Engine control systems and methods for future torque request increases
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
F02D-009/00
F02D-011/10
F02D-041/00
F02D-041/14
F02D-029/02
F02D-023/00
F02D-009/02
F02B-037/18
출원번호
US-0225496
(2014-03-26)
등록번호
US-9920697
(2018-03-20)
발명자
/ 주소
Pochner, Klaus
Whitney, Christopher E.
출원인 / 주소
GM GLOBAL TECHNOLOGY OPERATIONS LLC
인용정보
피인용 횟수 :
1인용 특허 :
124
초록▼
An engine control method includes: generating a torque request for an engine based on a driver input; and based on the torque request, controlling: opening of a wastegate of a turbocharger; opening of a throttle valve based on the torque request; and an intake valve phaser and an exhaust valve phase
An engine control method includes: generating a torque request for an engine based on a driver input; and based on the torque request, controlling: opening of a wastegate of a turbocharger; opening of a throttle valve based on the torque request; and an intake valve phaser and an exhaust valve phaser. The engine control method also includes selectively determining an expected future increase in the torque request. The engine control method also includes, based on the expected future increase and before the torque request increases based on the expected future increase: decreasing the opening of the wastegate; and at least one of: decreasing the opening of the throttle valve; and adjusting at least one of the intake valve phaser and the exhaust valve phaser to decrease a volumetric efficiency of the engine.
대표청구항▼
1. An engine control system of a vehicle, comprising: a driver torque requesting module that generates a first torque request for an engine in response to an increase in an accelerator pedal position;a torque requesting module that determines a second torque request based on the first torque request
1. An engine control system of a vehicle, comprising: a driver torque requesting module that generates a first torque request for an engine in response to an increase in an accelerator pedal position;a torque requesting module that determines a second torque request based on the first torque request;a future request module that, based on an expected increase in the first torque request in response to the increase in the accelerator pedal position, selectively sets a future torque request to greater than the second torque request,an air control module that controls opening of a wastegate of a turbocharger and opening of a throttle valve based on one of the second torque request and the future torque request; andwherein, based on the future torque request being greater than the second torque request, the air control module decreases the opening of the wastegate and the opening of the throttle valve before the expected increase in the first torque request. 2. The engine control system of claim 1 wherein, after the decrease in the opening of the wastegate and the opening of the throttle valve, the air control module increases the opening of the throttle valve when the first torque request increases in response to the increase in the accelerator pedal position. 3. The engine control system of claim 1 wherein, after the decrease in the opening of the wastegate and the opening of the throttle valve, when the first torque request increases in response to the increase in the accelerator pedal position, the air control module increases the opening of the throttle valve and maintains the opening of the wastegate. 4. The engine control system of claim 1 wherein, the future request module further, based on a second expected increase in the first torque request for engagement of an air conditioning compressor clutch, sets the future torque request to greater than the second torque request. 5. The engine control system of claim 1, wherein the future request module further, based on a second expected increase in the first torque request for a driver selecting a sport mode of operation of the vehicle, sets the future torque request to greater than the second torque request. 6. An engine control system of a vehicle, comprising: a torque requesting module that generates a torque request for an engine based on a driver input;an air control module that, based on the torque request, controls opening of a wastegate of a turbocharger, opening of a throttle valve, and intake and exhaust valve phasers; anda future request module that selectively determines an expected future increase in the torque request,wherein, based on the expected future increase and before the torque request increases based on the expected future increase, the air control module decreases the opening of the wastegate and adjusts at least one of the intake valve phaser and the exhaust valve phaser to decrease a volumetric efficiency of the engine. 7. The engine control system of claim 6 wherein, when the torque request increases based on the expected future increase, the air control module maintains the opening of the wastegate and adjusts at least one of the intake valve phaser and the exhaust valve phaser to increase the volumetric efficiency of the engine. 8. The engine control system of claim 6 wherein: the future request module, based on the expected future increase in the torque request in response to an increase in an accelerator pedal position, selectively sets a future torque request to greater than the torque request; andthe air control module, based on the future torque request and before the expected future increase in the torque request, decreases the opening of the wastegate and adjusts at least one of the intake valve phaser and the exhaust valve phaser to decrease the volumetric efficiency of the engine. 9. An engine control method for a vehicle, comprising: determining a first torque request for an engine in response to an increase in an accelerator pedal position;determining a second torque request based on the first torque request;setting a future torque request to greater than the second torque request based on an expected increase in the first torque request in response to the increase in accelerator pedal position;based on one of the second torque request and the future torque request, controlling: opening of a wastegate of a turbocharger;opening of a throttle valve based; andan intake valve phaser and an exhaust valve phaser;based on the future torque request being greater than the second torque request and before the expected increase in the first torque request:decreasing the opening of the wastegate; andadjusting at least one of the intake valve phaser and the exhaust valve phaser to decrease a volumetric efficiency of the engine. 10. The engine control method of claim 9 further comprising, after the decreasing the opening of the wastegate and the adjusting the at least one of the intake valve phaser and the exhaust valve phaser, when the first torque request increases in response to the increase in the accelerator pedal position, at least one of: increasing the opening of the throttle valve; andadjusting at least one of the intake valve phaser and the exhaust valve phaser to increase the volumetric efficiency of the engine. 11. The engine control method of claim 9 further comprising, after the decreasing the opening of the wastegate and the adjusting the at least one of the intake valve phaser and the exhaust valve phaser, when the first torque request increases in response to the increase in the accelerator pedal position: maintaining the opening of the wastegate; andat least one of: increasing the opening of the throttle valve; andadjusting at least one of the intake valve phaser and the exhaust valve phaser to increase the volumetric efficiency of the engine. 12. The engine control method of claim 10 further comprising, based on a second expected increase in the first torque request for engagement of an air conditioning compressor clutch, setting the future torque request to greater than the second torque request. 13. The engine control method of claim 10 further comprising, based on a second expected increase in the first torque request for a driver selecting a sport mode of operation of the vehicle, setting the future torque request to greater than the second torque request.
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