JP2016175531A - Control device for hybrid vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a control device for a hybrid vehicle that achieves both reduction in slip-in-shock and improvement in slip-in-response during slip-in-control of a friction clutch.SOLUTION: A drive system in which a second clutch CL2 is interposed between a motor generator and left and right front wheels is provided. This FF hybrid vehicle is provided with a hybrid control module in which, when engine start is requested, CL2 slip-in-control is exerted by adding motor torque to driver request drive torque and by causing a difference between the motor torque and CL2 clutch capacity. During the CL2 slip-in-control, the hybrid control module decreases upward gradation of the added motor torque as driver shock sensitivity becomes higher, S7, and increases it as the driver shock sensitivity becomes lower, S8.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a control apparatus for a hybrid vehicle that performs slip-in control for slipping a friction clutch interposed between a motor and drive wheels when an engine start request is issued.

  Conventionally, there has been known an engine start control device for a hybrid vehicle that performs CL2 slip-in control for starting slip of a second clutch by increasing motor torque when an engine start request is made (see, for example, Patent Document 1). .

JP 2007-69817 A

  However, when performing CL2 slip-in control, the conventional device is configured to give a predetermined constant gradient as the torque increase gradient of the motor torque. For this reason, if the increase gradient of the motor torque is set so as to meet the demand for improving the slip-in response, for example, a slip-in shock that the driver feels when the accelerator is constant or at a slow acceleration occurs. On the other hand, if the increase gradient of the motor torque is set so as to meet the demand for reducing the slip-in shock, there is a problem that the completion of the slip-in control is delayed, for example, at the start of accelerator depression.

  The present invention has been made paying attention to the above-mentioned problem, and an object of the present invention is to provide a hybrid vehicle control device that achieves both slip-in shock reduction and slip-in response improvement during slip-in control of a friction clutch. .

In order to achieve the above object, the present invention includes a drive system in which an engine and a motor are used as drive sources and a friction clutch is interposed between the motor and drive wheels.
In this hybrid vehicle, a controller is provided that performs slip-in control of the friction clutch by adding motor torque to driver-requested drive torque and causing a difference between the motor torque and clutch capacity when there is an engine start request.
During the slip-in control, the controller reduces the added motor torque increase slope as the driver shock sensitivity is higher and increases as the driver shock sensitivity is lower.

Therefore, during the slip-in control, the increased slope of the added motor torque is reduced as the driver shock sensitivity is higher, and is increased as the driver shock sensitivity is lower.
In other words, during slip-in control, the magnitude of the rising slope of the motor torque is determined according to the level of driver shock sensitivity. Therefore, when the driver shock sensitivity is high, such as when the accelerator is constant or when the vehicle is slowly accelerating, the rising slope of the motor torque is reduced, so that the occurrence of slip-in shock can be kept low. On the other hand, when the driver shock sensitivity is low, such as when the accelerator is depressed, the slip-in control is completed early by increasing the rising slope of the motor torque.
As a result, at the time of slip-in control of the friction clutch, both reduction of slip-in shock and improvement of slip-in response can be achieved.

1 is an overall system diagram illustrating an FF hybrid vehicle to which a control device according to a first embodiment is applied. It is a flowchart which shows the flow of the CL2 slip-in control process performed in the hybrid control module of Example 1. FIG. 6 is an EV-HEV mode transition map showing specific examples of various movements of operating points (VSP, APO) that discriminate between high and low driver shock sensitivity in the CL2 slip-in control process of the first embodiment. 6 is a time chart showing characteristics of CL2 torque, motor torque, and front-rear G when there is no defatter-packing determination region during EV travel and there is no intervention of an engine start request. Characteristics of CL2 torque command, CL2 actual torque, motor torque, and front / rear G when the CL2 slip-in control of the first embodiment intervenes based on an engine start request issued during EV driving and in the middle of the defattering determination area It is a time chart which shows. Time indicating the characteristics of CL2 torque command, CL2 actual torque, motor torque, and front and rear G when CL2 slip-in control of the first embodiment is performed based on the engine start request issued during EV driving with constant acceleration and slow acceleration It is a chart. A time chart showing the characteristics of CL2 torque command, CL2 actual torque, motor torque, and front / rear G when the CL2 slip-in control of the first embodiment is performed based on the engine start request issued during EV travel by depressing the accelerator. is there.

  Hereinafter, the best mode for realizing a control device for a hybrid vehicle of the present invention will be described based on a first embodiment shown in the drawings.

