IPC분류정보
국가/구분 |
United States(US) Patent
등록
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국제특허분류(IPC7판) |
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출원번호 |
US-0966437
(2004-10-15)
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발명자
/ 주소 |
- Spink,Kenneth M.
- McIntosh,Andrew W.
- Benjey,Robert P.
- Martin,Charles J.
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출원인 / 주소 |
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대리인 / 주소 |
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인용정보 |
피인용 횟수 :
15 인용 특허 :
16 |
초록
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Isolation valves of the invention are advantageously mechanically actuated. Such valves and associated methods comprise a first port in fluid communication with a first component; a second port in fluid communication with a second component; a third port in fluid communication with a third component
Isolation valves of the invention are advantageously mechanically actuated. Such valves and associated methods comprise a first port in fluid communication with a first component; a second port in fluid communication with a second component; a third port in fluid communication with a third component; a diaphragm disposed within the valve for closing a normally open internal pathway to occlude fluid communication between the first port and the second port in response to a pressure differential across the diaphragm; and a flow sensitive pressure device for controlling the pressure differential across the diaphragm. Fluid flows from the second component to the third component upon closing of the normally open internal pathway. In an exemplary embodiment, isolation valves and methods of the invention are adapted for use in fuel tank emission control systems.
대표청구항
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The invention claimed is: 1. A mechanically actuated isolation valve, comprising: a first port in fluid communication with a first component; a second port in fluid communication with a second component; a third port in fluid communication with a third component; a diaphragm disposed within the
The invention claimed is: 1. A mechanically actuated isolation valve, comprising: a first port in fluid communication with a first component; a second port in fluid communication with a second component; a third port in fluid communication with a third component; a diaphragm disposed within the valve for closing a normally open internal pathway to occlude fluid communication between the first port and the second port and allow fluid flow from the second component to the third component in response to a pressure differential across the diaphragm; and a flow sensitive pressure device for controlling the pressure differential across the diaphragm. 2. The mechanically actuated isolation valve of claim 1, wherein the fluid comprises fuel and the valve comprises a fuel tank isolation valve. 3. The mechanically actuated isolation valve of claim 1, wherein essentially the same pressure differential is maintained across the diaphragm irrespective of rate of fluid flow from the second component to the third component, and wherein fluid flow between the first component and the third component is prevented upon closing of the normally open internal pathway so long as pressure within the first component is less than the pressure differential across the diaphragm. 4. The mechanically actuated isolation valve of claim 1, wherein the pressure differential across the diaphragm is controlled to a relatively constant level of approximately two to approximately four inches of atmospheric water pressure with increasing fluid flow from the second component to the third component after closing of the normally open internal pathway. 5. The mechanically actuated isolation valve of claim 1, wherein the valve is capable of purging a hydrocarbon canister in a fuel tank emission control system while simultaneously isolating a fuel tank fluidly coupled thereto without reliance on reliable operation of electronic components therein. 6. The mechanically actuated isolation valve of claim 1, wherein the first component comprises a fuel tank. 7. The mechanically actuated isolation valve of claim 1, wherein the second component comprises a canister for storage of hydrocarbon vapor. 8. The mechanically actuated isolation valve of claim 1, wherein the third component comprises an engine purge control valve. 9. The mechanically actuated isolation valve of claim 1, wherein the diaphragm closes the normally open internal pathway in response to a pressure differential of approximately two to approximately four inches atmospheric water pressure. 10. The mechanically actuated isolation valve of claim 1, further comprising an overpressure relief ring and an associated overpressure relief spring. 11. The mechanically actuated isolation valve of claim 10, wherein the isolation valve operates to maintain pressure within the first component to approximately ten inches atmospheric water pressure or less. 12. The mechanically actuated isolation valve of claim 10, wherein when fluid flows from the second component to the third component upon closing of the normally open internal pathway, a relief pressure associated with the first component is essentially the same irrespective of rate of fluid flow from the second component to the third component. 13. The mechanically actuated isolation valve of claim 1, wherein the diaphragm closes the normally open internal pathway by moving longitudinally in a first direction by approximately 3/16 inch. 14. The mechanically actuated isolation valve of claim 1, wherein fluid flows from the second component to the third component at a rate of up to approximately 100 lpm. 15. The mechanically actuated isolation valve of claim 1, wherein the valve provides essentially the same function whether it is positioned upright or sideways within a larger assembly. 