WO2015033707A1 - 車両の制御装置 - Google Patents
車両の制御装置 Download PDFInfo
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- WO2015033707A1 WO2015033707A1 PCT/JP2014/070063 JP2014070063W WO2015033707A1 WO 2015033707 A1 WO2015033707 A1 WO 2015033707A1 JP 2014070063 W JP2014070063 W JP 2014070063W WO 2015033707 A1 WO2015033707 A1 WO 2015033707A1
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- Prior art keywords
- engine
- vehicle
- reacceleration
- scene
- accelerator
- Prior art date
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- B60W2540/12—Brake pedal position
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60W—CONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
- B60W2540/00—Input parameters relating to occupants
- B60W2540/30—Driving style
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60W—CONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
- B60W2552/00—Input parameters relating to infrastructure
- B60W2552/15—Road slope, i.e. the inclination of a road segment in the longitudinal direction
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60W—CONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
- B60W2552/00—Input parameters relating to infrastructure
- B60W2552/30—Road curve radius
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B60—VEHICLES IN GENERAL
- B60W—CONJOINT CONTROL OF VEHICLE SUB-UNITS OF DIFFERENT TYPE OR DIFFERENT FUNCTION; CONTROL SYSTEMS SPECIALLY ADAPTED FOR HYBRID VEHICLES; ROAD VEHICLE DRIVE CONTROL SYSTEMS FOR PURPOSES NOT RELATED TO THE CONTROL OF A PARTICULAR SUB-UNIT
- B60W2556/00—Input parameters relating to data
- B60W2556/10—Historical data
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02T—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
- Y02T10/00—Road transport of goods or passengers
- Y02T10/10—Internal combustion engine [ICE] based vehicles
- Y02T10/40—Engine management systems
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02T—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
- Y02T10/00—Road transport of goods or passengers
- Y02T10/60—Other road transportation technologies with climate change mitigation effect
- Y02T10/62—Hybrid vehicles
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02T—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
- Y02T10/00—Road transport of goods or passengers
- Y02T10/60—Other road transportation technologies with climate change mitigation effect
- Y02T10/64—Electric machine technologies in electromobility
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02T—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
- Y02T10/00—Road transport of goods or passengers
- Y02T10/60—Other road transportation technologies with climate change mitigation effect
- Y02T10/70—Energy storage systems for electromobility, e.g. batteries
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02T—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
- Y02T10/00—Road transport of goods or passengers
- Y02T10/60—Other road transportation technologies with climate change mitigation effect
- Y02T10/7072—Electromobility specific charging systems or methods for batteries, ultracapacitors, supercapacitors or double-layer capacitors
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02T—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
- Y02T10/00—Road transport of goods or passengers
- Y02T10/60—Other road transportation technologies with climate change mitigation effect
- Y02T10/72—Electric energy management in electromobility
Definitions
- the present invention relates to a vehicle control device capable of automatically starting and stopping an engine in response to a depression operation of an accelerator pedal.
- control device for a vehicle as described above, for example, the one described in Patent Document 1 is known.
- This control device includes an engine and a motor and travels only by a motor depending on a travel mode, or the engine and motor. It is used for a hybrid vehicle that can be switched by running.
- the above-described conventional device is a normal driving state where the driving state of the vehicle is within a normal range or a sports driving state where the driving state is outside the normal range based on the driving operation by the driver and the driving environment of the driving path.
- EV electric vehicle
- HEV hybrid vehicle
- the conventional vehicle control device has the following problems. That is, the conventional vehicle control apparatus estimates a reacceleration scene (scene) that requires subsequent reacceleration by detecting any one of a sudden accelerator-off, a sudden brake, and a curve with a predetermined curvature or more. The degree is determined on the basis of a driving tendency index obtained by weighting these values from the longitudinal acceleration / deceleration of the vehicle and the curvature of the travel path. The calculation of the sporting degree is disclosed in JP 2012-46148 A, JP 2012-8664 A, and the like in addition to the above-described conventional technology.
- the vehicle is driven in the HEV travel mode.
- the engine may be started other than a request from the vehicle side system (for example, a charge request when the battery charge rate decreases, a negative pressure supplement for a decrease in brake negative pressure, a compensation for a decrease in driving force by an air conditioner, etc.) is there. In this case, since the engine is started in an unexpected situation, there is a problem that the driver feels uncomfortable.
- FIG. 8 shows an example of a problem in the case where the sport level is determined based on the brake deceleration, which is one of the longitudinal acceleration / decelerations of the vehicle, in the conventional technology.
- (a) is the time variation of the accelerator opening
- (b) is the time variation of the brake deceleration
- (c) is the time variation of the longitudinal acceleration / deceleration of the vehicle
- (d) is the time variation of the vehicle speed.
- the change, (e) represents the temporal change of the sports degree
- (f) represents the temporal change of switching between the EV running mode and the HEV running mode.
- the driver is not able to decelerate the accelerator pedal from a straight-ahead state where the accelerator pedal is depressed greatly until the HEV driving mode is entered, but the longitudinal acceleration of the vehicle is not so high (therefore, the sporting degree is smaller than the sport determination threshold).
- the accelerator pedal is suddenly returned, a re-acceleration scene is predicted, and as shown in FIG. 8 (c), the absolute value of the deceleration in the front-rear direction is increased by the engine brake, as shown in FIG. 8 (d). Then, the vehicle speed begins to slow down. In this case, the degree of sport does not exceed the threshold with the magnitude of the deceleration.
- the vehicle travels in the HEV traveling mode when the accelerator opening is larger than the predetermined value even when the sporting degree is smaller than the sports determination threshold.
- the accelerator opening is suddenly returned to 0, this switches to the EV travel mode, and the engine that has been operating until then is stopped.
- the brake pedal is subsequently operated, the brake torque is actually applied to the vehicle, and the definite value of the deceleration of the vehicle is further increased, and when the sporting degree calculated based on this deceleration exceeds the sports determination threshold value.
- an instruction to switch from the EV travel mode to the HEV travel mode is issued, and the engine is started within a range where the operation is not originally required. It will be.
- the HEV travel mode is switched to the EV travel mode and the engine stops. .
- the dotted lines indicate the depression of the accelerator pedal (left mountain portion in the figure) and the brake pedal depression (right mountain portion in the figure), and the valley portion between both mountains. Indicates the part of the pedal to be switched. Since the sporting degree is determined based on the actual acceleration / deceleration in the front-rear direction, the degree of sport is slightly delayed from the depression and return of the pedal.
- FIG. 9 there is a case where unnecessary start / stop of the engine occurs although the vehicle can be climbed in the EV traveling mode.
- (a) represents the altitude of the road on which the vehicle travels
- (b) represents the estimated gradient of the road
- (c) represents the temporal change in switching between the EV travel mode and the HEV travel mode.