First, the configuration will be described.
The control device in the first embodiment is applied to an FF hybrid vehicle (an example of a hybrid vehicle) in which left and right front wheels are drive wheels and a belt type continuously variable transmission is mounted as a transmission. Hereinafter, the configuration of the control device for the FF hybrid vehicle according to the first embodiment will be described by being divided into an “overall system configuration” and a “CL2 slip-in control processing configuration”.

[Overall system configuration]
FIG. 1 shows an overall system of an FF hybrid vehicle to which the control device of the first embodiment is applied. Hereinafter, the overall system configuration of the FF hybrid vehicle will be described with reference to FIG.

  As shown in FIG. 1, the drive system of the FF hybrid vehicle includes a horizontally placed engine 2, a first clutch 3 (abbreviated “CL1”), a motor generator 4 (abbreviated “MG”), and a second clutch 5 (abbreviated). "CL2") and a belt type continuously variable transmission 6 (abbreviated as "CVT"). The output shaft of the belt type continuously variable transmission 6 is drivingly connected to the left and right front wheels 10R and 10L via a final reduction gear train 7, a differential gear 8, and left and right drive shafts 9R and 9L. The left and right rear wheels 11R and 11L are driven wheels.

  The horizontal engine 2 is an engine disposed in a front room with a starter motor 1 and a crankshaft direction as a vehicle width direction, an electric water pump 12, and a crankshaft rotation sensor 13 for detecting reverse rotation of the horizontal engine 2. Have. This horizontal engine 2 has an “MG start mode” in which cranking is performed by the motor generator 4 while the first clutch 3 is slidingly engaged, and a starter motor 1 which is powered by the 12V battery 22 as an engine starting method. Starter start mode ". The “starter start mode” is selected only when a limited condition such as a cryogenic temperature condition is satisfied.

  The motor generator 4 is a three-phase AC permanent magnet synchronous motor connected to the transverse engine 2 via the first clutch 3. The motor generator 4 uses a high-power battery 21 described later as a power source, and an inverter 26 that converts direct current to three-phase alternating current during power running and converts three-phase alternating current to direct current during regeneration is connected to the stator coil via an AC harness 27. Connected. The first clutch 3 interposed between the horizontal engine 2 and the motor generator 4 is a dry or wet multi-plate clutch operated by hydraulic operation, and complete engagement / slip engagement / release is controlled by the first clutch hydraulic pressure. Is done.

  The second clutch 5 is a hydraulically operated wet multi-plate friction clutch interposed between the motor generator 4 and the left and right front wheels 10R and 10L as drive wheels, and is fully engaged / slip engaged by the second clutch hydraulic pressure. / Open is controlled. The second clutch 5 in the first embodiment uses a forward clutch 5a and a reverse brake 5b provided in a forward / reverse switching mechanism using a planetary gear. That is, the forward clutch 5 a is the second clutch 5 during forward travel, and the reverse brake 5 b is the second clutch 5 during reverse travel.

  The belt-type continuously variable transmission 6 includes a primary pulley 6a, a secondary pulley 6b, and a belt 6c that spans the pulleys 6a and 6b. And it is a transmission which obtains a stepless gear ratio by changing the winding diameter of belt 6c with the primary pressure and secondary pressure supplied to a primary oil chamber and a secondary oil chamber. The belt type continuously variable transmission 6 includes a main oil pump 14 (mechanical drive) that is rotated by a motor shaft (= transmission input shaft) of a motor generator 4 as a hydraulic pressure source, and a sub oil pump used as an auxiliary pump. 15 (motor drive). And the control which produces the primary pressure and the secondary pressure of the 1st clutch pressure, the 2nd clutch pressure, and the belt-type continuously variable transmission 6 from the line pressure PL produced | generated by adjusting the pump discharge pressure from a hydraulic power source as a source pressure. A valve unit 6d is provided.

  The first clutch 3, the motor generator 4 and the second clutch 5 constitute a hybrid drive system called a one-motor / two-clutch. The main drive modes are "EV mode", "HEV mode", "WSC mode" Have The “EV mode” is an electric vehicle mode in which the first clutch 3 is disengaged and the second clutch 5 is engaged and only the motor generator 4 is used as a drive source, and traveling in the “EV mode” is referred to as “EV traveling”. The “HEV mode” is a hybrid vehicle mode in which both the clutches 3 and 5 are engaged and the transverse engine 2 and the motor generator 4 are used as driving sources, and traveling in the “HEV mode” is referred to as “HEV traveling”. The “WSC mode” is a CL2 slip engagement mode in which the motor generator 4 is controlled at the motor rotation speed and the second clutch 5 is engaged with the engagement torque capacity corresponding to the driver requested drive torque in the “HEV mode” or the “EV mode”. It is.

