IPC분류정보
국가/구분 |
United States(US) Patent
등록
|
국제특허분류(IPC7판) |
|
출원번호 |
UP-0489935
(2006-07-20)
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등록번호 |
US-7604019
(2009-11-10)
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발명자
/ 주소 |
- Frampton, Robert Frederick
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출원인 / 주소 |
- B/E Intellectual Property
|
대리인 / 주소 |
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인용정보 |
피인용 횟수 :
2 인용 특허 :
16 |
초록
▼
The electromechanical regulator for passenger oxygen is a hybrid oxygen regulator that provides for electronic or mechanical regulation of oxygen flow. The electronic portion of the regulator consists of an inlet solenoid valve, an outlet solenoid valve, a cabin pressure transducer, a regulated outp
The electromechanical regulator for passenger oxygen is a hybrid oxygen regulator that provides for electronic or mechanical regulation of oxygen flow. The electronic portion of the regulator consists of an inlet solenoid valve, an outlet solenoid valve, a cabin pressure transducer, a regulated output transducer and a PID based controller, and the solenoid valves are normally biased so that in the event of an electronic system failure or a power supply failure the system will automatically revert to mechanical operation.
대표청구항
▼
I claim: 1. An electromechanical regulator for regulating passenger oxygen for aircraft, comprising: an electromechanical regulator valve body including a supply inlet chamber and an outlet chamber; an oxygen supply inlet port for receiving oxygen from a source of oxygen, said oxygen supply inlet p
I claim: 1. An electromechanical regulator for regulating passenger oxygen for aircraft, comprising: an electromechanical regulator valve body including a supply inlet chamber and an outlet chamber; an oxygen supply inlet port for receiving oxygen from a source of oxygen, said oxygen supply inlet port being connected to said supply inlet chamber by a first supply channel; an oxygen outlet port connected to said outlet chamber; a balanced valve disposed in said electromechanical regulator valve body, said balanced valve including a valve channel defined in said electromechanical regulator valve body, a valve diaphragm separating said supply inlet chamber and said outlet chamber, said valve diaphragm including an opening forming a valve seat, and a valve member disposed in said valve channel and moveable therein between a valve closed position and a valve open position, said valve member being biased to engage said valve seat in the valve closed position; an electronic valve portion disposed in said electromechanical regulator valve body, said electronic valve portion being operative to control movement of said valve member between said open and closed positions responsive to sensed cabin pressure in the aircraft and sensed output pressure in said oxygen outlet port; and a mechanical valve portion disposed in said electromechanical regulator valve body, said mechanical valve portion including a supply pressure sensing chamber, said mechanical valve portion being operative to move said valve member between said open and closed positions responsive to pressure in said supply pressure sensing chamber and pressure in said outlet chamber. 2. The electromechanical regulator of claim 1, wherein said supply pressure sensing chamber includes a wall having a surface defining an aneroid valve vent hole, and further comprising an aneroid exposed to cabin pressure and mounted adjacent to said aneroid valve vent hole, said aneroid contracting to open said aneroid valve vent hole to vent pressure from the supply pressure sensing chamber, and lengthening to close said aneroid valve vent hole to trap pressure in the supply pressure sensing chamber, responsive to changes in cabin pressure. 3. The electromechanical regulator of claim 1, wherein said valve member comprises a valve poppet member including a poppet valve head to engage said valve seat, a poppet valve member base including an interior chamber, a seal disposed about said valve channel and forming a seal with said poppet valve member base, and a spring biasing said valve poppet member to said closed position. 4. The electromechanical regulator of claim 1, further comprising a movable diaphragm separating said supply pressure sensing chamber from said outlet chamber, and wherein a pressure sensing spring is disposed in said supply pressure sensing chamber and biases said movable diaphragm toward said valve member. 5. The electromechanical regulator of claim 1, further comprising a second supply inlet passage connecting said oxygen supply inlet port to said supply pressure sensing chamber. 6. The electromechanical regulator of claim 5, further comprising a sensitivity adjusting screw mounted in said second supply channel for controlling flow of oxygen into said supply pressure sensing chamber. 