Method and apparatus for controlling a powertrain system including an engine and electro-mechanical transmission
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B60W-010/06
F01L-001/34
B60K-006/08
G06F-017/00
출원번호
US-0634989
(2009-12-10)
등록번호
US-8527120
(2013-09-03)
발명자
/ 주소
Matthews, Gregory P.
Brennan, Daniel G.
출원인 / 주소
GM Global Technology Operations LLC
인용정보
피인용 횟수 :
0인용 특허 :
5
초록▼
A method for controlling a powertrain includes operating an engine substantially at wide open throttle, monitoring an output torque request, controlling the engine input torque by controlling a valve overlap setting for a cylinder of the engine based upon the output torque request wherein controllin
A method for controlling a powertrain includes operating an engine substantially at wide open throttle, monitoring an output torque request, controlling the engine input torque by controlling a valve overlap setting for a cylinder of the engine based upon the output torque request wherein controlling the valve overlap setting for the cylinder modulates a residual burnt gas fraction within the cylinder utilizing at least one of an extended low slope portion of an exhaust valve closing curve and an extended low slope portion of an intake valve opening curve, and controlling an electric machine input torque based upon the output torque request and a time-lag difference between the output torque request and the controlled engine input torque.
대표청구항▼
1. Method for controlling a powertrain comprising an electro-mechanical transmission, an internal combustion engine and an electric machine, the engine providing an engine input torque to the transmission and the electric machine providing an electric machine input torque to the transmission, the tr
1. Method for controlling a powertrain comprising an electro-mechanical transmission, an internal combustion engine and an electric machine, the engine providing an engine input torque to the transmission and the electric machine providing an electric machine input torque to the transmission, the transmission providing an output torque comprising the engine and electric machine input torques, the method comprising: operating the engine substantially at wide open throttle;monitoring an output torque request;controlling the engine input torque employing an engine control module by controlling a valve overlap setting for a cylinder of the engine based upon the output torque request wherein controlling the valve overlap setting for the cylinder modulates a residual burnt gas fraction within the cylinder utilizing at least one of a modified exhaust valve lift curve that decelerates at a first deceleration rate from a peak exhaust opening to a predetermined exhaust valve opening and then decelerates at a second deceleration rate from the predetermined exhaust valve opening in accordance with an extended low slope lift portion of the modified exhaust valve lift curve for a predetermined exhaust valve closing phase angle duration, wherein a magnitude of the second deceleration rate is less than a magnitude of the first deceleration rate, anda modified intake valve lift curve that accelerates at a first acceleration rate from a predetermined intake valve opening in accordance with an extended low slope portion of the modified intake valve lift curve for a predetermined intake valve opening phase angle duration and then accelerates at a second acceleration rate after the predetermined intake valve opening phase angle duration, wherein a magnitude of the first acceleration rate is less than a magnitude of the second acceleration rate; andcontrolling the electric machine input torque based upon the output torque request and a time-lag difference between the output torque request and the controlled engine input torque. 2. The method of claim 1, wherein the predetermined exhaust valve opening and the predetermined intake valve opening comprise a valve lift of less than 1 mm and the predetermined exhaust valve closing phase angle duration and the predetermined intake valve opening phase angle comprise a crank angle duration between about 75 degrees and 100 degrees. 3. The method of claim 1, wherein the valve overlap setting is determined from a look-up table. 4. The method of claim 1, wherein the valve overlap setting is determined from a programmed functional relationship of the output torque request, the engine input torque, and the residual burnt gas fraction. 5. The method of claim 1, wherein controlling the electric machine torque comprises feedback control. 6. The method of claim 1, wherein controlling the electric machine torque comprises feed forward control. 7. The method of claim 1, wherein operating said engine substantially at wide open throttle comprises operating said engine substantially at wide open throttle when the monitored output torque request exceeds a minimum output torque request. 8. The method of claim 1, wherein monitoring the output torque request comprises monitoring an accelerator pedal position. 9. The method of claim 1, wherein the modulated residual burnt gas fraction creates a dilutent to a subsequent unburned gas mixture in the cylinder. 10. The method of claim 1 wherein the powertrain further comprises a plurality of electric machines and controlling the electric machine input torque comprises controlling electric machine input torques of said plurality of electric machines. 