- the traveling road becomes a flat road after a road having an ascending slope
- the control device on the vehicle side for example, determines the accelerator opening and the vehicle longitudinal acceleration.
- the road gradient is estimated from the road information of the car navigation system or the inclination sensor, and the estimated value is compared with the gradient determination threshold value.
- This gradient estimation also causes a time lag from the actual gradient. Therefore, as shown in the figure, when the vehicle is traveling in the EV traveling mode, it is determined that the switching to the HEV traveling mode is necessary. Causes a time lag. Also in this case, switching from the EV driving mode to the HEV driving mode and then the EV driving mode may give the driver a sense of incongruity when the engine is started and stopped when unnecessary and not intended by the driver. become.
- the present invention has been made paying attention to the above problems, and the object of the present invention is in a vehicle capable of stopping and starting the engine in accordance with the opening degree of the accelerator pedal, the driver's request and the above system. It is an object of the present invention to provide a vehicle control apparatus that can prevent the driver from feeling uncomfortable when the engine is started other than the above request.
- the vehicle control apparatus includes an engine stop / start determination means for determining stop and start of the engine based on the magnitude of the accelerator opening, and an accelerator after the accelerator is turned off based on the accelerator opening.
- Re-acceleration scene prediction means for predicting a re-acceleration scene to be turned on, and when the re-acceleration scene prediction means predicts a re-acceleration scene of the engine, the engine stop / start determination means indicates that the engine is operating In this case, the engine is prohibited from being stopped, and when the engine is stopped, the engine control means starts the engine based on the accelerator on.
- the vehicle control device ⁇ of the present invention it is possible to prevent the engine from starting other than the driver's request or system request and giving the driver a sense of incongruity.
- 1 is a diagram schematically illustrating a control device for a hybrid vehicle and a power train thereof according to a first embodiment of the present invention.
- 1 is a functional block diagram illustrating a configuration of a control device for a hybrid vehicle according to a first embodiment. It is a flowchart which shows the switching control of EV mode and HEV mode which are performed with the control apparatus of the hybrid vehicle of Example 1, and are performed based on the prediction of a re-acceleration scene while an engine stops. It is a flowchart which shows the switching control of EV mode and HEV mode which are performed with the control apparatus of the hybrid vehicle of Example 1, and are performed based on the prediction of a re-acceleration scene while an engine stops.
- FIG. 5 is a flowchart used for predicting a reacceleration scene in the control according to the flowchart of FIG. 4. It is a figure which shows the structure of the example different from Example 1 of the power train carrying the vehicle control apparatus which concerns on this invention. It is a figure which shows the structure of another example of the power train carrying the vehicle control apparatus which concerns on this invention. It is a figure explaining the example of a malfunction which arises when performing sports run judgment based on brake deceleration in the prior art. It is a figure explaining the example of the malfunction which generate
- FIG. 1 schematically shows a control apparatus for a vehicle according to the first embodiment, a power train thereof, and the like.
- the hybrid vehicle includes an engine 1, a motor 2, a transmission 3, a first clutch (CL1) 4, a second clutch (CL2) 5, and left and right accelerator shafts 6a and 6b.
- Power trains such as left and right drive wheels 7a and 7b are provided.
- the hybrid vehicle further includes a battery 8, an inverter 9, a transmission controller 10, a motor controller 11, a battery controller 12, an engine controller 13, an integrated controller 14, a control area network (CAN) 15, and an accelerator. And an opening degree sensor 16.
- a battery 8 an inverter 9, a transmission controller 10, a motor controller 11, a battery controller 12, an engine controller 13, an integrated controller 14, a control area network (CAN) 15, and an accelerator.
- CAN control area network
- the engine 1 is an internal combustion engine that generates driving force by burning these with gasoline or the like as fuel.
- the motor 2 is supplied with electric power from the battery 8 through the inverter 9 to generate a driving force.
- the motor 2 functions as a generator during vehicle braking and can be regenerated by converting part of the brake energy into electric power. That is, the motor 2 functions as a motor / generator, and uses, for example, a three-phase AC motor.
- the transmission 3 includes a primary pulley, a secondary pulley arranged in parallel with the pulley, and a metal V-belt that is bridged between the pulleys and transmits power.
- This is a belt type continuously variable transmission that changes continuously by changing the groove width.
- the input shaft of the primary pulley is connected to the second clutch 5, and the output shaft of the secondary pulley is connected to a forward / reverse switching planetary gear set (not shown) and connected to the left and right accelerator shafts 5a and 5b via a differential gear set (not shown). Connecting.
- the transmission 3 may use a continuously variable transmission of a different type or a multi-stage automatic transmission instead of the belt-type transmission.
- the first clutch 4 is disposed between the engine 1 and the electric motor 2, and although not shown, the integrated controller 14 can connect and disconnect the engine 1 and the electric motor 2.
- the second clutch 5 is disposed between the electric motor 2 and the transmission 3 and can be connected to and disconnected from the electric motor 2 and the transmission 3 by an integrated controller 14 (not shown).
- the first clutch 4 and the second clutch 5 are, for example, hydraulically operated multi-plate clutches, and by controlling the clutch pressure, the transmission torque capacity thereof can be controlled continuously and variably.
- the accelerator shafts 5a and 5b connect the differential gear device of the transmission 3 and the drive wheels 7a and 7b respectively with joints (not shown).
- the battery 8 is a secondary battery that can be repeatedly charged and discharged, and for example, a lithium ion battery is used.
- the inverter 9 converts the direct current of the battery 9 into a three-phase alternating current of a required magnitude and supplies it to the motor 2 in accordance with a control signal from the motor controller 11. On the contrary, at the time of regeneration, the three-phase alternating current generated by the motor 2 is converted into direct current and the battery 8 is charged.
- the transmission controller 10 controls the hydraulic pressure supplied to the pulley so as to obtain an optimum gear ratio in accordance with a traveling state such as a vehicle speed, an accelerator pedal opening degree, and an operating state such as an input shaft rotational speed.
- the motor controller 11 sends a drive control signal, a regenerative control signal, and the like to the inverter 9 to control it.
- the battery controller 12 manages the temperature of each cell constituting the battery 8, and estimates the state of the battery 8, for example, a charging rate State of Charge (SoC) and a battery output limit value capable of maximum output.
- SoC State of Charge
- the engine controller 13 performs ignition control of the engine 1 and control of the supplied fuel amount, and performs control such as engine stop, start, and optimum operation (state where the engine speed is other than 0).
- the engine controller 13 corresponds to the engine control means of the present invention.
- the integrated controller 14 is connected to the transmission controller 10, the motor controller 11, the battery controller 12, and the engine controller 13 by CAN 15, and exchanges signals with these to coordinate the control performed by these controllers 10-13. They are controlled so that optimal control is performed as a whole.
- the integrated controller 14 is connected to an accelerator opening sensor 16 that detects an accelerator opening corresponding to the amount of operation of the accelerator pedal. So that you can get more information.