7. The electromechanical regulator of claim 1, wherein said electronic valve portion comprises: an electronic oxygen supply regulation chamber, a third supply channel connecting said electronic oxygen supply regulation chamber to said supply inlet chamber, and an electronic supply regulating chamber outlet passage; a first solenoid valve connected to said third supply channel and movable between a valve open position and a valve closed position for opening and closing said third supply channel, said first solenoid valve being normally closed; a second solenoid valve connected to said electronic supply regulating chamber outlet passage and movable between a valve open position and a valve closed position for opening and closing said electronic supply regulating chamber outlet passage, said second solenoid valve being normally open; and a controller for controlling operation of said first and second solenoid valves. 8. The electromechanical regulator of claim 7, further comprising a cabin pressure transducer sensing cabin pressure in the aircraft and generating a cabin pressure signal indicating cabin pressure, and an outlet pressure transducer sensing output pressure in said oxygen outlet port and generating an outlet port signal indicating pressure in said oxygen outlet port, said cabin pressure signal and said outlet port signal being received by said controller. 9. An electromechanical regulator for regulating passenger oxygen for aircraft, comprising: an electromechanical regulator valve body including a supply inlet chamber and an outlet chamber; an oxygen supply inlet port for receiving oxygen from a source of oxygen, said oxygen supply inlet port being connected to said supply inlet chamber by a first supply channel; an oxygen outlet port connected to said outlet chamber; a balanced valve disposed in said electromechanical regulator valve body, said balanced valve including a valve channel defined in said electromechanical regulator valve body, a valve diaphragm separating said supply inlet chamber and said outlet chamber, said valve diaphragm including an opening forming a valve seat, and a valve member disposed in said valve channel and moveable therein between a valve closed position and a valve open position, said valve member being biased to engage said valve seat in the valve closed position; an electronic valve portion disposed in said electromechanical regulator valve body, said electronic valve portion being operative to control movement of said valve member between said open and closed positions responsive to sensed cabin pressure in the aircraft and sensed output pressure in said oxygen outlet port; a mechanical valve portion disposed in said electromechanical regulator valve body, said mechanical valve portion including a supply pressure sensing chamber, said mechanical valve portion being operative to move said valve member between said open and closed positions responsive to pressure in said supply pressure sensing chamber and pressure in said outlet chamber, wherein said supply pressure sensing chamber includes a wall having a surface defining an aneroid valve vent hole, an aneroid exposed to cabin pressure and mounted adjacent to said aneroid valve vent hole, said aneroid contracting to open said aneroid valve vent hole to vent pressure from the supply pressure sensing chamber, and lengthening to close said aneroid valve vent hole to trap pressure in the supply pressure sensing chamber, responsive to changes in cabin pressure; and a movable diaphragm separating said supply pressure sensing chamber from said outlet chamber, and wherein a pressure sensing spring is disposed in said supply pressure sensing chamber and biases said movable diaphragm toward said valve member. 10. The electromechanical regulator of claim 9, wherein said valve member comprises a valve poppet member including a poppet valve head to engage said valve seat, a poppet valve member base including an interior chamber, a seal disposed about said valve channel and forming a seal with said poppet valve member base, and a spring biasing said valve poppet member to said closed position. 11. The electromechanical regulator of claim 9, further comprising a second supply inlet passage connecting said oxygen supply inlet port to said supply pressure sensing chamber. 12. The electromechanical regulator of claim 11, further comprising a sensitivity adjusting screw mounted in said second supply channel for controlling flow of oxygen into said supply pressure sensing chamber. 13. The electromechanical regulator of claim 9, wherein said electronic valve portion comprises: an electronic oxygen supply regulation chamber, a third supply channel connecting said electronic oxygen supply regulation chamber to said supply inlet chamber, and an electronic supply regulating chamber outlet passage; a first solenoid valve connected to said third supply channel and movable between a valve open position and a valve closed position for opening and closing said third supply channel, said first solenoid valve being normally closed; a second solenoid valve connected to said electronic supply regulating chamber outlet passage and movable between a valve open position and a valve closed position for opening and closing said electronic supply regulating chamber outlet passage, said second solenoid valve being normally open; and a controller for controlling operation of said first and second solenoid valves. 