Multi-stage turbocharger system with exhaust control valve
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02B-033/44
F02D-023/00
출원번호
US-0718645
(2010-03-05)
등록번호
US-8307650
(2012-11-13)
우선권정보
GB-0717212.5 (2007-09-05)
발명자
/ 주소
Robinson, Lee J.
McEwen, James A.
출원인 / 주소
Cummins Turbo Technologies Limited
대리인 / 주소
Krieg DeVault LLP
인용정보
피인용 횟수 :
8인용 특허 :
7
초록▼
A turbocharger system comprises a first relatively small turbocharger and a second relatively large turbocharger connected in series and an exhaust gas flow control valve. The exhaust control valve has an inlet port communicating with the exhaust gas flow upstream of the first turbine a first outlet
A turbocharger system comprises a first relatively small turbocharger and a second relatively large turbocharger connected in series and an exhaust gas flow control valve. The exhaust control valve has an inlet port communicating with the exhaust gas flow upstream of the first turbine a first outlet port communicating with the exhaust flow downstream of said first turbine but upstream of said second turbine, and a second outlet port communicating with the exhaust flow downstream of said second turbine. The valve is operable to selectively permit or block flow through the first and second outlet ports.
대표청구항▼
1. A turbocharger system comprising: a first turbocharger;a second turbocharger larger than the first turbocharger;the first turbocharger comprising a first exhaust turbine situated in a first exhaust passage;the second turbocharger including a second exhaust turbine situated in said first exhaust p
1. A turbocharger system comprising: a first turbocharger;a second turbocharger larger than the first turbocharger;the first turbocharger comprising a first exhaust turbine situated in a first exhaust passage;the second turbocharger including a second exhaust turbine situated in said first exhaust passage downstream of said first exhaust turbine;an exhaust gas flow control valve including: an inlet port communicating with the first exhaust gas passage upstream of the first exhaust turbine;a first outlet port communicating with the first exhaust gas passage downstream of said first exhaust turbine but upstream of said second exhaust turbine; anda second outlet port communicating with said first exhaust gas passage downstream of said second exhaust turbine;wherein the exhaust gas flow control valve is operable to selectively permit or block flow through the first and second outlet ports;wherein the second port has a smaller maximum flow area than either the inlet port or the first outlet port. 2. A turbocharger system according to claim 1, wherein the exhaust gas flow control valve is operable in a first mode to block flow through both the first and second outlet ports, a second mode in which flow is permitted through the first outlet port to allow at least a portion of the exhaust gas flow to bypass the first exhaust turbine alone, and a third mode in which flow is permitted through said second outlet port to allow at least a portion of the exhaust gas flow to bypass both the first and second exhaust turbines. 3. A turbocharger system according to claim 2, wherein in said third mode exhaust gas flow is permitted through both the first and second outlet ports. 4. A turbocharger system according to claim 2, wherein when operating in said second mode the first outlet port is at least partially unobstructed and the second outlet port is fully obstructed. 5. A turbocharger system according to claim 4, wherein in said third mode the first outlet port is fully unobstructed and the second outlet port is at least partially unobstructed. 6. A turbocharger system according to claim 5, wherein in said third mode the second outlet port is fully unobstructed. 7. A turbocharger system according to claim 2, wherein the inlet port is at least substantially unobstructed in each said first, second and third modes. 8. A turbocharger system according to claim 1, wherein the exhaust flow control valve is a rotary valve comprising a valve rotor which is rotatable about a valve axis to selectively block or unblock said first and second outlet ports. 9. A turbocharger system according to claim 8, wherein the valve rotor is rotatable between a first position in which both the first and second outlet ports are fully blocked, a second position in which the first outlet port is unblocked and the second outlet port is fully blocked, and a third position in which the first outlet port is unblocked and the second outlet port is at least partially unblocked. 10. A turbocharger system according to claim 9, wherein when the rotor is in said third position the second outlet port is fully unblocked. 11. A turbocharger system according to claim 9, wherein the rotor is selectively positionable at a plurality of positions between said first and second positions. 12. A turbocharger system according to claim 9, wherein the valve rotor is selectively positionable at a plurality of positions between said second and third positions. 13. A turbocharger system according to claim 9, wherein said valve rotor is selectively positionable at any position between said first, second and third positions. 