- FIG. 2 shows a functional block diagram showing a part of the integrated controller 14 necessary for the present invention.
- the integrated controller 14 includes a target driving force calculation unit 20, a request output calculation unit 21, a motor output target value generation unit 22, a motor output limit value calculation unit 23, an output target value determination unit 24, and a target operation mode determination.
- Unit 25 a reacceleration performance improvement control unit 26, a driving force correction unit 27, and a target operating point determination unit 28.
- the target driving force calculation unit 20 receives the accelerator opening signal detected by the accelerator opening sensor 16 and refers to the target driving force map storing the relationship between the accelerator opening and the target driving force, and inputs the accelerator opening signal.
- the target driving force signal corresponding to the degree signal is output to the request output calculation unit 21.
- the required output calculation unit 21 is a target drive force signal input from the target drive force calculation unit 20, a drive force correction signal input from the drive force correction unit 27, a request output signal from an auxiliary device such as an air conditioner, not shown. Based on the vehicle speed signal input from the vehicle speed sensor, all outputs required for the vehicle are calculated, and output to the target operating point determination unit 26 and the target operation mode determination unit 25 as all output signals.
- the motor output target value generation unit 22 corresponds to the detected charging rate by referring to the motor output target map that stores the relationship between the charging rate and the motor output target value based on the charging rate signal input from the battery controller 12.
- the motor output target value is determined and output to the output target value determination unit 24 as a motor output target value signal.
- the motor output limit value calculation unit 23 calculates a motor output limit value based on the battery output limit value signal input from the battery controller 12 and the motor output limit value signal input from the motor controller 11, and the motor output limit value The signal is output to the output target value determination unit 24 as a signal.
- the motor output limit value calculation unit 23 sets the motor output upper limit value and the motor output lower limit value as the motor output limit value.
- the battery output possible upper limit value is compared with the motor output upper limit value, whichever is smaller.
- the battery output possible lower limit value is compared with the motor output lower limit value, and the larger value is selected to prevent the battery 8 from being overcharged or overdischarged.
- the output target value determination unit 24 performs upper limit processing and lower limit processing on the motor output target value input from the motor output target generation unit 22 with the motor output limit value input from the motor output limit value calculation unit 23.
- the output target value signal of the motor 2 is output to the target operating point determination unit 28 and the target operation mode determination unit 25.
- the target operation mode determination unit 25 includes a charge rate signal input from the battery controller 12, a HEV mode request flag signal input from the reacceleration performance improvement control unit 26, a total output signal input from the request output calculation unit 21, and an output. Based on the output target value signal input from the target value determining unit 24, referring to the target operation mode map that stores the relationship between these values and the target operation mode, either the EV driving mode or the HEV driving mode is selected. Is output to the target operating point determination unit 26 and the reacceleration performance improvement control unit 26 as target mode signals.
- an operation mode (EV travel mode or HEV) corresponding to the accelerator opening corresponding to the driver's required load and the vehicle speed proportional to the output rotation speed of the transmission 3 is selected.
- the driving mode is determined using the driving mode map.
- the HEV travel mode request flag is input from the reacceleration performance improvement control unit 26, the EV travel mode is prohibited and the HEV travel mode is selected.
- the target operation mode determination unit 25 corresponds to engine stop / start determination means of the present invention.
- the reacceleration performance improvement control unit 26 receives a target mode signal from the target operation mode determination unit 25, an accelerator opening signal from the accelerator opening sensor, a brake operation signal from a brake pedal operation sensor (not shown), and a wheel speed from a wheel sensor (not shown).
- Curve signal calculated based on the above, acceleration / deceleration in the vehicle longitudinal direction are input from an acceleration sensor (not shown), and the degree of sports is calculated based on the vehicle longitudinal acceleration / deceleration, the curvature of the road, etc.
- the target driving mode is determined by determining whether or not the vehicle is driving in sport by comparing with the determination threshold and predicting the presence or absence of a re-acceleration scene that needs to be re-accelerated by detecting sudden acceleration off, sudden braking, curve detection, etc.
- T / M lower limit transmission
- the details of the control executed by the reacceleration performance improvement control unit 26 will be described later.
- the reacceleration performance improvement control unit 26 corresponds to a reacceleration scene prediction unit of the present invention.
- the driving force correction unit 27 receives the lower limit transmission input restriction rotation number signal from the reacceleration performance improvement control unit 26, and the input rotation number of the transmission 3 is the lower limit value during driving such as sudden accelerator off, sudden braking, and curve driving.
- a driving force correction signal for obtaining a driving force necessary to prevent the value from falling below is output to the request output calculation unit 21.
- the lower limit transmission input restriction rotational speed is the vehicle speed and the driving force correction for this rotational speed restriction is performed in both the EV traveling mode and the HEV traveling mode.
- the target operating point determination unit 28 is a total output signal input from the request output calculation unit 21, an output target value signal input from the output target value determination unit 24, a target mode signal input from the target operation mode determination unit 25, Based on the acceleration / deceleration transmission input regulation rotation speed signal input from the reacceleration performance improvement control unit 27, a target operating point map storing the relationship between these values and the control contents of the engine 1, the motor 2 and the transmission 3 is stored. Referring to each of the engine 1, the motor 2, and the transmission 3, target operation points are determined, and target operation point signals corresponding to these are output to the engine controller 13, the motor controller 11, and the transmission controller 10, respectively.
- the target operating point determination unit 28 uses the accelerator opening, full output (target driving torque of the engine 1 and target torque of the motor 2), operation mode, and vehicle speed as the target of reaching the operating point, and a transient target engine torque signal.
- Target motor torque signal or target generator torque signal
- target transmission input rotational speed signal target first clutch transmission torque capacity signal
- target second clutch transmission torque capacity signal engine 1, motor 2, transmission 3.
- FIG. 3 shows a flowchart in the case where it is determined whether or not it is a reacceleration scene in which reacceleration performance needs to be improved according to a medium to long-term driving environment / driving tendency and control is performed.
- the medium- to long-term driving environment is either the presence or absence of an uphill road with a climbing slope
- the medium- to long-term driving tendency is either the presence or absence of an operation in a re-acceleration scene where the accelerator is turned on after the accelerator is turned off. If this condition is satisfied, it is predicted to be a re-accelerated scene.
- step S1 the reacceleration performance improvement control unit 26 determines whether or not it is predicted that the scene needs improvement of the reacceleration performance due to the medium to long-term driving environment / driving tendency. That is, it is determined whether or not a predetermined or higher climb gradient that predicts a reacceleration scene or the accelerator operation that predicts a reacceleration scene is detected. If the determination result is YES, the process proceeds to step S3, and if NO, the process proceeds to step S2.
- step S1 the slope of the road traveling uphill is detected as follows. That is, power transmission friction, running resistance, and acceleration resistance are calculated, and the road gradient is calculated by filtering the gradient by subtracting the running resistance and acceleration resistance during flat road running from the driving force.
