Aircraft air conditioning systems and methods
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B64D-013/02
B64D-013/06
출원번호
US-0659897
(2012-10-24)
등록번호
US-9669936
(2017-06-06)
발명자
/ 주소
Fiterman, Charles J.
Atkey, Warren A.
출원인 / 주소
The Boeing Company
인용정보
피인용 횟수 :
1인용 특허 :
14
초록▼
There are provided aircraft air conditioning systems and methods. The aircraft air conditioning system has a duct in an aircraft connected to an aircraft cabin and configured to flow pressurized cabin outflow air from the aircraft cabin. The aircraft air conditioning system further has a turbine con
There are provided aircraft air conditioning systems and methods. The aircraft air conditioning system has a duct in an aircraft connected to an aircraft cabin and configured to flow pressurized cabin outflow air from the aircraft cabin. The aircraft air conditioning system further has a turbine connected to the duct and configured to reduce a temperature of the pressurized cabin outflow air and to generate power, and further has a compressor configured to generate a compressed inlet air stream, and further has an air conditioning pack configured to receive a reduced temperature cabin outflow air from the turbine and configured to receive the compressed inlet air stream from the compressor. The air conditioning pack has a cooling cycle system, a humidity control system, and one or more heat exchangers configured to use the reduced temperature cabin outflow air as a heat sink.
대표청구항▼
1. An aircraft air conditioning system comprising: a duct in an aircraft connected to an aircraft cabin and configured to flow pressurized cabin outflow air from the aircraft cabin;a turbine connected to the duct, the turbine configured to reduce a temperature of the pressurized cabin outflow air an
1. An aircraft air conditioning system comprising: a duct in an aircraft connected to an aircraft cabin and configured to flow pressurized cabin outflow air from the aircraft cabin;a turbine connected to the duct, the turbine configured to reduce a temperature of the pressurized cabin outflow air and to generate power and turbine outflow air;a compressor configured to generate a compressed inlet air stream, the compressor comprising one of a cabin compressor receiving ram air from an ambient air source, a boost compressor receiving bleed air from an aircraft engine compressor, or the aircraft engine compressor supplying aircraft supply air; and,an air conditioning pack configured to receive a reduced temperature cabin outflow air from the turbine, the reduced temperature cabin outflow air comprising a mixture of the turbine outflow air and ram air, and the air conditioning pack configured to receive the compressed inlet air stream from the compressor, the air conditioning pack comprising: a cooling cycle system;a humidity control system; and,one or more heat exchangers configured to use the reduced temperature cabin outflow air as a heat sink. 2. The aircraft air conditioning system of claim 1 wherein the cabin compressor is connected to a ram air duct and is configured to compress and flow the ram air as the compressed inlet air stream to the air conditioning pack. 3. The aircraft air conditioning system of claim 1 further comprising a shaft connecting the turbine to the compressor, the shaft configured to turn the compressor when the pressurized cabin outflow air passes through the turbine. 4. The aircraft air conditioning system of claim 3 wherein the shaft connects the turbine to an electric generator instead of the compressor, the electric generator configured to generate an electrical current, and the electric generator in electrical connection with an aircraft subsystem and configured to power the aircraft subsystem. 5. The aircraft air conditioning system of claim 1 further comprising a shaft connecting the turbine to the compressor and to an electric motor therebetween, the shaft configured to turn the compressor when the pressurized cabin outflow air passes through the turbine and the electric motor configured to turn the shaft. 6. The aircraft air conditioning system of claim 1 wherein the compressor is powered in whole or in part by the turbine. 7. The aircraft air conditioning system of claim 1 wherein the compressor is a boost compressor is connected to a bleed air duct connected to the aircraft engine compressor on an aircraft, and the boost compressor is configured to compress and flow the bleed air as the compressed inlet air stream to the air conditioning pack. 8. The aircraft air conditioning system of claim 1 wherein the aircraft engine compressor is on an aircraft connected to a duct system connected to the air conditioning pack, and the aircraft engine compressor is configured to compress and flow the aircraft supply air as the compressed inlet air stream to the air conditioning pack. 9. The aircraft air conditioning system of claim 1 wherein the one or more heat exchangers comprise a first heat exchanger configured to aid in reducing heat of the compressed inlet air stream using the reduced temperature cabin outflow air, and a second heat exchanger configured to aid in reducing heat of at least one transport fluid flowing through the air conditioning pack. 10. The aircraft air conditioning system of claim 1 further comprising the reduced temperature cabin outflow air of the turbine connected to at least one air to liquid heat exchanger configured to aid in reducing heat of at least one liquid coolant stream flowing through the at least one air to liquid heat exchanger. 