  As shown in FIG. 1, the braking system of the FF hybrid vehicle includes a brake operation unit 16, a brake fluid pressure control unit 17, left and right front wheel brake units 18R and 18L, and left and right rear wheel brake units 19R and 19L. ing. In this braking system, when regeneration is performed by the motor generator 4 during brake operation, regenerative cooperative control is performed in which the hydraulic braking force shares the amount obtained by subtracting the regenerative braking force from the requested braking force with respect to the requested braking force based on the pedal operation. Done.

  The brake operation unit 16 includes a brake pedal 16a, a negative pressure booster 16b that uses the intake negative pressure of the horizontal engine 2, a master cylinder 16c, and the like. The regenerative cooperative brake unit 16 generates a predetermined master cylinder pressure in accordance with the brake depression force applied from the driver to the brake pedal 16a, and is a unit having a simple configuration that does not use an electric booster.

  Although not shown, the brake fluid pressure control unit 17 includes an electric oil pump, a pressure increasing solenoid valve, a pressure reducing solenoid valve, an oil path switching valve, and the like. Control of the brake fluid pressure control unit 17 by the brake control unit 85 exhibits a function of generating wheel cylinder fluid pressure when the brake is not operated and a function of adjusting wheel cylinder fluid pressure when the brake is operated. Control using the hydraulic pressure generation function when the brake is not operated includes traction control (TCS control), vehicle behavior control (VDC control), emergency brake control (automatic brake control), and the like. Controls using the hydraulic pressure adjustment function during brake operation include regenerative cooperative brake control, antilock brake control (ABS control), and the like.

  The left and right front wheel brake units 18R and 18L are provided on the left and right front wheels 10R and 10L, respectively, and the left and right rear wheel brake units 19R and 19L are provided on the left and right rear wheels 11R and 11L, respectively. Give. These brake units 18R, 18L, 19R and 19L have wheel cylinders (not shown) to which the brake fluid pressure generated by the brake fluid pressure control unit 17 is supplied.

  As shown in FIG. 1, the power supply system of the FF hybrid vehicle includes a high-power battery 21 as a power supply for the motor generator 4 and a 12V battery 22 as a power supply for a 12V system load.

  The high-power battery 21 is a secondary battery mounted as a power source for the motor generator 4. For example, a lithium ion battery in which a cell module constituted by a large number of cells is set in a battery pack case is used. The high-power battery 21 has a built-in junction box in which relay circuits for supplying / cutting off / distributing high-power are integrated, and further includes a cooling fan unit 24 having a battery cooling function, a battery charging capacity (battery SOC) and a battery. And a lithium battery controller 86 for monitoring the temperature.

  The high-power battery 21 and the motor generator 4 are connected via a DC harness 25, an inverter 26, and an AC harness 27. The inverter 26 is provided with a motor controller 83 that performs power running / regenerative control. That is, the inverter 26 converts the direct current from the DC harness 25 into the three-phase alternating current to the AC harness 27 during power running that drives the motor generator 4 by discharging the high-power battery 21. Further, the three-phase alternating current from the AC harness 27 is converted into direct current to the DC harness 25 during regeneration in which the high-power battery 21 is charged by power generation by the motor generator 4.

  The 12V battery 22 is a secondary battery mounted as a power source for a starter motor 1 and a 12V system load that is an auxiliary machine. For example, a lead battery mounted in an engine vehicle or the like is used. The high voltage battery 21 and the 12V battery 22 are connected via a DC branch harness 25a, a DC / DC converter 37, and a battery harness 38. The DC / DC converter 37 converts a voltage of several hundred volts from the high-power battery 21 into 12V, and the charge amount of the 12V battery 22 is controlled by controlling the DC / DC converter 37 by the hybrid control module 81. The configuration is to be managed.

  As shown in FIG. 1, the electronic control system of the FF hybrid vehicle includes a hybrid control module 81 (abbreviation: “HCM”) as an electronic control unit having an integrated control function for appropriately managing energy consumption of the entire vehicle. Yes. Other electronic control units include an engine control module 82 (abbreviation: “ECM”), a motor controller 83 (abbreviation: “MC”), and a CVT control unit 84 (abbreviation: “CVTCU”). Furthermore, it has a brake control unit 85 (abbreviation: “BCU”) and a lithium battery controller 86 (abbreviation: “LBC”). These electronic control units 81, 82, 83, 84, 85, 86 are connected via a CAN communication line 90 (CAN is an abbreviation for “Controller Area Network”) so that bidirectional information can be exchanged, and share information with each other.