14. A turbocharger system according to claim 1, wherein the inlet port communicates with a first portion of an exhaust bypass flow path communicating with the first exhaust gas passage upstream of the first exhaust turbine, the first outlet port communicates with a second portion of the exhaust bypass flow path which communicates with the first exhaust gas passage between the first and second exhaust turbines and the second outlet port communicates with a third portion of the exhaust gas bypass flow path which communicates with the first exhaust gas passage downstream of the second exhaust turbine. 15. A turbocharger system according to claim 1, wherein the exhaust gas flow control valve is housed within a housing of the second exhaust turbine. 16. A turbocharger system according to claim 1, further comprising an exhaust brake valve situated in the first exhaust passage. 17. A turbocharger system according to claim 16, wherein the exhaust brake valve is movable between an open position, in which flow through the exhaust brake valve is at least substantially unobstructed; and a closed position, in which flow through the exhaust brake valve is at least substantially prevented. 18. A turbocharger system comprising: a first turbocharger;a second turbocharger larger than the first turbocharger;the first turbocharger comprising a first exhaust turbine situated in a first exhaust passage;the second turbocharger including a second exhaust turbine situated in said first exhaust passage downstream of said first exhaust turbine;an exhaust gas flow control valve including: an inlet port communicating with the first exhaust gas passage upstream of the first exhaust turbine;a first outlet port communicating with the first exhaust gas passage downstream of said first exhaust turbine but upstream of said second exhaust turbine; anda second outlet port communicating with said first exhaust gas passage downstream of said second exhaust turbine;wherein the exhaust gas flow control valve is operable to selectively permit or block flow through the first and second outlet ports;wherein the second outlet port communicates with the first exhaust gas passage via an exhaust gas bypass passage; andwherein a portion of the exhaust gas bypass passage is sized to flow only a portion of the total exhaust gas flow when both the first and second valve outlet ports are fully unobstructed. 19. A turbocharger system comprising: a first turbocharger:a second turbocharger larger than the first turbocharger;the first turbocharger comprising a first exhaust turbine situated in a first exhaust passage;the second turbocharger including a second exhaust turbine situated in said first exhaust passage downstream of said first exhaust turbine;an exhaust gas flow control valve including: an inlet port communicating with the first exhaust gas passage upstream of the first exhaust turbine;a first outlet port communicating with the first exhaust gas passage downstream of said first exhaust turbine but upstream of said second exhaust turbine; anda second outlet port communicating with said first exhaust gas passage downstream of said second exhaust turbine;wherein the exhaust gas flow control valve is operable to selectively permit or block flow through the first and second outlet ports; andan exhaust brake valve situated in the first exhaust passage;wherein the exhaust brake valve is situated upstream of the first exhaust turbine and downstream of a junction with communicating with the inlet port of the exhaust gas flow control valve. 20. A turbocharger system comprising: a first turbocharger;a second turbocharger larger than the first turbocharger;the first turbocharger comprising a first exhaust turbine situated in a first exhaust passage;the second turbocharger including a second exhaust turbine situated in said first exhaust passage downstream of said first exhaust turbine;an exhaust gas flow control valve including: an inlet port communicating with the first exhaust gas passage upstream of the first exhaust turbine;a first outlet port communicating with the first exhaust gas passage downstream of said first exhaust turbine but upstream of said second exhaust turbine; anda second outlet port communicating with said first exhaust gas passage downstream of said second exhaust turbine;wherein the exhaust gas flow control valve is operable to selectively permit or block flow through the first and second outlet ports; andan exhaust brake valve situated in the first exhaust passage;wherein the exhaust brake valve is situated downstream of the first exhaust turbine and upstream of a junction communicating with the second outlet port of the exhaust gas flow control valve. 21. A turbocharger system according to claim 20, wherein the exhaust brake valve is situated upstream of a junction communicating with the first outlet port of the exhaust gas flow control valve. 