Small engine carbon canister with check valve
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02M-033/02
F02M-033/00
출원번호
UP-0553776
(2006-10-27)
등록번호
US-7527044
(2009-07-01)
발명자
/ 주소
Dunkle, Gary L.
Mullins, Josh J.
Frank, Louis T.
출원인 / 주소
Stant Manufacturing Inc.
대리인 / 주소
Barnes & Thornburg LLP
인용정보
피인용 횟수 :
10인용 특허 :
29
초록
A power source is provided for a machine. The power source includes an engine and an engine fuel system of the type that generates fuel vapor containing hydrocarbon material.
대표청구항▼
The invention claimed is: 1. A fuel vapor recovery apparatus comprising a carbon canister including a housing formed to include an interior region, an atmosphere orifice opening into the interior region, and a tank-and-engine orifice opening into the interior region, and a carbon bed located in the
The invention claimed is: 1. A fuel vapor recovery apparatus comprising a carbon canister including a housing formed to include an interior region, an atmosphere orifice opening into the interior region, and a tank-and-engine orifice opening into the interior region, and a carbon bed located in the interior region between the atmosphere orifice and the tank-and-engine orifice, and flow control means for discharging fuel vapor exhausted from a fuel tank into the interior region of the housing through the tank-and-engine orifice to flow through the carbon bed in a direction toward the atmosphere orifice during a fuel tank fuel vapor venting cycle and for applying a vacuum generated by an engine intake when an engine coupled to the engine intake is running to the interior region of the housing through the tank-and-engine orifice to cause atmospheric air to be drawn into the interior region through the atmosphere orifice and into and through the carbon bed to produce a first stream of fuel vapor that exits the housing through the tank-and-engine orifice and through a check valve responsive to the vacuum generated by the engine intake for combustion in the engine during a carbon bed cleaning cycle; wherein the carbon canister further includes an end closure coupled to the housing to close the tank-and-engine orifice and formed to include a passageway arranged to provide vapor/vacuum means for conducting inbound fuel vapor from a fuel tank into the interior region of the housing and outbound fuel vapor from the interior region of the housing to an engine intake coupled to an engine associated with the fuel tank; and wherein the end closure includes an end cap coupled to the housing to close the tank-and-engine orifice and formed to include an aperture defining a first portion of the vapor/vacuum means and a three-way vapor conduit including a first tube section formed to include a housing channel defining a second portion of the vapor/vacuum means, a second tube section formed to include a tank channel defining a third portion of the vapor/vacuum means and terminating at a tank hose mount adapted to mate with a tank hose configured to conduct fuel vapor between the fuel tank and the tank channel, and a third tube section formed to include a vacuum channel defining a fourth portion of the vapor/vacuum means, merging with the housing and tank channels at a junction located inside the three-way vapor conduit, and terminating at a vacuum hose mount adapted to mate with a vacuum hose configured to conduct vacuum between the vacuum channel and the engine intake. 2. The apparatus of claim 1, wherein a first portion of the third tube section is formed to include an annular valve seat, and wherein the three-way vapor conduit further comprises a valve located in a part of the vacuum channel formed in a second portion of the third tube section and a valve-control spring located in the vacuum channel and arranged to yieldably urge the valve to a normally closed channel-closing position mating with the annular valve seat to block flow of fuel vapor from the housing channel and the tank channel into the part of the vacuum channel formed in the second portion of the third tube section and to yield to allow the valve to move to a temporarily opened channel-opening position unmating from the annular valve seat to allow flow of fuel vapor from the housing channel into the part of the vacuum channel formed in the second portion of the third tube section. 3. The apparatus of claim 1, wherein the third tube section includes a first portion coupled to the first and second tube sections and a second portion coupled to the first portion and formed to include the vacuum hose mount and wherein the end cap, first tube section, second tube section, and first portion of the third tube section cooperate to define a monolithic element made of a plastics material. 4. The apparatus of claim 3, wherein the first portion of the third tube section is formed to include an annular valve seat, and wherein the three-way vapor conduit further comprises a valve located in a part of the vacuum channel formed in the second portion of the third tube section and a valve-control spring located in the vacuum channel and arranged to yieldably urge the valve to a normally closed channel-closing position mating with the annular valve seat to block flow of fuel vapor from the housing channel and the tank channel into the part of the vacuum channel formed in the second portion of the third tube section and to yield to allow the valve to move to a temporarily opened channel-opening position unmating from the annular valve seat to allow flow of fuel vapor from the housing channel into the part of the vacuum channel formed in the second portion of the third tube section. 