- the filtering process here, it is possible to prevent fluctuations in the operation value and satisfy the responsiveness requirement.
- By comparing the gradient degree thus calculated with a threshold value it is determined whether or not the scene needs to be improved in reacceleration performance.
- step S2 the degree of gradient is below the threshold value, and the accelerator operation that predicts the above reacceleration speed scene is not detected. As a result, it is determined in step S1 that the reacceleration performance is not improved.
- the improvement control unit 26 does not request the HEV traveling mode. That is, the HEV travel mode request flag signal is not output. Subsequently, the process returns to step S1.
- step S3 at least one of the climbing slope and the accelerator operation is detected, and it is determined in step S1 that the scene needs to be improved again. It is determined whether or not the output target mode signal is the HEV mode. If this determination is YES, the process proceeds to step S4, and if NO, the process proceeds to step S2.
- step S4 since the vehicle is currently traveling in the HEV travel mode, an HEV travel mode request flag signal is output to request the HEV travel mode, and the target operation mode determination unit 25 outputs the HEV travel mode as the target mode. To. Then, it returns to step S1.
- the reacceleration performance improvement control unit 26 starts the engine 1 when the reacceleration scene is predicted while the engine 1 is stopped (that is, during traveling in the EV traveling mode). No request was made (that is, the HEV running mode was not set). Therefore, the engine is started only in the case of a driver request or a system request, and in other cases, it is possible to prevent the engine from starting and giving the driver a sense of incongruity. Also, once the engine 1 is stopped, the engine 1 will not start unless there is a driver request or system request even if the accelerating scene is predicted to cause hunting between the stop and start of the engine 1. There is no sense of incongruity.
- the reacceleration performance improvement control unit 26 outputs a HEV traveling mode request flag to the target operation mode determining unit 25.
- the minimum transmission speed is obtained from the map, the driving force is changed (regardless of whether the engine 1 is stopped or operating), and HEV This is reflected in the target rotational speed in the traveling mode (change of the rotational speed is performed only while the engine is running).
- the vehicle When traveling on an uphill, the vehicle is more heavily loaded than when traveling on a flat road, so the required driving force must be increased to maintain or accelerate the vehicle. Therefore, in many cases, the vehicle travels while the engine 1 is running during the climbing gradient traveling, and in this case, the engine 1 can be prohibited from being stopped by predicting the reacceleration scene. On the other hand, when the vehicle is traveling on an uphill slope in the EV traveling mode in which the engine is stopped, the vehicle is often decelerated. Thereafter, since the acceleration operation is not always performed, starting the engine 1 other than the driver request or the system request has a great disadvantage for the driver.
- the acceleration can be maintained once the engine 1 is moved by depressing the accelerator pedal. Therefore, the reacceleration performance is improved.
- the engine 1 can be started at a lower accelerator opening than usual due to an accelerator request. Become.
- a composite acceleration is calculated from the longitudinal acceleration and lateral acceleration of the vehicle (acceleration detection by an acceleration sensor or calculation from a vehicle speed from a vehicle speed sensor) and divided by a reference value. Thus, it may be obtained by indexing, or may be obtained by performing integration processing (including filtering processing and average processing) on the resultant acceleration.
- the value to be integrated may be a jerk (jerk acceleration), or may be an accelerator opening, a brake operation amount, or a steering angle related to vehicle acceleration.
- the reacceleration performance improvement control unit 26 When it is necessary to improve the reacceleration response and the vehicle is traveling in the HEV travel mode, the reacceleration performance improvement control unit 26 outputs a HEV travel mode request flag to the target operation mode determination unit 25. Further, the minimum transmission speed is obtained from the map using the sport level and the vehicle speed, and is reflected in the target rotational speed in the driving force change and HEV travel modes as described above.
- an acceleration applied to the vehicle including at least the vehicle longitudinal acceleration is integrated (including filtering processing and average processing), and a scene that requires the reacceleration scene is compared with a threshold value. You may make it detect.
- the acceleration is mainly generated when the accelerator is on, the deceleration is generated mainly during the brake operation, and the lateral acceleration is generated mainly during the steering operation.
- the estimated value of the sport level is greater than or equal to a threshold value due to acceleration, the sport is often driven mainly by an accelerator operation. In this case, since there are many runs while operating the engine 1, in that case, it is possible to prohibit the engine 1 from being stopped by re-acceleration scene prediction.
- FIG. 4 shows a flowchart of control when there is a short-term operation.
- the reacceleration performance improving unit 26 performs a sudden acceleration based on an accelerator opening signal input from the accelerator opening sensor 16 and a brake operation amount signal input from a brake pedal operation sensor (not shown). It is determined whether or not there is a short-term operation such as an off operation or a sudden brake operation. If the determination result is YES, the process proceeds to step S13, and if the determination result is NO, the process proceeds to step S12.
- step S12 the activation of the reacceleration response improvement control by a short-term operation is not permitted, that is, the engine 1 is not started when the engine 1 is stopped. Subsequently, the process returns to step S11.
- step S13 the reacceleration performance improving unit 26 determines whether or not the target mode output from the target operation mode determining unit 25 is the current HEV travel mode. If the determination result is YES, the process proceeds to step S14, and if NO, the process proceeds to step S12.
- step S14 it is determined whether or not there is permission for re-acceleration control due to the above-mentioned medium- to long-term driving tendency. If the determination result is YES, the process proceeds to step S15, and if NO, the process proceeds to step S12.
- step S15 re-acceleration improvement control by short-term operation is permitted to operate. That is, the reacceleration performance improving unit 26 outputs a HEV travel mode request flag signal to the target operation mode determination unit 25 to request the HEV travel mode. Further, the minimum speed of transmission is obtained from the map using the sport level and the vehicle speed, and is reflected in the change in driving force and the target speed in the HEV travel mode. Subsequently, the process returns to step S11.
- one of the control conditions is that the engine 1 is in operation. For this reason, the engine 1 can be started without being requested by the driver or the system. Even if this condition exists, there is no problem when the reacceleration scene is predicted because the engine 1 is almost in operation.
- the control since the control is activated on condition that the engine 1 is in operation, even if the engine 1 moves due to a system request after sudden accelerator off or sudden brake operation, reacceleration by sudden accelerator off or sudden brake operation is required. The improving control does not operate, and the driver does not feel uncomfortable.
- the reacceleration improvement control unit 26 determines that the scene is not a reacceleration improvement scene after the operation of the control to improve the reacceleration performance by detecting the reacceleration scene by sudden accelerator off or sudden braking operation, It is possible to improve the reacceleration performance by determining the reacceleration scene due to the accelerator off or the sudden brake operation and prohibiting the engine stop by the reacceleration control.
- step S11 the reacceleration performance improving unit 26 determines whether or not the scene requires improvement of the reacceleration performance based on the current information.
