Method for controlling an internal combustion engine
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02D-041/00
F02D-041/40
F02D-041/24
F01N-003/20
F01N-003/021
F02D-041/30
F02P-005/04
F02D-037/02
F02D-041/38
출원번호
US-0092252
(2016-04-06)
등록번호
US-9845763
(2017-12-19)
발명자
/ 주소
Solomon, Arun S.
Otto, Ronald M.
출원인 / 주소
GM Global Technology Operations LLC
대리인 / 주소
Quinn IP Law
인용정보
피인용 횟수 :
0인용 특허 :
6
초록▼
A fuel injection strategy and ignition timing for a spark-ignition direct fuel injection engine are selected in response to monitored engine load in relation to a plurality of load regions. This includes selecting a preferred ignition timing based upon the engine load, and selecting a first fuel inj
A fuel injection strategy and ignition timing for a spark-ignition direct fuel injection engine are selected in response to monitored engine load in relation to a plurality of load regions. This includes selecting a preferred ignition timing based upon the engine load, and selecting a first fuel injection event that is executed post-ignition, wherein the first fuel injection event delivers a set fuel mass at a preset timing relative to the preferred timing for the spark ignition event regardless of the engine load. A first pre-ignition fuel injection event is selected, and includes a second fuel mass being injected at a second fuel injection timing, wherein an end-of-injection timing of the first pre-ignition fuel injection event is at a preset timing relative to the preferred ignition timing regardless of the engine load, and wherein the second fuel mass is determined in relation to the engine load.
대표청구항▼
1. A multi-cylinder spark-ignition direct injection (SIDI) internal combustion engine, comprising: a plurality of direct-injection fuel injectors that are arranged to inject fuel into individual cylinders of the engine;a plurality of spark plugs including tip portions that are inserted into the indi
1. A multi-cylinder spark-ignition direct injection (SIDI) internal combustion engine, comprising: a plurality of direct-injection fuel injectors that are arranged to inject fuel into individual cylinders of the engine;a plurality of spark plugs including tip portions that are inserted into the individual cylinders of the engine;an engine controller operatively connected to the fuel injectors and the spark plugs and in communication with a plurality of engine sensors, the engine controller including instruction sets, the instruction sets executable to:separate engine load into a plurality of separate, contiguous load regions ranging between a minimum load region and a maximum load region; monitor engine load;select a preferred fuel injection strategy and a preferred ignition timing for each cylinder event responsive to the monitored engine load in relation to the plurality of load regions; andexecute the selected preferred fuel injection strategy and preferred ignition timing for the cylinder event;wherein the preferred fuel injection strategy and preferred ignition timing for each cylinder event are selected responsive to the monitored engine load in relation to the plurality of load regions, including: select a preferred timing for a spark ignition event based upon the load;select a post-ignition fuel injection event including a first fuel mass being injected at a first fuel injection timing;select a first pre-ignition fuel injection event including a second fuel mass being injected at a second fuel injection timing, wherein the first pre-ignition fuel injection event is proximal to the spark ignition event when the engine load falls within the minimum load region;add a second pre-ignition fuel injection event including a third fuel mass being injected at a third fuel injection timing, wherein the second pre-ignition fuel injection event occurs prior to the first pre-ignition fuel injection event when the engine load falls within a second of the load regions greater than the minimum load region;add a third pre-ignition fuel injection event including a fourth fuel mass being injected at a fourth fuel injection timing, wherein the third pre-ignition fuel injection event occurs prior to the second pre-ignition fuel injection event when the engine load falls within a third of the load regions greater than the second load region; andadd a fourth pre-ignition fuel injection event including a fifth fuel mass being injected at a fifth fuel injection timing, wherein the fourth pre-ignition fuel injection event occurs prior to the third pre-ignition fuel injection event when the engine load falls within a fourth of the load regions greater than the third load region. 2. The internal combustion engine of claim 1, further comprising an intake air compressor, wherein the minimum load region corresponds to engine operation with the intake air compressor at a zero boost condition, and wherein the maximum load region corresponds to engine operation with the intake air compressor near a full boost condition. 3. A method for controlling a spark-ignition, direct fuel injection internal combustion engine, the method comprising: separating engine load into a plurality of separate, contiguous load regions ranging between a minimum load region and a maximum load region;monitoring engine load;selecting a preferred fuel injection strategy and selecting a preferred ignition timing for each cylinder event responsive to the monitored engine load and in relation to the plurality of load regions; andexecuting the selected preferred fuel injection strategy and executing a spark ignition event at the preferred ignition timing for each cylinder event;wherein selecting the preferred fuel injection strategy and preferred ignition timing for each cylinder event responsive to the monitored engine load in relation to the plurality of load regions includes: selecting the preferred ignition timing based upon the engine load,selecting a first fuel injection event that is executed post-ignition, wherein the first fuel injection event delivers a set fuel mass at a preset timing relative to the preferred timing for the spark ignition event regardless of the engine load, andselecting a first pre-ignition fuel injection event including a second fuel mass being injected at a second fuel injection timing, wherein an end-of-injection timing of the first pre-ignition fuel injection event is at a preset timing relative to the preferred ignition timing for the spark ignition event regardless of the engine load, and wherein the second fuel mass is determined in relation to the engine load. 4. The method of claim 3, further comprising adding a second pre-ignition fuel injection event including a third fuel mass being injected at a third fuel injection timing, wherein the second pre-ignition fuel injection event occurs prior to the first pre-ignition fuel injection event when the engine load falls within a second of the load regions that is greater than the minimum load region. 