5. A fuel vapor recovery apparatus comprising a carbon canister including a housing formed to include an interior region, an atmosphere orifice opening into the interior region, and a tank-and-engine orifice opening into the interior region, and a carbon bed located in the interior region between the atmosphere orifice and the tank-and-engine orifice, and flow control means for discharging fuel vapor exhausted from a fuel tank into the interior region of the housing through the tank-and-engine orifice to flow through the carbon bed in a direction toward the atmosphere orifice during a fuel tank fuel vapor venting cycle and for applying a vacuum generated by an engine intake when an engine coupled to the engine intake is running to the interior region of the housing through the tank-and-engine orifice to cause atmospheric air to be drawn into the interior region through the atmosphere orifice and into and through the carbon bed to produce a first stream of fuel vapor that exits the housing through the tank-and-engine orifice and through a check valve responsive to the vacuum generated by the engine intake for combustion in the engine during a carbon bed cleaning cycle; wherein the carbon canister further includes an end closure coupled to the housing to close the tank-and-engine orifice and formed to include a passageway arranged to provide vapor/vacuum means for conducting inbound fuel vapor from a fuel tank into the interior region of the housing and outbound fuel vapor from the interior region of the housing to an engine intake coupled to an engine associated with the fuel tank; and wherein the end closure includes an end cap coupled to the housing to close the tank-and-engine orifice and formed to include an aperture defining a first portion of the vapor/vacuum means, a check valve assembly, and a three-legged vapor conductor having a first leg coupled to the end cap to receive fuel vapor through the aperture, a second leg adapted to be coupled to a fuel tank vapor line to receive fuel vapor from a fuel tank, and a third leg coupled to the check valve assembly and also to the first and second legs at a junction to discharge fuel vapor from the first and second legs to the check valve assembly. 6. The apparatus of claim 5, wherein the end cap and the three-legged conductor cooperate to define a monolithic element made of a plastics material. 7. A fuel vapor recovery apparatus comprising a carbon canister including a housing formed to include an interior region, an atmosphere orifice opening into the interior region, and a tank-and-engine orifice opening into the interior region, and a carbon bed located in the interior region between the atmosphere orifice and the tank-and-engine orifice, and flow control means for discharging fuel vapor exhausted from a fuel tank into the interior region of the housing through the tank-and-engine orifice to flow through the carbon bed in a direction toward the atmosphere orifice during a fuel tank fuel vapor venting cycle and for applying a vacuum generated by an engine intake when an engine coupled to the engine intake is running to the interior region of the housing through the tank-and-engine orifice to cause atmospheric air to be drawn into the interior region through the atmosphere orifice and into and through the carbon bed to produce a first stream of fuel vapor that exits the housing through the tank-and-engine orifice and through a check valve responsive to the vacuum generated by the engine intake for combustion in the engine during a carbon bed cleaning cycle: wherein the carbon canister further includes an end closure coupled to the housing to close the tank-and-engine orifice and formed to include a passageway arranged to provide vapor/vacuum means for conducting inbound fuel vapor from a fuel tank into the interior region of the housing and outbound fuel vapor from the interior region of the housing to an engine intake coupled to an engine associated with the fuel tank; and wherein the end closure includes an end cap coupled to the housing to close the tank-and-engine orifice and formed to include an aperture defining a first portion of the vapor/vacuum means and a two-way vapor conduit including lower and upper tube sections, the lower tube section is formed to include a tank channel defining a second portion of the vapor/vacuum means and terminating at a tank hose mount adapted to mate with a tank hose configured to conduct fuel vapor between the fuel tank and the tank channel, and the upper tube section is formed to include a vacuum channel defining a third portion of the vapor/vacuum means, merging with the aperture and tank channel at a junction located inside the two-way vapor conduit, and terminating at a vacuum hose mount adapted to mate with a vacuum hose configured to conduct vacuum between the vacuum channel and the engine intake. 8. The apparatus of claim 7, wherein the upper and lower tube sections cooperate to define an included angle of about 26° therebetween. 9. The apparatus of claim 7, wherein the upper tube section, the lower tube section, and the end cap cooperate to define a monolithic element made of a plastics material. 10. The apparatus of claim 7, wherein the two-way vapor conduit further includes a valve located in the vacuum channel and a valve-control spring located in the vacuum channel and arranged to yieldably urge the valve to a normally closed channel-closing position mating with an annular valve scat associated with the vacuum channel to block flow of fuel vapor from the aperture in the end cap and the tank channel into a part of the vacuum channel formed in the vacuum hose mount and to yield to allow the valve to move to a temporarily opened channel-opening position unmating from the annular valve seat to allow flow of fuel vapor from the aperture formed in the end cap into the part of the vacuum channel formed in the vacuum hose mount for delivery to the engine intake and the engine. 11. A fuel vapor recovery apparatus comprising a carbon canister including a housing formed to include an interior region, an atmosphere orifice opening into the interior region, and a tank-and-engine orifice opening into the interior region, and a carbon bed located in the interior region between the atmosphere orifice and the tank-and-engine orifice, and flow control means for discharging fuel vapor exhausted from a fuel tank into the interior region of the housing through the tank-and-engine orifice to flow through the carbon bed in a direction toward the atmosphere orifice during a fuel tank fuel vapor venting cycle and for applying a vacuum generated by an engine intake when an engine coupled to the engine intake is running to the interior region of the housing through the tank-and-engine orifice to cause atmospheric air to be drawn into the interior region through the atmosphere orifice and into and through the carbon bed to produce a first stream of