- the current information includes, for example, sudden accelerator off and sudden braking operation. If the determination result is YES, the process proceeds to step S23, and if the determination result is NO, the process proceeds to step S22.
- step S22 operation of reacceleration improvement control based on current information is not permitted. Subsequently, the process returns to step S21.
- step S23 curve determination is performed.
- the curve is detected as follows. That is, the reacceleration performance improving unit 26, for example, four-wheel wheel speed input from a wheel speed sensor (not shown), steering angle input from a steering angle sensor (not shown), vehicle lateral acceleration input from an acceleration sensor (not shown), A curve is detected based on a vehicle speed input from a vehicle speed sensor (not shown). The curve is detected by detecting whether the curve is based on the vehicle speed input from the yaw rate input from a yaw rate sensor (not shown), the longitudinal acceleration input from a longitudinal acceleration sensor (not shown), or the like. It may be a method. As a result of the calculation, if there is a curve determination, the process proceeds to step S24, and if not, the process proceeds to step S22.
- step S24 it is determined whether or not the current target mode is the HEV travel mode. If the determination result is YES, the process proceeds to step S25, and if NO, the process proceeds to step S22.
- step S25 it is determined whether a reacceleration scene due to a medium- to long-term driving tendency is predicted and the operation of the reacceleration control is permitted. If this determination result is YES, the process proceeds to a step S26, and if NO, the process proceeds to a step S22.
- step S26 the operation of the reacceleration response improvement control based on the current information is permitted.
- the minimum transmission speed is calculated from the lateral acceleration or steering angle and the vehicle speed using a map. Subsequently, the process returns to step S21.
- control is performed to improve the reacceleration response by detecting the curve, but since this control does not want to be activated by the operation at the time of driving, when the reacceleration scene is predicted in step S25 It is supposed to work.
- the engine start condition is added to the above control start condition (step S24)
- the engine 1 is prohibited from starting, It prevents the engine 1 from starting other than system requirements and does not give a sense of incongruity.
- the engine is stopped in the above-described control start condition, there is no problem because the engine 1 is almost in operation when the reacceleration scene is predicted.
- the control for improving the reacceleration response by the curve detection does not operate.
- the above-described control based on the curve detection is prevented during the curve traveling, the driver does not feel uncomfortable.
- the control that detects the curve and improves the reacceleration response is activated, even if the reacceleration performance control unit 26 determines that it is not the reacceleration improvement scene, the control that improves the reacceleration response by detecting the curve Since the stop of the engine 1 is prohibited, the reacceleration response can be improved.
- the determination result of switching between the EV traveling mode and the HEV traveling mode may vary due to the variation of the estimated value of the sport degree, and the engine starts due to this.
- the estimated value of sporting level (represented by practice) varies as shown in FIG. 10, it increases or decreases with respect to the travel mode switching threshold (represented by a dotted line), and between EV travel mode and HEV travel mode. Hunting occurs, and the engine hunts between starting and stopping. In this case as well, the driver feels uncomfortable and uncomfortable.
- the engine start determination is not performed unless there is a driver request or a system request. Even if the acceleration performance improvement control unit 26 predicts the re-acceleration scene, the occurrence of hunting between the start and stop of the engine 1 can be suppressed.
- the vehicle control apparatus can obtain the following effects. That is, when the engine reacceleration scene is predicted, the engine 1 is prohibited from being stopped when the engine 1 is operating, and when the engine 1 is stopped, the engine 1 is turned on based on the accelerator opening. Therefore, it is possible to suppress a sense of discomfort to the driver due to the engine 1 being started other than the driver request or the system request.
- the reacceleration performance improvement control unit 26 calculates a value related to the driving situation by integrating the acceleration / deceleration acting on the vehicle including at least the longitudinal acceleration / deceleration of the vehicle or a physical quantity related thereto, and calculates the value related to the driving situation and the threshold value. Because the re-acceleration scene is predicted by comparing with, when the acceleration exceeds the threshold value, the accelerator is mainly on, and the engine is often operating if running sports, In that case, the required driving force can be ensured by prohibiting the stop of the engine 1 by predicting the reacceleration scene. Also, if the deceleration or lateral acceleration exceeds the threshold, the engine 1 will not start other than the driver request or system request if the engine 1 is started, so the driver will not feel uncomfortable Can be.
- the reacceleration performance improvement control unit 26 detects at least a road gradient, calculates a value related to the driving environment by integrating the gradient, and compares the value related to the driving environment with a threshold value to determine the reacceleration scene. Because it is predicted, when the vehicle speed is maintained or accelerated on the uphill road, the required driving force is large and the engine is often running. The necessary driving force can be secured. On the other hand, when driving on an uphill in the engine stop mode, the vehicle is often decelerating, so the engine 1 is prohibited from starting other than the driver request or system request, and the driver feels uncomfortable. Can not be given.
- the reacceleration performance improvement control unit 26 detects an operation of sudden braking or sudden acceleration off, predicts a reacceleration scene, and detects that the engine 1 is operating, it prohibits the engine from being stopped. Therefore, when a sudden brake operation or sudden accelerator-off detection is detected and a re-acceleration scene is predicted, the engine 1 is not stopped, so that a necessary driving force can be ensured. In addition, it is possible to prevent the engine 1 from starting other than a driver request or a system request, and to prevent the driver from feeling uncomfortable.
- the control to improve the re-acceleration response due to the sudden operation will not operate, thus preventing the driver from feeling uncomfortable. Can do.
- the re-acceleration scene is determined and restarted by the sudden operation.
- the control for improving the acceleration response can prohibit the stop of the engine 1 and improve the reacceleration response.
- the reacceleration performance improvement control unit 26 detects a curve, predicts a reacceleration scene, and detects that the engine 1 is operating, the engine 1 is prohibited from being stopped. It is possible to prevent the engine 1 from starting other than the system request or in the middle of the curve, so that the driver does not feel uncomfortable. Further, even if the engine 1 is operated due to a system request after the curve is detected, it is possible to prevent the control for improving the reacceleration response by the curve detection from being activated.
- the engine 1 is prohibited from being stopped by the control that improves the re-acceleration response by detecting the curve. Therefore, the reacceleration response can be improved.
- the engine 1 will not start except for the driver request or system request, so the engine 1 will be hunted between start and stop. It can prevent the driver from feeling uncomfortable.
- the vehicle control apparatus has been described based on the embodiment configured as described above.
- the present invention is not limited to the above-described embodiment. Design changes and modifications are included in the present invention.
- the vehicle control device of the present invention can be applied to a vehicle having the power train shown in FIGS. 6 and 7 instead of the power train of the first embodiment, and also in this case.
- FIG. 6 shows a clutch that is not a hybrid vehicle, has no motor, is driven only by the engine 1, and is arranged between the torque converter 17 connected to the engine 1 and the transmission 4 according to the accelerator opening.