16. An isolation valve adapted for use in a fuel tank emission control system, wherein the valve comprises: a first port for fluid communication with a fuel tank; a second port for fluid communication with a canister for storage of hydrocarbon vapor received from the fuel tank; a third port for fluid communication with an engine purge control valve for delivery of purged hydrocarbon vapors from the canister to the engine for internal combustion therein; a diaphragm disposed within the valve for closing a normally open internal pathway to occlude fluid communication between the first port and the second port and allow flow of hydrocarbon vapor from the second port to the third port in response to a pressure differential across the diaphragm; and a flow sensitive pressure device for controlling the pressure differential across the diaphragm, wherein essentially the same pressure differential is maintained across the diaphragm irrespective of rate of purge flow from the canister to the engine purge control valve, and wherein fluid flow between the fuel tank and the engine purge control valve is prevented upon closing of the normally open internal pathway so long as pressure within the fuel tank is less than the pressure differential across the diaphragm. 17. The isolation valve of claim 16, wherein the pressure differential across the diaphragm is controlled to a relatively constant level of approximately two to approximately four inches of atmospheric water pressure with increasing hydrocarbon vapor flow from the canister to the engine purge control valve after closing of the normally open internal pathway. 18. The isolation valve of claim 16, wherein the valve is capable of purging hydrocarbon vapor from the canister while simultaneously isolating the fuel tank without reliance on reliable operation of electronic components therein. 19. The isolation valve of claim 16, wherein the diaphragm closes the normally open internal pathway in response to a pressure differential of approximately two to approximately four inches atmospheric water pressure. 20. The isolation valve of claim 16, further comprising an overpressure relief ring and an associated overpressure relief spring. 21. The isolation valve of claim 20, wherein pressure is maintained within the fuel tank to approximately ten inches atmospheric water pressure or less. 22. The isolation valve of claim 20, wherein during a purge event a relief pressure associated with the fuel tank is essentially the same irrespective of rate of purge flow from the canister to the engine purge control valve. 23. The isolation valve of claim 16, wherein the diaphragm closes the normally open internal pathway by moving longitudinally in a first direction by approximately 3/16 inch. 24. The isolation valve of claim 16, wherein hydrocarbon vapor is capable of flowing from the canister to the engine purge control valve at a purge flow rate of up to approximately 100 lpm. 25. The isolation valve of claim 16, wherein the valve provides essentially the same function whether it is positioned upright or sideways within a larger assembly. 26. A fuel tank emission control system comprising the isolation valve of claim 16 fluidly coupled between a fuel tank, canister, and engine purge control valve therein. 27. A gasoline-powered vehicle comprising the fuel tank emission control system of claim 26. 28. The gasoline-powered vehicle of claim 27, wherein the vehicle comprises a passenger car. 29. The gasoline-powered vehicle of claim 27, wherein the vehicle comprises a light passenger truck. 30. A method of isolating a fuel tank from a canister within a fuel tank emission control system, the method comprising: providing a mechanically actuated isolation valve in fluid communication with the fuel tank and the canister: initiating purge of the canister, thereby fluidly isolating the fuel tank from the canister by actuating the mechanically actuated isolation valve. 31. The method of claim 30, wherein the mechanically actuated isolation valve comprises: a first port for fluid communication with the fuel tank: a second port for fluid communication with the canister for storage of hydro received from the fuel tank: a third port for fluid communication with an engine purge control valve for delivery of purged hydrocarbon vapors from the canister to the engine for internal combustion therein: a diaphragm disposed within the valve for closing a normally open internal pathway to occlude fluid communication between the first port and the second port and allow flow of hydrocarbon vapor from the second port to the third port in response to a pressure differential across the diaphragm; and a head valve for controlling the pressure differential across the diaphragm, wherein essentially the same pressure differential is maintained across the diaphragm irrespective of rate of purge flow from the canister to the engine purge control valve, and wherein fluid flow between the fuel tank and the engine purge control valve is prevented upon closing of the normally open internal pathway so long as pressure within the fuel tank is less than the pressure differential across the diaphragm. 32. The method of claim 30, wherein the mechanically actuated isolation valve maintains pressure within the fuel tank to approximately ten inches atmospheric water pressure or less. 33. The method of claim 30, wherein the mechanically actuated isolation valve comprises a diaphragm and a flow sensitive pressure device. 34. The method of claim 30, wherein an essentially constant pressure differential is maintained across the diaphragm during the purge. 35. The method of claim 30, wherein the mechanically actuated isolation valve comprises an overpressure relief ring and an associated overpressure relief spring.
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