11. Method for controlling a powertrain comprising an electro-mechanical transmission, an internal combustion engine and an electric machine, the engine providing an engine input torque to the transmission and the electric machine providing an electric machine input torque to the transmission, the transmission providing an output torque comprising the engine and electric machine input torques, the method comprising: operating the engine substantially at wide open throttle;monitoring an output torque request;transitioning the engine input torque employing an engine control module in response to the monitored output torque request by diluting an air fuel charge within a cylinder of the engine through controlling a valve overlap of an exhaust valve and an intake valve of the cylinder, the valve overlap provided by at least one of a modified exhaust valve lift curve that decelerates at a first deceleration rate from a peak exhaust opening to a predetermined exhaust valve opening and then decelerates at a second deceleration rate from the predetermined exhaust valve opening in accordance with an extended low slope lift portion of the modified exhaust valve lift curve for a predetermined exhaust valve closing phase angle duration, wherein a magnitude of the second deceleration rate is less than a magnitude of the first deceleration rate, anda modified intake valve lift curve that accelerates at a first acceleration rate from a predetermined intake valve opening in accordance with an extended low slope portion of the modified intake valve lift curve for a predetermined intake valve opening phase angle duration and then accelerates at a second acceleration rate after the predetermined intake valve opening phase angle duration, wherein a magnitude of the first acceleration rate is less than a magnitude of the second acceleration rate; andduring transitioning the engine input torque, controlling the electric machine input torque in response to the output torque request and the engine input torque. 12. The method of claim 11, wherein the extended low slope portion of the exhaust valve closing curve overlaps an intake valve opening curve. 13. The method of claim 11, wherein the extended low slope portion of the intake valve opening curve overlaps an exhaust valve closing curve. 14. The method of claim 12, wherein the intake valve opening curve comprises the extended low slope portion of the intake valve opening curve. 15. The method of claim 11, wherein the predetermined exhaust valve opening and the predetermined intake valve opening comprises a valve lift of less than 1 mm and the predetermined exhaust valve closing phase angle duration and the predetermined intake valve opening phase angle comprise a crank angle duration between about 75 degrees and 100 degrees. 16. The method of claim 11, wherein controlling the electric machine input torque compensates for a difference between the output torque request and the engine input torque. 17. A powertrain system, comprising: an electro-mechanical transmission;an internal combustion engine providing an engine input torque to the transmission, said engine comprising a throttle device, a combustion chamber, an exhaust valve, an intake valve, an exhaust cam, an intake cam, an exhaust cam phaser adjusting the timing of the exhaust cam, and an intake cam phaser adjusting the timing of the intake cam;an electric machine providing an electric machine input torque to the transmission;the transmission providing an output torque comprising the engine and electric machine input torques; anda control module operating the throttle device at a substantially wide open position,monitoring an output torque request,controlling the engine input torque through controlling charge dilution in the combustion chamber by a valve overlap setting, the valve overlap setting provided by at least one of the exhaust cam phaser that controls a modified exhaust valve lift curve that decelerates at a first deceleration rate from a peak exhaust opening to a predetermined exhaust valve opening and then decelerates at a second deceleration rate from the predetermined exhaust valve opening in accordance with an extended low slope lift portion of the modified exhaust valve lift curve for a predetermined exhaust valve closing phase angle duration, wherein a magnitude of the second deceleration rate is less than a magnitude of the first deceleration rate, andthe intake cam phaser that controls a modified intake valve lift curve that accelerates at a first acceleration rate from a predetermined intake valve opening in accordance with an extended low slope portion of the modified intake valve lift curve for a predetermined intake valve opening phase angle duration and then accelerates at a second acceleration rate after the predetermined intake valve opening phase angle duration, wherein a magnitude of the first acceleration rate is less than a magnitude of the second acceleration rate, andcontrolling the electric machine input torque based upon the output torque request and a time-lag difference between the output torque request and the engine input torque. 18. The powertrain system of claim 17, further comprising a plurality of electric machines. 19. The method of claim 17, wherein the predetermined exhaust valve opening and the predetermined intake valve opening comprise a valve lift of less than 1 mm and the predetermined exhaust valve closing phase angle duration and the predetermined intake valve opening phase angle comprise a crank angle duration between about 75 degrees and 100 degrees.
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이 특허에 인용된 특허 (5)
Yang,Jialin, Control of autoignition timing in a HCCI engine.
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