11. The aircraft air conditioning system of claim 1 further comprising the reduced temperature cabin outflow air of the turbine connected to at least one heat exchanger positioned upstream of the compressor, the at least one heat exchanger configured to aid in reducing heat of ram air from the ambient air source entering the compressor. 12. An aircraft having an aircraft air conditioning system providing expanded air conditioning and thermal management performance, the aircraft comprising: a fuselage;an aircraft cabin disposed within the fuselage; and,an aircraft air conditioning system disposed within the fuselage, the aircraft air conditioning system comprising: a duct connected to the aircraft cabin and configured to flow pressurized cabin outflow air from the aircraft cabin;a turbine connected to the duct, the turbine configured to reduce a temperature of the pressurized cabin outflow air and to generate power and turbine outflow air;a compressor configured to generate a compressed inlet air stream, the compressor comprising one of a cabin compressor receiving ram air from an ambient air source, a boost compressor receiving bleed air from an aircraft engine compressor, or the aircraft engine compressor supplying aircraft supply air; and,an air conditioning pack configured to receive a reduced temperature cabin outflow air from the turbine, the reduced temperature cabin outflow air comprising a mixture of the turbine outflow air and ram air, and the air conditioning pack configured to receive the compressed inlet air stream from the compressor, the air conditioning pack comprising: a cooling cycle system;a humidity control system; and,one or more heat exchangers configured to use the reduced temperature cabin outflow air as a heat sink. 13. The aircraft of claim 12 wherein the cabin compressor is connected to a ram air duct and is configured to compress and flow the ram air as the compressed inlet air stream to the air conditioning pack. 14. The aircraft of claim 12 wherein the boost compressor is connected to a bleed air duct connected to the aircraft engine compressor on the aircraft, and the boost compressor is configured to compress and flow the bleed air as the compressed inlet air stream to the air conditioning pack. 15. The aircraft of claim 12 wherein the aircraft engine compressor is on the aircraft connected to a duct system connected to the air conditioning pack, and the aircraft engine compressor is configured to compress and flow the aircraft supply air as the compressed inlet air stream to the air conditioning pack. 16. The aircraft of claim 12 wherein the aircraft air conditioning system further comprises a shaft connecting the turbine to either the compressor or an electric generator. 17. The aircraft of claim 12 wherein the compressor is powered in whole or in part by the turbine. 18. A method for air conditioning an aircraft comprising: flowing a pressurized cabin outflow air from an aircraft cabin to a turbine via a duct in an aircraft;extracting energy from the pressurized cabin outflow air via the turbine to generate power and turbine outflow air;mixing the turbine outflow air with ram air to generate a reduced temperature cabin outflow air;using the power from the turbine to power in whole or in part a compressor;using the compressor to generate a compressed inlet air stream, the compressor comprising one of a cabin compressor receiving ram air from an ambient air source, a boost compressor receiving bleed air from an aircraft engine compressor, or the aircraft engine compressor supplying aircraft supply air; andflowing the reduced temperature cabin outflow air and the compressed inlet air stream through an air conditioning pack, the air conditioning pack comprising: a cooling cycle system;a humidity control system; andone or more heat exchangers configured to use the reduced temperature cabin outflow air as a heat sink. 19. The method of claim 18 further comprising using the one or more heat exchangers to aid in reducing heat of the compressed inlet air stream using the reduced temperature cabin outflow air and to aid in reducing heat of at least one transport fluid flowing through the air conditioning pack. 20. The method of claim 18 further comprising connecting a shaft between the turbine and either the compressor or an electric generator. 21. The method of claim 18 further comprising ducting the reduced temperature cabin outflow air to at least one air to liquid heat exchanger, and aiding in reducing heat of at least one liquid coolant stream flowing through the at least one air to liquid heat exchanger. 22. The method of claim 18 further comprising ducting the reduced temperature cabin outflow air to at least one heat exchanger positioned upstream of the compressor, and aiding in reducing heat of ram air from the ambient air source entering the compressor.
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이 특허에 인용된 특허 (14)
Ostersetzer Shlomo,ILX ; Lior David,ILX, Air cycle air conditioning system.
Asfia, Julie F.; Williams, Kenneth R.; Atkey, Warren A.; Fiterman, Charles J.; Loukusa, Steven M.; Ng, Casey Y., Electric air conditioning system for an aircraft.
Claeys Henry M. (Lomita CA) Clarke Kathrine J. (Hermosa Beach CA) Matulich Dan S. (Rolling Hills Estates CA), Integrated power and cooling environmental control system.
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