This invention relates to an engine control device. In particular, it relates to control executed by an engine control device when a driver shifts a shift lever position from a stationary range position (P range position or N range position) to a running range position (D range position or R range position).
A prior art technique disclosed in Tokkai Sho61-105228 published by the Japan Patent Office in 1986 reduces engine torque when the shift lever position is shifted from a stationary range position to a running range position in a stationary state of the vehicle. The prior art technique delays the ignition timing of the engine in response to the engagement of a forward/reverse clutch used for starting the vehicle. Consequently torque inputted to the clutch from the engine is reduced in the time period from the commencement of engagement of the forward/reverse clutch to completion of engagement. Thus, output torque from an automatic/transmission is reduced in this time period. In this manner, it is possible to suppress differences in output torque of an automatic/transmission (torque differentials) before and after the shift of the automatic transmission from a stationary range to a running range. Furthermore it is possible to suppress torque shock associated with clutch engagement.
However the prior art technique for suppressing torque differentials only takes account of the fact that before shifting to a running range the output torque of the automatic transmission approaches the output torque after the shift. It does not take account of an overshoot or under shoot of the output torque of the automatic transmission.
It is therefore an object of this invention to further suppress torque shock associated with shifting from a stationary range to a running range in an automatic transmission.
In order to achieve the above object, this invention provides an engine control device for a vehicle, the vehicle having an engine, an automatic transmission receiving an output torque of the engine, a drive shaft for transmitting an output torque from the automatic transmission to the vehicle wheels and a shift lever for selecting the operating range of the automatic transmission; wherein the operating range of the automatic transmission includes a stationary range in which the engine output torque is not transmitted to a side of the drive shaft and a running range in which the engine output torque is transmitted to the side of the drive shaft, and a shift lever position includes a stationary range position corresponding to the stationary range of the automatic transmission and a running range position corresponding to the running range of the automatic transmission. The engine control device comprises a torque control mechanism for regulating the engine output torque, the torque control mechanism including at least one of a fuel injector for injecting fuel and a throttle valve for regulating an intake air amount to the engine; a sensor for detecting the shift lever position; and a controller. The controller is programmed to detect a shift in the shift lever position from the stationary range position to the running range position based on the shift lever position; and transmit a command signal to the torque control mechanism when a first predetermined period elapses after the detection of the shift in the shift lever position, the command signal increasing the engine output torque by a predetermined correction gain from a first output torque at the detection of the shift lever position to a second output torque.
Further, this invention provides an engine control method for the vehicle, the engine control method comprising the steps of detecting the shift lever position; detecting a shift in the shift lever position from the stationary range position to the running range position based on the shift lever position; and transmitting a command signal to the torque control mechanism when a first predetermined period elapses after the detection of the shift in the shift lever position, the command signal increasing the engine output torque by a predetermined correction gain from a first output torque at the detection of the shift lever position to a second output torque. The torque control mechanism includes at least one of a fuel injector for injecting fuel and a throttle valve for regulating an intake air amount to the engine.
The details as well as other features and advantages of this invention are set forth in the remainder of the specification and are shown in the accompanying drawings.
Referring to
The engine control device 20 comprises a controller 9 (electric control unit), an inhibitor switch 10, a torque control mechanism 17 and an engine rotation sensor 19. The torque control mechanism 17 is provided with a fuel injector 12 for injecting fuel or a throttle valve 11 for regulating the intake air amount to the engine, or both. The inhibitor switch 10 is a sensor detecting the shift lever position and outputting a detection signal (range signal) to the controller 9. The controller 9 detects variation in the shift lever position based on a variation in the range signal. The engine rotation speed sensor 19 detects the engine rotation speed.
The controller 9 transmits a command signal to the torque control mechanism 17 in response to the operating state of the vehicle including vehicle speed and acceleration pedal position. In other words, the controller 9 controls either the fuel injection amount of the fuel injector 12 or the opening of the throttle valve 11 or controls both simultaneously. A target engine output torque is achieved as a result of control of the opening of the throttle valve 11 or control of fuel injection by the fuel injector 12, or both.
The controller 9 performing the above control comprises a microcomputer provided with a central processing unit (CPU) for executing programs, a read-only memory (ROM) storing programs or data, a random access memory (RAM) temporarily storing data and calculation results from the CPU and an input/output interface (I/O interface).
