Microcondenser device and evaporative emission control system and method having microcondenser device
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02M-033/02
B01D-053/00
F02M-025/08
F02M-031/20
H01L-035/00
B01D-053/04
출원번호
US-0702796
(2011-06-08)
등록번호
US-9334837
(2016-05-10)
국제출원번호
PCT/US2011/039563
(2011-06-08)
§371/§102 date
20130129
(20130129)
국제공개번호
WO2011/156452
(2011-12-15)
발명자
/ 주소
Chung, Dennis B.
출원인 / 주소
Honda Motor Co., Ltd.
대리인 / 주소
Rankin, Hill & Clark LLP
인용정보
피인용 횟수 :
1인용 특허 :
36
초록▼
A microcondenser device for an evaporative emission control system includes a housing having an inlet for receiving fuel vapor and a condensation outlet for discharging condensed fuel vapor, and a porous element disposed in the housing and fluidly interposed between the inlet and the condensation ou
A microcondenser device for an evaporative emission control system includes a housing having an inlet for receiving fuel vapor and a condensation outlet for discharging condensed fuel vapor, and a porous element disposed in the housing and fluidly interposed between the inlet and the condensation outlet for absorbing the fuel vapor received through the inlet. The microcondenser device further includes a thermoelectric element in thermal contact with the porous element for removing heat from the fuel vapor absorbed by the porous element to condense the fuel vapor.
대표청구항▼
1. A microcondenser device for an evaporative emission control system, comprising: a housing having an inlet for receiving fuel vapor and a condensation outlet for discharging condensed fuel vapor;a porous element disposed in the housing and fluidly interposed between the inlet and the condensation
1. A microcondenser device for an evaporative emission control system, comprising: a housing having an inlet for receiving fuel vapor and a condensation outlet for discharging condensed fuel vapor;a porous element disposed in the housing and fluidly interposed between the inlet and the condensation outlet for absorbing the fuel vapor received through the inlet: anda thermoelectric element in thermal contact with the porous element for removing heat from the fuel vapor absorbed by the porous element to condense the fuel vapor;wherein the housing has a lower wall and at least one side wall extending upward from the lower wall, the lower wall and the at least one side wall together define a chamber in the housing, the porous element supported by the at least one side wall in spaced relation relative to the lower wall, the porous element received in the chamber, andwherein at least one support baffle supports the porous element within the housing, wherein the at least one supported baffle includes a first baffle and separate second baffle, the first and second baffles defining a condensation chamber located between the condensation outlet and the porous element. 2. The microcondenser device of claim 1 wherein the porous element is a porous metal, a porous metal alloy, or a carbon foam. 3. The microcondenser device of claim 2 wherein the porous element is a microporous aluminum foam. 4. The microcondenser device of claim 2 wherein the porous element has a varying porosity including an increased porosity adjacent the inlet relative to a porosity adjacent the condensation outlet. 5. The microcondenser device of claim 1 wherein the housing is formed of aluminum which facilitates higher heat transfer from the fuel vapor to the thermoelectric element. 6. The microcondenser device of claim 1 wherein the porous element includes at least one chamber therein. 7. The microcondenser device of claim 6 wherein the porous element is provided with a first side and a second side opposite the first side, the second opposite side having an opening to the at least one chamber. 8. The microcondenser device of claim 7 wherein the first side is positioned adjacent the thermoelectric element. 9. The microcondenser device of claim 1 wherein the porous element includes a first surface disposed adjacent the thermoelectric element and a second, opposite surface having at least one aperture defined therein for reducing a thermal gradient across the porous element. 10. The microcondenser device of claim 1 wherein an insulating layer is disposed one of: around an exterior of the housing or inside the housing around the porous element. 11. The microcondenser device of claim 1 wherein the housing is mounted on a vehicle with the inlet fluidly connected to a fuel tank without a canister interposed between the fuel tank and the inlet, and the outlet is fluidly connected to the fuel tank. 12. The microcondenser device of claim 1 wherein the housing is mounted on a vehicle with the inlet fluidly connected to a fuel canister and the condensation outlet fluidly connected to a fuel tank. 13. The microcondenser device of claim 12 wherein a pump is fluidly interposed between the fuel canister and the inlet for forcing fuel vapor to be purged from the canister into the microcondenser device. 14. The microcondenser device of claim 13 wherein the fuel canister includes a first canister portion and a second canister portion, the first canister portion having a charge inlet fluidly connected to the fuel tank, a drain outlet fluidly connected to atmosphere, a first purge outlet fluidly connected to an intake of an internal combustion engine and a second purge outlet fluidly connected to the second canister portion, the second canister portion having a charge inlet fluidly connected to the second purge outlet of the first canister portion and a purge outlet fluidly connected to the inlet of the microcondenser device. 