fuel vapor that exits the housing through the tank-and-engine orifice and through a check valve responsive to the vacuum generated by the engine intake for combustion in the engine during a carbon bed cleaning cycle; and wherein the carbon canister further includes an end closure coupled to the housing to close the tank-and-engine orifice and formed to include a vapor conduit and a separate vacuum conduit, the vapor conduit is configured to define vapor means for conducting inbound fuel vapor from a fuel tank into the interior region of the housing to reach the carbon bed located in the interior region of the housing so that hydrocarbons associated with the inbound fuel vapor are captured by the carbon bed, and the vacuum conduit is configured to define vacuum means for conducting outbound fuel vapor from the interior region of the housing toward an engine intake coupled to an engine associated with the fuel tank so that hydrocarbons released by the carbon bed and entrained in the outbound fuel vapor are burned in the engine after discharge from the interior region of the housing. 12. The apparatus of claim 11, wherein the end closure includes an end cap coupled to the housing to close the tank-and-engine orifice and formed to include a vapor aperture defining a first portion of the vapor means and a vacuum aperture defining a first portion of the vacuum means, a vapor tube coupled to the end cap at the vapor aperture and formed to include a tank channel defining a second portion of the vapor means, and a base coupled to the end cap at the vacuum aperture and formed to include a vacuum channel defining a second portion of the vacuum means. 13. The apparatus of claim 12, wherein the end cap and the tube cooperate to define a monolithic element made of a plastics material. 14. The apparatus of claim 12, wherein the base is formed to include a housing tube adapted to mate with a vacuum purge line and a valve housing arranged to lie between the housing tube and the end cap, and further comprising a valve mounted for movement in a first segment of the vacuum channel located in the valve housing and a valve control spring located in the first segment of the vacuum channel and arranged yieldably to urge the valve to a normally closed channel-closing position mating with an annular valve seat included in the base to block flow of fuel vapor from the interior region of the housing and the first segment of the vacuum channel into a second segment of the vacuum channel formed in the housing tube and to yield to allow flow of fuel vapor from the interior region of the housing and the first segment of the vacuum channel into the second segment of the vacuum channel formed in the housing tube. 15. The apparatus of claim 14 wherein a distal portion of the housing tube is formed to include a vacuum hose mount adapted to mate with a vacuum hose configured to provide the vacuum purge line. 16. The apparatus of claim 12, wherein a distal portion of the vapor tube is formed to include a tank hose mount adapted to mate with a tank hose configured to conduct fuel vapor between a fuel tank and the vapor tube. 17. A fuel vapor recovery apparatus comprising a carbon canister including a housing formed to include an interior region, an atmosphere orifice opening into the interior region, a tank-and-engine orifice opening into the interior region, and a carbon bed located in the interior region between the atmosphere orifice and the tank-and-engine orifice, and an end closure including an end cap, a check valve assembly, and a three-legged vapor conductor interposed between the end cap and the check valve assembly, wherein the end cap is coupled to the housing to close the tank-and-engine orifice and formed to include an aperture and the check valve assembly is formed to include an aperture, and the three-legged vapor conductor includes a first leg coupled to the end cap to receive fuel vapor through the aperture formed in the end cap, a second leg adapted to be coupled to a fuel tank vapor line to receive fuel vapor from a fuel tank, and a third leg coupled to the aperture of the check valve assembly and also to the first and second legs at a junction to discharge fuel vapor from the first and second legs into the check valve assembly through the aperture of the check valve assembly. 18. A fuel vapor recovery apparatus comprising a carbon canister including a housing formed to include an interior region, an atmosphere orifice opening into the interior region, a tank-and-engine orifice opening into the interior region, and a carbon bed located in the interior region between the atmosphere orifice and the tank-and-engine orifice, and an end cap closure including an end cap, a tank conduit, and a vacuum conduit, and wherein the end cap is coupled to the housing to close the tank-and-engine orifice and formed to include a vapor aperture and a vacuum aperture, the tank conduit is coupled to the end cap at the vapor aperture, the vapor conduit is coupled to the end cap at the vacuum aperture, and further comprising a valve mounted for movement in a channel formed in the vacuum conduit and a valve control spring located in the vacuum conduit and arranged yieldably to urge the valve to a normally closed channel-closing position mating with an annular valve seat included in the vacuum conduit to block flow of fuel vapor from the interior region of the housing through the channel formed in the vacuum conduit and to yield to allow flow of fuel vapor from the interior region of the housing and through the channel formed in the vacuum conduit.
Heath Stephen D. (Chula Vista CA) Borbolla ; Jr. Lorenzo (Dulzura CA), Method and apparatus for controlling displaced vapor emissions in motor vehicles.
Urich Carl L. (7293 S. Sherman St. Littleton CO 80122), Method and apparatus for producing and supplying atomized fuel to an internal combustion engine.
Curran Patrick J. (Farmington Hills MI) Niessen Paul M. (Canton MI) Schwager Bryce A. (Ypsilanti MI), Method and system for monitoring evaporative purge flow.
Dudar, Aed M.; Pearce, Russell Randall; Yang, Dennis Seung-Man; Ognjanovski, Jr., Robert; Ghannam, Mahmoud Yousef, Latchable valve and method for operation of the latchable valve.
※ AI-Helper는 부적절한 답변을 할 수 있습니다.