Referring to the timing chart in
The variation in the range of the transmission 2 is completed at a time t3 separated from the time t2 by an interval Tt2 (for example 0.5 seconds). In other words, the shift of the operating range of the transmission 2 from a stationary range to a running range starts at the time t1 and is completed by the time t3. As shown by the broken line in
In contrast, in this invention as shown by the solid line in
The method for realizing this correction gain will be described in detail hereafter. The predetermined correction gain ΔTe for the engine output torque is set based on the engine rotation speed (normally the idling rotation speed) before the variation (N→D) in the shift lever position is detected. Thus, the correction gain ΔTe increases as the engine rotation speed before the variation (N→D) in the shift lever position increases. The engine load increases as a result of load on auxiliary devices in the operation of auxiliary devices such as the alternator or the air conditioner. In this case, the engine power and thus the engine rotation speed are usually increased by an idle-up device which operates to increase the opening of the throttle valve 11 when an auxiliary device is operating. Consequently the correction gain ΔTe for the engine output torque is set in response to the auxiliary device load. In other words, the correction gain ΔTe is set to increase as the number of operated auxiliary devices increases. In this manner, as shown by the solid line in
After the variation in the shift lever position is detected, the correction on the engine output torque is executed after a time period (Tt1+Tt2) elapses. Thus it is possible to decrease the torque differential by suppressing the undershoot. A decrease in the torque differential suppresses shocks felt by passengers immediately after the shift in the operating range of the transmission 2 from a stationary range to a running range.
The torque differential increases when the load related to operation of auxiliary devices increases. However since the correction gain ΔTe for engine output torque is set in response to the load related to operation of auxiliary devices, it is possible to ensure suppression of a torque differential related to variation in the auxiliary device load.
Referring to the flowchart in
Firstly in a step S1 and a step S2, it is determined whether or not the shift lever position has varied from a stationary range position to a running range position. In the step S1, it is determined whether or not the current shift lever position is in the P range position or the N range position. When the shift lever position is outside the P range position and the N range position, the control routine is terminated. When the shift lever position is in the P or N range in the step S1, the routine proceeds to the step S2 where it is determined whether or not the shift lever position is outside of the P and N range position. When a range position outside of the P and N range is detected, it is determined that the shift lever position has shifted to a running range position and the routine proceeds to a step S3. In the step S2, when a P or N range position is detected, the control routine is terminated.
The predetermined correction gain ΔTe for engine output torque is set based on the engine rotation speed before the variation (N→D) in the shift lever position is detected. In this case, an optional step S1′ may be provided between the step S1 and the step S2. Otherwise, the correction gain ΔTe may be set before the routine starts. In the step S1′, the controller 9 uses the engine rotation speed sensor 19 to detect the engine rotation speed and sets the correction gain ΔTe based on the detected engine rotation speed.
In a step S3, the time is counted up and it is determined whether or not the elapsed time after the detection of the shift in the shift lever position in the step S2 is greater than a first predetermined period TtB1. When the determination is negative, the determination in the step S3 is repeated. Thus after the step S2, the routine waits until the first predetermined period TtB1 elapses. When the determination is affirmative, the routine proceeds to a step S4. In a step S4, a correction increasing the engine output torque is performed by transmitting a command signal to the torque control mechanism 17 i.e. throttle valve 11 or fuel injector 12. The routine is terminated after the step S4. Therefore the first predetermined period TtB1 basically represents the time period (Tt1+Tt2) between the shift in the shift lever position from a stationary range position to a running range position and the completion of the actual shift to a running range (D or R) of the automatic transmission 2. The completion of the actual shift to a running range means the completion of engagement of the forward/reverse clutch.
When the controller 9 sets a target air fuel ratio, the engine output torque is determined on the basis of the intake air amount aspirated into the cylinders. The control of the intake air amount is performed by regulating the opening of the throttle valve 11 by the controller 9. The controller 9 sets the target air fuel ratio, (intake air amount)/(fuel injection amount), in response to the exhaust emission control requirements. The fuel injection amount is determined based on the intake air amount required to realize the target air fuel ratio and varies in response to the intake air amount. Thus the fuel injection amount increases when the intake air amount increases. In this manner, engine output torque increases from the first output torque Te0 (for example 20 Nm) to the second output torque Te1 by a correction gain ΔTe (for example 5 Nm).