5. The method of claim 4, further comprising adding a third pre-ignition fuel injection event including a fourth fuel mass being injected at a fourth fuel injection timing, wherein the third pre-ignition fuel injection event occurs prior to the second pre-ignition fuel injection event when the engine load falls within a third of the load regions that is greater than the second load region. 6. The method of claim 5, further comprising adding a fourth pre-ignition fuel injection event including a fifth fuel mass being injected at a fifth fuel injection timing, wherein the fourth pre-ignition fuel injection event occurs prior to the third pre-ignition fuel injection event when the engine load falls within a fourth of the load regions that is greater than the third load region. 7. The method of claim 6, wherein the fourth load region comprises the maximum load region. 8. The method of claim 7, wherein the third fuel mass is a constant value during engine operation in the third and fourth load regions. 9. The method of claim 7, wherein the fourth fuel mass is a constant value during engine operation in the fourth load region. 10. The method of claim 6, wherein selecting timings of one of the first, second, third and fourth fuel injection events comprises selecting timings of end-of-injections for the corresponding one of the first, second, third and fourth fuel injection events. 11. The method of claim 6, wherein selecting timings of one of the first, second, third and fourth fuel injection events comprises selecting timings of start-of-injections for the corresponding one of the first, second, third and fourth fuel injection events. 12. The method of claim 3, wherein selecting the first pre-ignition fuel injection event further comprises selecting the timing of the second fuel injection event based upon combustion stability. 13. The method of claim 3, further comprising selecting the second fuel injection mass based upon the engine load and engine knock. 14. The method of claim 3, wherein adding the second pre-ignition fuel injection event comprises adding the third fuel mass injected at the third fuel injection timing based upon smoke generation. 15. The method of claim 3, wherein adding the third pre-ignition fuel injection event comprises adding the fourth fuel mass injected at the fourth fuel injection timing based upon smoke generation. 16. The method of claim 3, wherein adding the fourth pre-ignition fuel injection event comprises adding the fifth fuel mass injected at the fifth fuel injection timing based upon smoke generation. 17. A method for controlling a spark-ignition, direct fuel injection internal combustion engine that includes an intake air compressor, the method comprising: separating engine load into a plurality of separate, contiguous load regions ranging between a minimum load region and a maximum load region;monitoring engine load;selecting a preferred fuel injection strategy, wherein the preferred fuel injection strategy includes selecting a first pre-ignition fuel injection event including a second fuel mass being injected at a second fuel injection timing, wherein the first pre-ignition fuel injection event is proximal to the spark ignition event when the engine load falls within the minimum load region;selecting a preferred ignition timing for a spark ignition event for each cylinder event responsive to the monitored engine load;executing the selected preferred fuel injection strategy and the spark ignition event timing for each cylinder event;wherein selecting the preferred fuel injection strategy for each cylinder event responsive to the monitored engine load in relation to the plurality of load regions includes: selecting a first fuel injection event that is executed post-ignition, wherein the first fuel injection event delivers a set fuel mass at a preset timing relative to the preferred timing for the spark ignition event regardless of the engine load, andselecting a first pre-ignition fuel injection event including a second fuel mass being injected at a second fuel injection timing, wherein the second fuel mass is determined in relation to the engine load;adding a second pre-ignition fuel injection event including a third fuel mass being injected at a third fuel injection timing, wherein the second pre-ignition fuel injection event occurs prior to the first pre-ignition fuel injection event when the engine load falls within a second ofthe load regions greater than the minimum load region; adding a third pre-ignition fuel injection event including a fourth fuel mass being injected at a fourth fuel injection timing, wherein the third pre-ignition fuel injection event occurs prior to the second pre-ignition fuel injection event when the engine load falls within a third of the load regions greater than the second load region;adding a fourth pre-ignition fuel injection event including a fifth fuel mass being injected at a fifth fuel injection timing, wherein the fourth pre-ignition fuel injection event occurs prior to the third pre-ignition fuel injection event when the engine load falls within a fourth of the load regions greater than the third load region. 18. The method of claim 17, wherein the minimum load region corresponds to engine operation with the intake air compressor at a zero boost condition. 19. The method of claim 17, wherein the maximum load region corresponds to engine operation with the intake air compressor near a full boost condition.
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이 특허에 인용된 특허 (6)
Sugano, Kazumitsu; Metsugi, Hiromitsu; Oishi, Toshiya, Control unit for vehicle driving device.
Lippert, Andreas M.; Otto, Ronald M.; Parrish, Scott E.; Solomon, Arun S.; Upatnieks, Ansis; Zeng, Yangbing, Method and apparatus for operating a spark-ignited direct fuel injection engine.
Szekely, Jr.,Gerald A.; Huebler,Mark S.; Parrish,Scott E.; Schimelfening,Gerald J.; Lippert,Andreas M., Method and apparatus to control combustion in a spray-guided direct injection spark-ignited engine.
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