- the vehicle has a so-called coast stop sailing function that controls connection / release of 18 (opens when the accelerator opening is 0).
- FIG. 6 shows a clutch that is not a hybrid vehicle, has no motor, is driven only by the engine 1, and is arranged between the torque converter 17 connected to the engine 1 and the transmission 4 according to the accelerator opening.
- the vehicle has a so-called coast stop sailing function that controls connection / release of 18 (opens when the accelerator opening is 0).
- the generator 19 is connected to the engine 1 and the electric power generated by the operation of the engine 1 is converted into a direct current by the inverter 8a to charge the battery 9, while the battery 9 is transferred to the motor (motor / generator) 2.
- Is supplied to the vehicle by converting it into a three-phase alternating current by the inverter 8b. Needless to say, it may be a plug-in hybrid vehicle.
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Abstract
Description
上記従来装置は、運転者による運転操作と走行路の走行環境に基づいて、車両の走行状態が通常の範囲内にある通常走行状態であるか、あるいは通常の範囲外にあるスポーツ走行状態であるかをといったスポーツ度を判定し、この判定結果がスポーツ走行状態である場合には、モータのみで車両を駆動する電気自動車(EV)走行モード領域とモータおよびエンジンで車両を駆動するハイブリッド車両(HEV)走行モード領域との境界を、通常走行状態に係る原位置から電気走行モード領域側に変更して、ハイブリッド走行モード領域を拡大するようにしている。
すなわち、上記従来の車両の制御装置では、急アクセルオフ、急ブレーキ、所定曲率以上のカーブのいずれかの検知により続いて再加速が必要となる再加速シーン(場面)を推定するとともに、上記スポーツ度の判定を車両の前後方向加減速度および走行路の曲率からこれらを重み付け演算した運転傾向指数に基づいて行っている。このスポーツ度の演算としては、上記従来技術の他に、特開2012-46148号公報、特開2012-8664号公報などに開示されている。
このため、EV走行モードでの走行中に、運転状態・走行状態によりスポーツ度の推定値が変動し、かつ再加速シーンが想定されてHEV走行モードへの移行がなされると、運転者の要求、あるいは車両側システムの要求(たとえば、電池の充電率低下時の充電要求、ブレーキ負圧の低下に対する負圧の補充、エアコンディショナによる駆動力低下に対する補償など)以外でエンジンが始動することがある。この場合、想定外の状況でエンジンが始動されることになるので、運転者に対して違和感を与えてしまうといった問題がある。
図8は、上記従来技術において、車両の前後方向加減速度の一つであるブレーキ減速度に基づいてスポーツ度を判定した場合の不具合例を示す。
同図において、(a)はアクセル開度の時間的変化、(b)はブレーキ減速度の時間的変化、(c)は車両の前後加減速度の時間的変化、(d)は車速の時間的変化、(e)はスポーツ度の時間的変化、(f)はEV走行モードとHEV走行モードとの切り替えの時間的変化をそれぞれ表す。
アクセルペダルを急激に戻すと、再加速シーンが予測され、また図8(c)に示すように、エンジンブレーキにより前後方向の減速度の絶対値が大きくなって、図8(d)に示すように、車速が減速し始める。この場合、その減速度の大きさでは、スポーツ度が閾値以上となることはない。
ブレーキが効き始めると、エンジンブレーキに加え車輪側ブレーキユニットによるブレーキトルク付与により、前後方向の減速度はさらにその絶対値が増加してスポーツ度がスポーツ判定閾値以上となる。ただし、この時点は、上述のように、ブレーキペダル操作より遅れることとなる。
このブレーキ作動により、車速もさらに急に減少し、車速が0になったら、運転者はブレーキペダルへの踏力を緩めて車両を停止状態に維持する。
しかしながら、続いてブレーキペダルが操作され、実際にブレーキトルクが車両に作用して車両の減速度の絶定値がさらに大きくなり、この減速度に基づき演算したスポーツ度がスポーツ判定閾値以上となると、上述のように再加速シーンが予測されていることから、図8(f)に示すように、EV走行モードからHEV走行モードへ切り替える指示が出され、本来稼働が不要な範囲でエンジンが始動されることになる。
このように、システム要求がなく、また運転者が意図しないときに、エンジンの始動・停止が行われると、運転者に違和感を与えることになる。
なお、図8において、点線はアクセルペダルの踏み込み(同図中、左の山部分)と、ブレーキペダルの踏み込み(同図中、右の山部分)を示し、両方の山の間の谷の部分はペダルの踏み換え部分を表している。スポーツ度は実際の前後方向の加減速度に基づいて決定されるので、上記ペダルの踏み込みや戻しからは若干遅れることになる。
図9において、(a)は車両が走行する道路の高度、(b)は道路の推定した勾配、(c)はEV走行モードとHEV走行モードとの切り替えの時間的変化をそれぞれ表す。
この例では、図9(a)に示すように、走行道路が登り勾配を有する道路の後、平坦路となる場合であって、車両側の制御装置では、たとえばアクセル開度および車両前後方向加速度、あるいはカーナビゲーションシステムの道路情報、あるいは傾斜センサなどから、図9(b)に示すように、道路の勾配を推定し、この推定値と勾配判定閾値と比較する。
なお、この勾配の推定も実際の勾配から時間のずれが生じる。したがって、同図に示されるように、EV走行モードで走行している場合に、HEV走行モードへの切り替えが必要と判定されるのは、実際の勾配が始まり終わる時点はとそれらの推定時間とは、時間のずれが生じる。この場合も、EV走行モードからHEV走行モード、次いでEV走行モードと切り替わることにより、不必要で、かつ運転者が意図しないときに、エンジンの始動・停止が行われると運転者に違和感を与えることになる。
2 モータ
3 変速機
4 第1クラッチ
5 第2クラッチ
6a、6b アクセルシャフト
7a、7b 駆動輪
8 バッテリ
9、9a、9b インバータ