22. A method of operating a turbocharger system comprising: a first turbocharger;a second turbocharger larger than the first turbocharger;the first turbocharger comprising a first exhaust turbine situated in a first exhaust passage;the second turbocharger including a second exhaust turbine situated in said first exhaust passage downstream of said first exhaust turbine;an exhaust gas flow control valve including:an inlet port communicating with the first exhaust gas passage upstream of the first exhaust turbine;a first outlet port communicating with the first exhaust gas passage downstream of said first exhaust turbine but upstream of said second exhaust turbine; anda second outlet port communicating with said first exhaust gas passage downstream of said second exhaust turbine;an exhaust brake valve situated in the first passage;wherein the exhaust gas flow control valve is operable to selectively permit or block flow through the first and second outlet portsthe method comprising: operating the exhaust gas flow control valve in a first mode to divert all exhaust gas flow through the first exhaust turbine;operating the exhaust gas flow control valve in a second mode to allow at least a portion of the exhaust gas flow to bypass the first exhaust turbine;operating the exhaust gas flow control valve in a third mode to allow exhaust gas flow to bypass the first exhaust turbine, and in addition allow at least a portion of the exhaust gas flow to bypass the second exhaust turbine; andclosing the exhaust brake valve so as to at least substantially prevent flow through the exhaust brake valve; andoperating the exhaust gas flow control valve in an exhaust braking mode to allow at least a portion of the exhaust gas flow to bypass the exhaust brake valve. 23. A method according to claim 22, wherein in said second mode the exhaust gas flow control valve is operated to modulate the amount of exhaust gas flow allowed to bypass the first exhaust turbine. 24. A method according to claim 22, wherein the exhaust gas flow control valve is operated in said third mode to control boost pressure generated by the second turbocharger. 25. A method according to claim 24, wherein the exhaust gas flow control valve is operated in said third mode to allow exhaust gas flow to bypass the second exhaust turbine when the boost pressure generated by the second turbocharger reaches a predetermined limit. 26. A method according to claim 22, wherein the exhaust gas flow control valve is operated in said third mode to control the rotational speed of the second turbocharger. 27. A method according to claim 26, wherein the exhaust gas flow control valve is operated in said third mode when the rotational speed of the second turbocharger reaches a predetermined limit. 28. A method according to claim 22, wherein the exhaust gas flow control valve is operated to modulate the amount of exhaust gas flow allowed to bypass the exhaust brake valve by regulating the exhaust gas flow through any of the following: the inlet port of the exhaust gas flow control valve;the first outlet port of the exhaust gas flow control valve; andthe second outlet port of the exhaust gas flow control valve. 29. A turbocharger system comprising: a first turbocharger;a second turbocharger larger than the first turbocharger;the first turbocharger comprising a first exhaust turbine situated in a first exhaust passage;the second turbocharger including a second exhaust turbine situated in said first exhaust passage downstream of said first exhaust turbine;a bypass gas passage communicating with the first exhaust gas passage at a first junction upstream of the first exhaust turbine and at a second junction downstream of the first exhaust turbine; andan exhaust gas flow control valve located in the bypass passage;wherein the exhaust gas flow control valve is operable to selectively permit or block flow through the bypass gas passage; andthe turbocharger system further comprises an exhaust brake valve situated in the first exhaust gas passage between the first and second junctions. 30. A turbocharger system according to claim 29, wherein the exhaust brake valve is situated between the first junction and the first turbocharger. 31. A turbocharger system according to claim 29, wherein the exhaust brake valve is situated between the first turbocharger and the second junction. 32. A method of operating a turbocharger system comprising: a first turbocharger;a second turbocharger larger than the first turbocharger;the first turbocharger comprising a first exhaust turbine situated in a first exhaust passage;the second turbocharger including a second exhaust turbine situated in said first exhaust passage downstream of said first exhaust turbine;a bypass gas passage communicating with the first exhaust gas passage at a first junction upstream of the first exhaust turbine and at a second junction downstream of the first exhaust turbine; andan exhaust gas flow control valve located in the bypass passage;wherein the exhaust gas flow control valve is operable to selectively permit or block flow through the bypass gas passage; andthe turbocharger system further comprises an exhaust brake valve situated in the first exhaust gas passage between the first and second junctions;the method comprising:operating the turbocharger system in an exhaust braking mode in which the exhaust braking valve is closed to at least substantially block flow through the first passage and the exhaust gas flow control valve is operated to control flow through the bypass gas passage so to modulate the braking force.
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이 특허에 인용된 특허 (7)
Dietz, Martin; Fledersbacher, Peter; Hertweck, Gernot; Sumser, Siegfried, Engine braking method for an internal combustion engine having two serially arranged exhaust-gas turbochargers.
Backlund Ove (Vastra Frolunda SEX) Dahlgren Mats (Stockholm SEX) Rydquist Jan-Erling (Kullavik SEX) Sandberg Lars (Gothenburg ; all og SEX), Method and a device for regulation of a turbo-charging device.
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