15. The microcondenser device of claim 1 wherein the inlet is fluidly connected to an underground fuel storage vessel for directing fuel vapor from the vessel to the microcondenser device and the outlet is fluidly connected to the vessel for returning condensed fuel vapor to the vessel. 16. The microcondenser device of claim 10 wherein the insulating layer is disposed inside the housing around the porous element. 17. A microcondenser device for an evaporative emission control system, comprising: a housing having an inlet for receiving fuel vapor and a condensation outlet for discharging condensed fuel vapor;a porous element disposed in the housing and fluidly interposed between the inlet and the condensation outlet for absorbing the fuel vapor received through the inlet; anda thermoelectric element in thermal contact with the porous element for removing heat from the fuel vapor absorbed by the porous element to condense the fuel vapor,wherein the porous element includes a first surface disposed adjacent the thermoelectric element and a second, opposite surface having at least one aperture defined therein for reducin a thermal adient across the orous element, andwherein the at least one aperture extends from the second, opposite surface to a location adjacent and spaced apart from the first surface, and further wherein the at least one aperture is a plurality of apertures dispersed about the second surface of the porous element. 18. The microcondenser device of claim 17 wherein the porous element is formed of microporous aluminum foam and the housing is formed of aluminum. 19. The microcondenser device of claim 17 wherein the porous element is hexahedron shaped with the upper surface forming an upper side and the lower surface forming a lower side, the plurality of apertures arranged in rows and columns on the lower side with at least two rows and at least two columns, and further wherein spacing between the plurality of apertures is approximately equal along each row and along each column. 20. An evaporative emission control system, comprising: a fuel storage vessel wherein vaporized fuel is generated; anda microcondenser device for processing the vaporized fuel received from the fuel storage vessel and for an evaporative emission control system, the microcondenser device including:a housing having an inlet for receiving fuel vapor and a condensation outlet for discharging condensed fuel vapor;a porous portion that facilitates removal of heat from the vaporized fuel, wherein the porous portion is a porous element disposed in the housing and fluidly interposed between the inlet and the condensation outlet for absorbing the fuel vapor received through the inlet; anda thermoelectric element in thermal contact with the porous element for removing heat from the fuel vapor absorbed by the porous element to condense the fuel vapor;wherein the housing has a lower wall and at least one side wall extending upward from the lower wall, the lower wall and the at least one side wall together define a chamber in the housing, the porous element supported by the at least one side wall in spaced relation relative to the lower wall, the porous element received in the chamber, andwherein at least one support baffle supports the element within the housing, wherein the at least one supported baffle includes a first baffle and separate second baffle, the first and second baffles defining a condensation chamber located between the condensation outlet and the porous element. 21. The system of claim 20 further including a canister fluidly interposed between the fuel storage vessel and the microcondenser device, the canister having an inlet for receiving the vaporized fuel from the fuel storage device and a bed element for temporarily retaining the fuel vapor therein, the canister having a purge line fluidly connected to an inlet of the microcondenser device for directing the temporarily retained fuel vapor to the microcondenser device. 22. The system of claim 21 wherein the purge line is selectively fluidly connected to the inlet and is selectively fluidly connected to an engine intake of an internal combustion engine on a vehicle, and further wherein the fuel storage vessel is a fuel tank on the vehicle. 23. The system of claim 21 wherein a pump is fluidly interposed between the canister and the microcondenser device for moving fuel vapor from the canister to the microcondenser device. 24. The system of claim 23 wherein the canister includes a first canister portion and a second canister portion, the first canister portion having the inlet fluidly connected to the fuel tank and a drain port selectively fluidly connected to atmosphere, the purge line including a first purge line portion selectively fluidly connecting the first canister portion to the engine intake and a second purge line portion selectively fluidly connecting the first canister portion to microcondenser device with the second canister portion disposed along the second purge line portion and fluidly interposed between the first canister portion and the second canister portion. 25. The system of claim 20 wherein the fuel storage vessel is an underground fuel storage vessel.
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