10 変速機コントローラ
11 モータコントローラ
12 バッテリコントローラ
13 エンジンコントローラ(エンジン制御手段)
14 統合コントローラ
15 コントローラエリアネットワーク
16 アクセル開度センサ
17 トルクコンバータ
18 クラッチ
19 ジェネレータ
20 目標駆動力演算部
21 要求出力演算部
22 モータ出力目標生成部
23 モータ出力制限値算出部
24 出力目標値決定部
25 目標運転モード決定部(エンジン停止・始動判定手段)
26 再加速性能向上制御部(再加速シーン予測手段)
27 駆動力補正部
28 目標動作点決定部
図1に、その実施例1の車両の制御装置およびそのパワートレーンなどを模式的に示す。
同図に示すように、ハイブリッド車両は、エンジン1と、モータ2と、変速機3と、第1クラッチ(CL1)4と、第2クラッチ(CL2)5と、左右のアクセルシャフト6a,6bと、左右の駆動輪7a、7bと、などのパワートレーンを備えている。
エンジン1は、ガソリンなどを燃料としてこれらを燃焼して駆動力を作り出す内燃機関である。
モータ2は、インバータ9を介してこの制御のもとにバッテリ8から電力の供給を受けて駆動力を作り出す。また、車両ブレーキ中にジェネレータとして機能してブレーキエネルギーの一部を電力に変えて回生可能である。すなわち、モータ2は、モータ/ジェネレータとして機能し、たとえば三相交流モータを用いる。
プライマリプーリの入力軸は第2クラッチ5に接続し、セカンダリプーリの出力軸は、図示しない前後進切り替え遊星歯車組に接続し、図示しない差動歯車組を介して左右のアクセルシャフト5a、5bに接続する。
なお、変速機3は、上記ベルト式変速機に代えて、これとは異なるタイプの無段変速機、あるいは多段の自動変速機などを用いるようにしてもよい。
第2クラッチ5は、電気モータ2と変速機3との間に配置されて、図示しないが統合コントローラ14により電気モータ2と変速機3との間を接続、切り離しすることが可能である。
ここで、第1クラッチ4および第2クラッチ5には、たとえば油圧作動の多板式クラッチを用い、クラッチ圧を制御することでそれの伝達トルク容量を連続的可変に制御することができるようにしている。
アクセルシャフト5a、5bは、変速機3の差動歯車装置と駆動輪7a、7bとをそれぞれ図示しないジョイントで接続する。
インバータ9は、モータコントローラ11からの制御信号に応じて、バッテリ9の直流電流を必要な大きさの三相交流電流に変換してモータ2に供給する。また、これとは逆に回生時には、モータ2で発電した三相交流電流を直流電流に変換してバッテリ8に充電したりする。
モータコントローラ11は、駆動制御信号や回生制御信号などをインバータ9へ送り、これを制御する。
エンジンコントローラ13は、エンジン1の点火制御や供給燃料量の制御などを行い、エンジンの停止、始動また最適な稼働(エンジン回転数が0以外の状態)といった制御を行う。なお、エンジンコントローラ13は、本発明のエンジン制御手段に相当する。
なお、統合コントローラ14には、アクセルペダルの操作量に対応するアクセル開度を検出するアクセル開度センサ16が接続されているが、これらの他にも図示しないが種々のセンサが接続されて必要な情報を得ることができるようにしてある。
統合コントローラ14は、目標駆動力演算部20と、要求出力演算部21と、モータ出力目標値生成部22と、モータ出力制限値算出部23と、出力目標値決定部24と、目標運転モード決定部25と、再加速性能向上制御部26と、駆動力補正部27と、目標動作点決定部28と、を備えている。
目標駆動力演算部20は、アクセル開度センサ16で検出したアクセル開度信号が入力されて、アクセル開度~目標駆動力の関係を記憶した目標駆動力マップを参照し、入力されたアクセル開度信号に対応する目標駆動力信号を要求出力演算部21へ出力する。
ここで、モータ出力制限値算出部23は、モータ出力制限値としてモータ出力上限値およびモータ出力下限値を設定し、前者としてはバッテリ出力可能上限値とモータ出力上限値とを比較して小さい方の値を選択し、後者としてはバッテリ出力可能下限値とモータ出力下限値とを比較して大きい方の値を選択して、バッテリ8が過充電、過放電にならないようにする。
なお、再加速性能向上制御部26で実行する制御の内容については、後で説明する。また、再加速性能向上制御部26は、本発明の再加速シーン予測手段に相当する。
なお、下限変速機入力規制回転数は、車速とこの回転数規制の駆動力補正は、EV走行モード、HEV走行モードのいずれにおいても実行する。
ここでは、ハイブリッド車両のパワートレーンの制御はよく知られているので、本発明に関係する作用だけに絞って説明する。
ここでの再加速シーンの予測は、中長期的な走行環境・運転傾向によって、また短期的な運転操作によって、それぞれ演算する。以下、それぞれの場合について順次説明する。
図3において、ステップS1で、再加速性能向上制御部26が、中長期的な走行環境・運転傾向によって再加速性能の向上が必要なシーンであることを予測したか否かを判定する。すなわち、再加速シーンを予測させる所定以上の登り勾配の検知、あるいは再加速シーンを予測させる上記アクセル操作を検知したか否かを判定する。この判定結果が、YESの場合にはステップS3に、またNOの場合にはステップS2へ進む。
すなわち、動力伝達摩擦、走行抵抗、加速度抵抗を算出し、駆動力から平坦路走行時の走行抵抗よび加速抵抗を減算することで勾配をフィルタリング処理することにより道路勾配を算出する。ここでフィルタリング処理を行うことで演算値のふらつきを防止し、応答性の要求を満たすことができる。なお、勾配角センサを用いるときは、この検出値をフィルタリング処理するようにしてもよい。
このようにして算出した勾配度を閾値と比較することで再加速性能の向上が必要なシーンであるか否かを判定する。
また、一度エンジン1を停止すれば、たとえ再加速シーンの予測がエンジン1の停止~始動間でハンチングを起こしても、エンジン1は運転者要求やシステム要求がない限り始動しないので、運転者に違和感を与えることがない。
一方、エンジン停止であるEV走行モードで登坂勾配を走行しているときは、車両が減速している場合が多い。その後、加速操作をするとは限らないので、運転者要求やシステム要求以外でエンジン1を始動することは運転者にとって違和感のデメリットが大きい。しかしながら、登り勾配で加速あるいは車速維持を行おうとすれば、いずれアクセルペダルを踏み込むことで、一度エンジン1が可動すればその可動を維持できるので、再加速性能が向上する。
また、勾配度に応じて目標駆動力の変更を行い、エンジン1の停止中に勾配度を演算することにより、アクセル要求によるエンジン1の始動を、通常より低アクセル開度で行うことが可能となる。
なお、スポーツ度としては、たとえば車両の前後方向の加速度および横方向の加速度(加速度センサによる加速度検出、あるいは車速センサからの車速からの演算など)から合成加速度を算出し、これを基準値で割ることで指数化して得たり、あるいは、合成加速度を積算処理(フィルタリング処理や平均処理を含む)したりすることで得るようにしてもよい。これらの値と閾値とを比較することにより再加速レスポンスの向上が必要なシーンを検出する。
上記積算処理をする値は、躍度(加加速度)を用いるようにしてもよいし、車両の加速度に関係するアクセル開度、ブレーキ操作量、操舵角でもよい。