Conversely when the target air fuel ratio is not set, the controller 9 can perform independent control of the fuel injector 12 and the throttle valve 11. The controller 9 transmits a command signal to at least one of the throttle valve 11 and the fuel injector 12 in order to increase the engine output torque.
Since the intake air amount is realized by the throttle valve 11, a time lag (transmission time lag) occurs due to the time taken for an amount of intake air to enter the cylinders. This time lag depends on the capacity of the air passage from the throttle valve to the cylinders. Consequently variation in the engine output torque occurs later than variation in the throttle valve opening. Thus the first predetermined period TtB1 used in the determination in the step S3 may take the transmission time lag of the intake air amount into account and may be set to a time corresponding to the transmission time lag being subtracted from the time period (Tt1+Tt2).
Referring to the timing chart in
After the time t3 in the first embodiment, the engine output torque is maintained at a second output torque Te1 which increases from a first output torque Te0 by the predetermined correction gain ΔTe. The second embodiment differs from the first embodiment in that the engine output returns to the first output torque Te0 from the time t7 to the time t8.
As shown in
The time period Tt3 is longer than the time period Tt4. The time period Tt4 (for example 0.1 seconds) is defined by the period from the time t3 at which the transmission 2 completely shifts to a running range to the time t6 at which the output torque of the transmission stabilizes if it is assumed that engine output torque is constant (in other words, if a correction gain is not applied as a result of a shift in the operating range of the transmission 2) (refer to FIGS. 4B and 4C).
In this manner, it is possible to ensure suppression of a torque differential that would be produced if engine output torque were constant. Furthermore it is possible to limit any increase in the fuel injection amount which increases the engine output torque to the minimum amount required for suppressing the torque differential.
Referring to the flowchart in
Since the control routine in the steps S1 to S4 in
In the step S5, it is determined whether or not the elapsed time after the time t3 is greater than the second predetermined period TtB2. In other words, it is determined whether or not the second predetermined period TtB2 has elapsed after the correction gain is applied to the engine output torque in the step S4. When the determination is negative, the determination in the step S5 is repeated. Therefore after the step S4, the routine waits until the second predetermined period TtB2 elapses. When the determination is positive, the routine proceeds to the step S6. In the step S6, a command signal is outputted to the torque control mechanism 17 in order to gradually reduce the engine output torque from the second output torque Te1. As a result, the engine output torque returns to the first output torque Te0. After the step S6, the routine is terminated. Herein the second predetermined period TtB2 basically represents the time period Tt3, however it may take into account the time lag of the transmission of the intake air from the throttle valve 11 to the cylinders and may be set to a period corresponding to the transmission time lag being subtracted from the time period Tt3. However the time period Tt3 is still longer than the time period Tt4.
Referring to the timing chart in
Firstly a prior-art example of control will be described as shown by the broken line in
In contrast, in the third embodiment, at the time t2, the output torque of the transmission 2 starts to increase. However the rate of increase is smaller than in the prior-art technique. The suppression of the rate of increase in the torque is due to providing an orifice in the oil supply line of the transmission 2. The provision of the orifice also suppresses the overshoot and shortfall of the output torque of the transmission 2.
The increase in torque continues until the time t3b. The engine output torque increases from Te0 to Te1 at the time t3b, is gradually reduced after the time t7b and coincides with Te0 at the time t8b.
The control routine of the third embodiment is the same as the control routine described in
The entire contents of Japanese Patent Application P2003-1376 (filed Jan. 7, 2003) are incorporated herein by reference.
Although the invention has been described above by reference to certain embodiments of the invention, the invention is not limited to the embodiments described above. Modifications and variations of the embodiment described above will occur to those skilled in the art, in light of the above teachings. The scope of the invention is defined with reference to the following claims.
Number | Date | Country | Kind |
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2003-001376 | Jan 2003 | JP | national |
Number | Name | Date | Kind |
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4730708 | Hamano et al. | Mar 1988 | A |
4898138 | Nishimura et al. | Feb 1990 | A |
5403246 | Umemoto | Apr 1995 | A |
5743826 | Usuki et al. | Apr 1998 | A |
5795262 | Robinson | Aug 1998 | A |
6634984 | Doering et al. | Oct 2003 | B1 |
6881170 | Onoyama et al. | Apr 2005 | B2 |
Number | Date | Country |
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61-105228 | May 1986 | JP |
Number | Date | Country | |
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20040192501 A1 | Sep 2004 | US |