Environmental control system for precision airborne payloads
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01C-023/00
출원번호
US-0704267
(2010-02-11)
등록번호
US-8209066
(2012-06-26)
발명자
/ 주소
Engelhardt, Michel
출원인 / 주소
BAE Systems Information and Electronic Systems Integration Inc.
대리인 / 주소
Zucker, Leo
인용정보
피인용 횟수 :
0인용 특허 :
17
초록▼
Outside air enters a ram air scoop on an aircraft frame, and is ducted to a ram air control valve. The air control valve outputs a desired air mass flow to a cyclone air-water separator which removes moisture and produces a dry air flow. A heater assembly heats the dry air to a desired temperature a
Outside air enters a ram air scoop on an aircraft frame, and is ducted to a ram air control valve. The air control valve outputs a desired air mass flow to a cyclone air-water separator which removes moisture and produces a dry air flow. A heater assembly heats the dry air to a desired temperature and directs the heated air into an equipment bay enclosure on the aircraft. The relative humidity of the heated air is sensed by an air moisture sensor which produces a corresponding signal. Other sensors disposed near a payload in the bay enclosure produce corresponding air temperature and air pressure signals. All the sensor signals are input to a processor or controller configured to activate the air control valve and the heater assembly according to set points for temperature and humidity that are specified for the payload in the bay enclosure.
대표청구항▼
1. An environmental control system for a payload equipment bay enclosure on an aircraft, comprising: a ram air scoop arranged to open in a forward direction of the aircraft for obtaining a supply of outside air;an air control valve constructed and arranged for receiving the outside air supply from t
1. An environmental control system for a payload equipment bay enclosure on an aircraft, comprising: a ram air scoop arranged to open in a forward direction of the aircraft for obtaining a supply of outside air;an air control valve constructed and arranged for receiving the outside air supply from the scoop, and for providing a determined air mass flow in response to an air control valve signal;a cyclone air-water separator constructed and arranged for receiving the air mass flow from the air control valve, and for removing moisture to provide a dry air mass flow from an outlet of the separator;an air heater assembly constructed and arranged for heating the dry air mass flow from the separator to a determined temperature in response to a heater signal, and for directing the heated air mass flow from an outlet of the heater assembly toward the equipment bay enclosure;an air moisture sensor disposed in a path of the heated air mass flow from the heater assembly for producing an air moisture signal corresponding to a relative humidity of the heated air mass flow;a first air temperature sensor disposed in the equipment bay enclosure in the region of a payload when mounted in the enclosure, for producing corresponding air temperature signals;an air pressure sensor disposed in the equipment bay enclosure in the region of the payload for producing a signal corresponding to an altitude of the payload; anda processor or controller having inputs coupled to the air moisture sensor, the first air temperature sensor and the air pressure sensor, wherein the controller is configured and arranged to supply the air control valve signal and the heater signal according to desired set points for temperature and humidity for the payload inside the equipment bay enclosure. 2. An environmental control system according to claim 1, wherein the controller is a proportional-integral-differential (PID) type of controller. 3. An environmental control system according to claim 1, including an air circulation fan and a duct arranged for recirculating air that exits from the equipment bay enclosure through the duct so that the recirculated air mixes with the dry air from the separator in response to a signal from the controller. 4. The system of claim 3, including a check valve arranged in the duct to block the dry air from the separator from entering the duct. 5. An environmental control system according to claim 1, including a desiccant arranged at or near the outlet of the cyclone separator for lowering the relative humidity of the air mass flow from the separator further prior to entering the equipment bay enclosure. 6. An environmental control system according to claim 1, including a desiccant arranged in the vicinity of the outlet of the air heater assembly for lowering the relative humidity of the heated air from the heater assembly further prior to entering the equipment bay enclosure. 7. An environmental control system according to claim 1, including a filter arranged at or near an outlet of the separator for removing particulates in the air mass flow from the separator. 8. An environmental control system according to claim 1, including an air circulation fan arranged for recirculating air exiting from the equipment bay enclosure in response to a signal from the controller. 9. A system according to claim 8, including a duct arranged for receiving the recirculated air from the air circulation fan, wherein a downstream end of the duct is formed and arranged to open into the outlet of the cyclone separator so that recirculated air in the duct is entrained with the air mass flow provided at the outlet of the separator. 10. A system according to claim 9, wherein the downstream end of the duct is formed so that a flow of recirculated air in the duct enters the outlet of the cyclone separator at an angle of approximately 15 degrees with respect to the direction of the air mass flow provided at the outlet of the separator. 11. A system according to claim 9, including a check valve arranged in the vicinity of the downstream end of the duct for blocking a flow of dried air at the outlet of the cyclone separator from entering the duct. 12. An environmental control system according to claim 8, wherein the controller is configured to maintain the air circulation fan in an on state from take-off and during ascent to an altitude of approximately 20,000 feet during the course of an aircraft mission profile. 13. An environmental control system according to claim 12, wherein the controller is configured to open the air control valve and to set the air circulation fan to an OFF state at said altitude. 14. An environmental control system according to claim 12, wherein the controller is configured to control the heater assembly at and above said altitude so that the air temperature inside the equipment bay enclosure is controlled according to the desired setpoint for temperature for the payload. 15. An environmental control system according to claim 12, wherein the controller is configured to control the air control valve at and above said altitude so that the relative humidity inside the equipment bay enclosure is controlled according to the desired setpoint for humidity for the payload. 16. An environmental control system according to claim 12, wherein the controller is configured to control the heater assembly and the air control valve at an altitude of approximately 60,000 feet. 17. An environmental control system according to claim 1, wherein the controller is configured to maintain the air control valve in a closed state from take-off and during ascent to an altitude of approximately 20,000 feet during the course of an aircraft mission profile. 18. An environmental control system according to claim 1, including a second air temperature sensor disposed in the region of the payload and coupled to an input of the processor. 19. An environmental control system according to claim 1, including a third air temperature sensor co-located with the air moisture sensor and coupled to an input of the processor.
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이 특허에 인용된 특허 (17)
Jonqueres Michel, Air cycle environmental control system with vapor cycle system assisted condensation.
Kanzawa Terukazu,JPX ; Tanaka Hideaki,JPX, Apparatus for air dehumidification having a unitary casing for a cyclone separator, a primary filter, a secondary filter, and a separation membrane element.
Kidder Kenneth B. (Coon Rapids MN) Smith Gary A. (Albuquerque NM) Wacker Paul C. (St. Louis Park MN), Demand limit control by integral reset of thermostats.
Mathis Lee R. (Dana Point CA) Panagotacos George W. (Corona CA) Panagotacos Steve K. (Yorba Linda CA) Bruce Ronald A. (Corona CA), Electric resistance air reating system for an aircraft cabin.
Bensoussan David (5170 ; Hingston Montreal ; Quebec CAX H3X 3R4) Tardio Don (2569 rue Taillon ; apt: #4 Montreal ; Quebec CAX H1L 4S7), Electronic temperature controller for householding.
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