ここで、加減速度にあっては、加速度は主にアクセルオンのとき、減速度は主にブレーキ操作のとき、横加速度は主にハンドル操作のときに発生する。
加速度によりスポーツ度の推定値が閾値以上となった場合には主にアクセル操作による場合でスポーツ走行していることが多い。この場合、エンジン1を稼働しながらの走行が多いので、その場合、再加速シーンの予測によりエンジン1を停止するのを禁止することができる。
図4において、ステップS11で、再加速性能向上部26がアクセル開度センサ16から入力されたアクセル開度信号、また図示しないブレーキペダル操作センサから入力されたブレーキ操作量信号に基づいて、急アクセルオフ操作や急ブレーキ操作などの短期的な操作があったか否かを判定する。
この判定結果が、YESの場合にはステップS13へ進み、NOの場合にはステップS12へ進む。
また、エンジン1が稼働中であることが条件として制御を作動させるので、急アクセルオフや急ブレーキ操作後に、システム要求によりエンジン1が可動しても、急アクセルオフや急ブレーキ操作による再加速を向上する制御が作動することはなく、運転者に違和感を与えることがない。
急アクセルオフや急ブレーキ操作により再加速シーンを検知し、再加速性能の向上を行う制御の作動後に、再加速向上制御部26で再加速向上シーンではないと判定した場合にあっても、急アクセルオフや急ブレーキ操作による再加速シーンを判定し再加速制御によるエンジン停止を禁止することで、再加速性能の向上を図ることができる。
図5において、ステップS11で、再加速性能向上部26が、現在情報によって再加速性能の向上が必要なシーンであるか否かを判定する。ここで、現在情報としては、たとえば急アクセルオフや急ブレーキ操作がある。判定結果が、YESの場合にはステップS23へ進み、NOの場合にはステップS22へ進む。
ここで、カーブの検知は、以下のように行う。すなわち、再加速性能向上部26は、たとえば図示しない車輪速センサから入力された4輪車輪速度、図示しない操舵角センサから入力された操舵角、図示しない加速センサから入力された車両横方向加速度、図示しない車速センサから入力された車速に基づいてカーブを検知する。なお、カーブの検出は、図示しないヨーレイトセンサから入力されたヨーレイト、図示しない前後方向加速度センサから入力された前後方向加速度、から入力された車速に基づいてカーブか否かを検出するなど、他の方法であってもよい。上記演算の結果、カーブ判定があればステップS24へ進み、カーブ判定でなければステップS22へ進む。
また、上記制御の開始条件にエンジン稼働中であることを条件に加えているので(ステップS24)、エンジン停止中に再加速シーンを予測してもエンジン1の始動が禁止され、運転者要求やシステム要求以外でエンジン1が始動するのを防ぎ、違和感を与えない。
また、このように上記制御の開始条件にエンジン停止中であることを加えても、再加速シーンを予測している時は、エンジン1が稼働中であることがほとんどであるので、問題ない。
さらに、カーブを検知し再加速レスポンスの向上を行う制御が作動した後に、再加速性能幸寿御部26が再加速向上シーンではないと判定した場合でも、カーブ検知により再加速レスポンス向上を行う制御によってエンジン1の停止を禁止するので、再加速レスポンスを向上させることができる。
すなわち、エンジンの再加速シーンを予測した場合に、エンジン1が稼働中の際はこのエンジン1の停止を禁止し、エンジン1が停止中の際にはアクセル開度に基づいてアクセルオンによりエンジン1の始動を行うようにしたので、運転者要求やシステム要求以外でエンジン1が始動することによる運転者への違和感を抑制することができる。
一方、エンジン停止モードで登り勾配を走行しているときは、車両が減速していることが多いことから、運転者要求やシステム要求以外でエンジン1が始動するのを禁止して運転者に違和感を与えないようにすることができる。
図6は、ハイブリッド車両ではなく、モータを有せず、エンジン1のみで車両を駆動し、アクセル開度に応じて、エンジン1に接続したトルクコンバータ17と変速機4との間に配置したクラッチ18の接続・開放を制御(アクセル開度0で開放)する、いわゆるコーストストップセーリング機能を有する車両である。
また、図7は、エンジン1にジェネレータ19を接続しエンジン1の稼働で発電した電力をインバータ8aで直流電流に変換してバッテリ9に充電する一方、バッテリ9からモータ(モータ/ジェネレータ)2への電力供給をインバータ8bにより三相交流電流に変換して行うようにした車両である。
また、プラグインハイブリッド車両であっても良いことは言うまでもない。
Claims (5)
- 燃料の燃焼により駆動力を活性するエンジンと、
該エンジンに供給する燃料量を制御するアクセルペダルの操作量に相当するアクセル開度を検出するアクセル開度センサと、
該アクセル開度センサで検出した前記アクセル開度の大きさに基づいて前記エンジンの停止と始動を判定するエンジン停止・始動判定手段と、
前記エンジン停止・始動判定手段の判定に応じてエンジンの停止・始動を行うエンジン制御手段と、
前記アクセル開度センサで検出したアクセル開度に基づいてアクセルオフ後にアクセルオンを行う再加速シーンを予測する再加速シーン予測手段と、
を備え、
該再加速シーン予測手段が前記エンジンの再加速シーンを予測した場合に、前記エンジン停止・始動判定手段は、該エンジンが稼働中の際は該エンジンの停止を禁止し、該エンジンが停止中の際には前記アクセル開度センサで検出した前記アクセル開度に基づいてアクセルオンにより前記エンジン制御手段が前記エンジンの始動を行うようにした、
ことを特徴とする車両の制御装置。 - 請求項1に記載の車両の制御装置において、
前記再加速シーン予測手段は、少なくとも車両の前後方向加減速度を含み車両に作用する加減速度またこれに関する物理量を積算処理して運転状況に関する値を算出し、この運転状況に関する値と閾値とを比較することで再加速シーンを予測する、
ことを特徴とする車両の制御装置。 - 請求項1に記載の車両の制御装置において、
前記再加速シーン予測手段は、少なくとも道路勾配を検知し、この勾配を積算処理して走行環境に関する値を算出し、この走行環境に関する値と閾値とを比較することで再加速シーンを予測する、
ことを特徴とする車両の制御装置。 - 請求項1に記載の車両の制御装置において、
該制御装置は、ブレーキ操作を検出するブレーキセンサをさらに備え、
該ブレーキセンサで検出したブレーキ操作量に基づく急ブレーキ操作あるいは前記アクスル開度センサで検出したアクセル開度に基づく急アクセルオフ操作を検知し、前記再加速シーン予測手段が再加速シーンを予測し、前記エンジンの稼働中を検出したときは、該エンジンの停止を禁止するようにした、
ことを特徴とする車両の制御装置。 - 請求項1に記載の車両の制御装置において、
該制御装置は、車両の横加速度およびステアリング角度のうちの少なくとも一方と車速とに基づいてカーブを検出するカーブ検出手段をさらに備え、
該カーブ検出手段がカーブを検出し、前記再加速シーン予測手段が再加速シーンを予測し、前記エンジンの稼働中を検出したときは、該エンジンの停止を禁止するようにした、
ことを特徴とする車両の制御装置。
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