  The hybrid control module 81 performs various integrated controls based on input information from other electronic control units 82, 83, 84, 85, 86, an ignition switch 91, and the like.

  The engine control module 82 is based on input information from the hybrid control module 81, the engine speed sensor 92, and the like, and controls the start of the horizontal engine 2, fuel injection control, ignition control, fuel cut control, engine idle speed control, etc. I do.

  The motor controller 83 performs power running control, regenerative control, motor creep control, motor idle control, etc. of the motor generator 4 according to control commands for the inverter 26 based on input information from the hybrid control module 81, the motor rotational speed sensor 93, and the like. Do.

  The CVT control unit 84 outputs a control command to the control valve unit 6d based on input information from the hybrid control module 81, the accelerator opening sensor 94, the vehicle speed sensor 95, the inhibitor switch 96, the ATF oil temperature sensor 97, and the like. The CVT control unit 84 performs the engagement hydraulic pressure control of the first clutch 3, the engagement hydraulic pressure control of the second clutch 5, the transmission hydraulic pressure control by the primary pressure and the secondary pressure of the belt type continuously variable transmission 6, and the like.

  The brake control unit 85 outputs a control command to the brake hydraulic pressure control unit 17 based on input information from the hybrid control module 81, the brake switch 98, the brake stroke sensor 99, and the like. The brake control unit 85 performs TCS control, VDC control, automatic brake control, regenerative cooperative brake control, ABS control, and the like.

  The lithium battery controller 86 manages the battery SOC, battery temperature, and the like of the high-power battery 21 based on input information from the battery voltage sensor 100, the battery temperature sensor 101, and the like.

[CL2 slip-in control processing configuration]
FIG. 2 shows a flow of CL2 slip-in control processing executed by the hybrid control module 81 (controller) of the first embodiment. In the following, each step of FIG. 2 representing a CL2 slip-in control processing configuration for starting control based on the output of the engine start request and ending control by CL2 slip determination will be described.

In step S1, the torque command for the second clutch CL2 is reduced from a command for giving the capacity that the second clutch CL2 does not slip relative to the motor torque to a command for giving a capacity equivalent to the driver requested drive torque, and step S2 Proceed to
Here, the “capacity that the second clutch CL2 does not slip” means the torque capacity obtained by adding the additional torque to the motor torque so that the second clutch CL2 does not slip and maintains the complete engagement even if the motor torque fluctuates. Say. The “driver-requested driving torque” is determined based on the accelerator opening APO and the vehicle speed VSP so that the larger the accelerator opening APO and the higher the vehicle speed VSP, the larger the torque value.

In step S2, following the CL2 torque command decrease in step S1, it is determined whether or not the deftagnation determination is ON. If YES (deflag filling determination ON), the process proceeds to step S3. If NO (deflation filling determination OFF), the process proceeds to step S6.
Here, “defect filling determination ON” is determined independently of the CL2 slip-in control process, and the driver-requested drive torque is switched from negative to positive to start the ON determination, and the driver-requested drive torque is positive. It is determined whether the end (defragment filling determination OFF) is below a predetermined value.

In step S3, following the determination in step S2 that the defogger stuffing determination is ON, the motor torque rising gradient is set to the first gradient α1, and the process proceeds to step S4.
Here, the first gradient α1 is set as a gradient that suppresses the backlash of the differential gear having high driver shock sensitivity when the accelerator is released, and has a smaller gradient value than a second gradient α2 described later.

  In step S4, following the setting of the first gradient α1 in step S3 or the determination that the deftagnation filling determination is ON in step S5, a motor torque command that increases with the first gradient α1 set in step S3 is issued. Output, and go to step S5.

  In step S5, following the motor torque command based on the first gradient α1 in step S4, it is determined whether or not the differential stuffing determination is OFF. If YES (defect filling determination OFF), the process proceeds to step S6. If NO (deflation filling determination ON), the process returns to step S4.