14. The electromechanical regulator of claim 13, further comprising a cabin pressure transducer sensing cabin pressure in the aircraft and generating a cabin pressure signal indicating cabin pressure, and an outlet pressure transducer sensing output pressure in said oxygen outlet port and generating an outlet port signal indicating pressure in said oxygen outlet port, said cabin pressure signal and said outlet port signal being received by said controller. 15. An electromechanical regulator for regulating passenger oxygen for aircraft, comprising: an electromechanical regulator valve body including a supply inlet chamber and an outlet chamber; an oxygen supply inlet port for receiving oxygen from a source of oxygen, said oxygen supply inlet port being connected to said supply inlet chamber by a first supply channel; an oxygen outlet port connected to said outlet chamber; a balanced valve disposed in said electromechanical regulator valve body, said balanced valve including a valve poppet channel defined in said electromechanical regulator valve body, a valve diaphragm separating said supply inlet chamber and said outlet chamber, said valve diaphragm including an opening forming a valve seat, and a valve poppet member disposed in said valve poppet channel and moveable therein between a valve closed position and a valve open position, said valve poppet member being biased to engage said valve seat in the valve closed position; an electronic valve portion disposed in said electromechanical regulator valve body, said electronic valve portion being operative to control movement of said valve poppet member between said open and closed positions responsive to sensed cabin pressure in the aircraft and sensed output pressure in said oxygen outlet port; a mechanical valve portion disposed in said electromechanical regulator valve body, said mechanical valve portion including a supply pressure sensing chamber, said mechanical valve portion being operative to move said valve poppet member between said open and closed positions responsive to pressure in said supply pressure sensing chamber and pressure in said outlet chamber, wherein said supply pressure sensing chamber includes a wall having a surface defining an aneroid valve vent hole, an aneroid exposed to cabin pressure and mounted adjacent to said aneroid valve vent hole, said aneroid contracting to open said aneroid valve vent hole to vent pressure from the supply pressure sensing chamber, and lengthening to close said aneroid valve vent hole to trap pressure in the supply pressure sensing chamber, responsive to changes in cabin pressure; a movable diaphragm separating said supply pressure sensing chamber from said outlet chamber, and wherein a pressure sensing spring is disposed in said supply pressure sensing chamber and biases said movable diaphragm toward said valve poppet member; and a cabin pressure transducer sensing cabin pressure in the aircraft and generating a cabin pressure signal indicating cabin pressure, and an outlet pressure transducer sensing output pressure in said oxygen outlet port and generating an outlet port signal indicating pressure in said oxygen outlet port, said cabin pressure signal and said outlet port signal being received by said controller. 16. The electromechanical regulator of claim 15, wherein said valve poppet member comprises a poppet valve head to engage said valve seat, a poppet valve member base including an interior chamber, a seal disposed about said valve poppet channel and forming a seal with said poppet valve member base, and a spring biasing said valve poppet member to said closed position. 17. The electromechanical regulator of claim 15, further comprising a second supply inlet passage connecting said oxygen supply inlet port to said supply pressure sensing chamber. 18. The electromechanical regulator of claim 17, further comprising a sensitivity adjusting screw mounted in said second supply channel for controlling flow of oxygen into said supply pressure sensing chamber. 19. The electromechanical regulator of claim 15, wherein said electronic valve portion comprises: an electronic oxygen supply regulation chamber, a third supply channel connecting said electronic oxygen supply regulation chamber to said supply inlet chamber, and an electronic supply regulating chamber outlet passage; a first solenoid valve connected to said third supply channel and movable between a valve open position and a valve closed position for opening and closing said third supply channel, said first solenoid valve being normally closed; a second solenoid valve connected to said electronic supply regulating chamber outlet passage and movable between a valve open position and a valve closed position for opening and closing said electronic supply regulating chamber outlet passage, said second solenoid valve being normally open; and a controller for controlling operation of said first and second solenoid valves.
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