regulation of the variable setting of the blades, between full opening on the ground and progressive closing of air flow while gaining altitude, is automated by the regulation system according to pressurization in the cabin. 14. The main power unit according to claim 2, in which the supercharger is directly coupled with the power turbine. 15. The main power unit according to claim 2, in which the gas generator includes an intake compressor capable of serving as the supercharger.
연구과제 타임라인
LOADING...
LOADING...
LOADING...
LOADING...
LOADING...
이 특허에 인용된 특허 (6)
Friedrich Helmut (Bremen DT), Apparatus for starting aircraft engines and for operating auxiliary on-board power generating equipment.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.