In step S6, following the determination that the deftagnation determination is OFF in step S2 or step S5, the vehicle speed VSP and the accelerator opening change speed ΔAPO are used for determining the driver shock sensitivity. In addition, it is determined whether or not a condition that the accelerator opening change speed ΔAPO is equal to or less than a specified value is satisfied. If YES (vehicle speed VSP ≦ specified value and accelerator opening change speed ΔAPO ≦ specified value), the process proceeds to step S7, and NO (vehicle speed VSP> specified value or accelerator opening change speed ΔAPO> specified value). Advances to step S8.
That is, the driver shock sensitivity is determined to be higher as the vehicle speed VSP is on the lower vehicle speed side (lower gear ratio side) and the accelerator opening change speed ΔAPO due to the accelerator depressing operation is smaller. Conversely, when the vehicle speed VSP is on the high vehicle speed side (high gear ratio side) or when the accelerator opening change speed ΔAPO due to the accelerator sudden depression operation is large, it is determined that the driver shock sensitivity is low.

In step S7, following the determination in step S6 that the vehicle speed VSP ≦ the specified value and the accelerator opening change speed ΔAPO ≦ the specified value, it is determined that the driver shock sensitivity is high, and the rising gradient of the motor torque is set to the second gradient. The gradient α2 is set, and the process proceeds to step S9.
That is, in FIG. 3, in the case of a slow acceleration traveling scene from the driving point A where the vehicle speed VSP ≦ the specified value or a constant accelerator starting traveling scene from the driving point B where the vehicle speed VSP ≦ the specified value, the driver shock sensitivity is high. Determined. Furthermore, it is determined that the driver shock sensitivity is high also in the case of a system start (when an engine start is requested due to a decrease in battery SOC or the like) in a coasting scene from the driving point C where the vehicle speed VSP ≦ the specified value.

In step S8, following the determination that the vehicle speed VSP> the specified value or the accelerator opening change speed ΔAPO> the specified value in step S6, it is determined that the driver shock sensitivity is low, and the rising slope of the motor torque is set to a third value. The gradient α3 (> second gradient α2) is set, and the process proceeds to step S9.
That is, in FIG. 3, in the case of the driving point D where the accelerator opening change speed ΔAPO> the specified value or the stepping start running scene from the driving point E, it is determined that the driver shock sensitivity is low. Furthermore, in the case of a system start in a slowly accelerating driving scene from the driving point F where the vehicle speed VSP> the specified value, a constant accelerator starting driving scene from the driving point G, and a coast driving scene from the driving point H, the driver shock sensitivity is Determined to be low.

  In step S9, following the gradient setting in step S7 and step S8 or the determination of no CL2 slip determination in step S10, the motor is increased by the selected gradient (second gradient α2 or third gradient α3). A torque command is output and it progresses to step S10.

In step S10, following the motor torque command based on the second gradient α2 or the third gradient α3 selected in step S9, it is determined whether or not the second clutch CL2 starts slipping and slip determination is made. If YES (CL2 slip determination is present), the process proceeds to the end. If NO (CL2 slip determination is not present), the process returns to step S9.
Here, “CL2 slip determination” monitors the slip amount of the second clutch CL2, and determines that the CL2 slip determination is present when the slip amount is equal to or greater than the slip determination threshold.

Next, the operation will be described.
The operation of the control device for the FF hybrid vehicle of the first embodiment will be described separately for “CL2 slip-in control processing operation”, “CL2 slip-in control operation”, and “characteristic operation of CL2 slip-in control”.

[CL2 slip-in control processing action]
Hereinafter, the operation of the CL2 slip-in control process will be described based on the flowchart of FIG.

  When the engine start request is issued in the state where the deftagnation determination is ON, the process proceeds from step S1, step S2, step S3, step S4, and step S5 in the flowchart of FIG. Then, while it is determined at step S5 that the deflation stuffing determination is ON, the flow from step S4 to step S5 is repeated. In step S1, the torque command for the second clutch CL2 is reduced from a command for giving the capacity that the second clutch CL2 does not slip with respect to the motor torque to a command for giving a capacity equivalent to the driver requested drive torque. Note that the CL2 actual torque decreases with a response delay of the hydraulic pressure (see FIGS. 5, 6, and 7). In step S3, the rising gradient of the motor torque is set to the first gradient α1 (<second gradient α2). In step S4, a motor torque command that increases with the first gradient α1 set in step S3 is output.

  Then, if it is determined in step S5 that the deflation filling determination is OFF, in the flowchart of FIG. 2, the process proceeds from step S5 to step S6. It is determined whether or not a condition that is equal to or less than a specified value is satisfied. If it is determined in step S6 that the vehicle speed VSP ≦ the specified value and the accelerator opening change speed ΔAPO ≦ the specified value, the process proceeds to step S7. In step S7, the motor torque is determined based on the determination that the driver shock sensitivity is high. Is set to the second gradient α2. On the other hand, if it is determined in step S6 that the vehicle speed VSP> the specified value or the accelerator opening change speed ΔAPO> the specified value, the process proceeds to step S8, and in step S8, based on the determination that the driver shock sensitivity is low, The rising gradient of the torque is set to the third gradient α3 (> second gradient α2).

  Then, the process proceeds from step S7 or step S8 to step S9 → step S10, and the process of proceeding to step S9 → step S10 is repeated until it is determined in step S10 that the CL2 slip determination is present. In step S9, a motor torque command that increases with the selected gradient (second gradient α2 or third gradient α3) is output. If it is determined in step S10 that the CL2 slip determination is present, the process proceeds from step S10 to the end, and the CL2 slip-in control is terminated.

  On the other hand, when the engine start request is issued in the state of the defatter stuffing determination OFF, the process proceeds from step S1 to step S2 to step S6 in the flowchart of FIG. Then, in the same way as described above, if the processing speed after step S6 is determined in step S6 as vehicle speed VSP ≦ specified value and accelerator opening change speed ΔAPO ≦ specified value, step S6 to step S7 → step S9 → Proceed to step S10. Then, a motor torque command that rises by the second gradient α2 is output until the CL2 slip-in control is finished. If it is determined in step S6 that the vehicle speed VSP> the specified value or the accelerator opening change speed ΔAPO> the specified value, the process proceeds from step S6 to step S8 → step S9 → step S10. Then, a motor torque command that increases by the third gradient α3 is output until the CL2 slip-in control is finished.

[CL2 slip-in control action]
Hereinafter, the CL2 slip-in control action of Example 1 is referred to as “technical background”, “CL2 slip-in control action in the defagged region (FIGS. 4 and 5)”, “CL2 slip-in control at constant acceleration / slow acceleration” “Operation (FIG. 6)” and “CL2 slip-in control operation when the accelerator is depressed (FIG. 7)”.

(Technical background)
As in the first embodiment, the one-motor / two-clutch drive system is based on the concept of blocking the torque fluctuation transmitted to the drive wheels by slipping the second clutch CL2 when the engine is started in the MG start mode.
Therefore, when there is an engine start request, CL2 slip-in control for starting the slip of the second clutch CL2 is performed in order to prevent an engine start shock due to a sudden torque change at the time of engine start. This CL2 slip-in control increases the input torque to the second clutch CL2 by adding the motor torque to the driver requested drive torque, and causes a difference between the motor torque and the CL2 clutch capacity (≈ driver requested drive torque). This is done by urging the second clutch CL2 to slip due to the torque difference.

  In the CL2 slip-in control, how to set the rising gradient of the added motor torque is important. Therefore, the present inventors have analyzed the relationship between the motor torque increase gradient, slip-in time, and slip-in shock through experiments. As a result, the larger the motor torque increase gradient, the shorter the slip-in time and the better the slip-in response. Further, the slip-in shock increases as the motor torque increase gradient increases. Based on this result, the response request is determined based on the accelerator operation information by the driver, and the motor torque increase gradient is increased when the response request is high, and the motor torque increase gradient is decreased at other times.

  However, when the same motor torque increase gradient is used, the slip-in shock worsens on the low vehicle speed side (low gear ratio side), but the slip-in shock does not deteriorate on the high vehicle speed side (high gear ratio side). . In this way, if only the accelerator operation information by the driver is used, the gear ratio becomes high in the high vehicle speed region, so the slip-in shock sensitivity is low, and it is desired to bring it to the slip-in response side, but it cannot be separated.

Based on the above knowledge, we focused on driver shock sensitivity, added vehicle speed information to accelerator operation information to determine driver shock sensitivity, and came up with the idea of separating the motor torque increase gradient according to driver shock sensitivity. It became clear that the slip-in shock reduction and the slip-in response improvement can be achieved by separating the motor torque increase gradient according to the driver shock sensitivity. However, since the backlash area is highly sensitive to backlash generated by sudden reversal of the direction of torque, it is necessary to reduce the motor torque increase gradient by another setting regardless of the driver operation.
The CL2 slip-in control according to the first embodiment adopts a configuration in which the motor torque increase gradient is separated according to the driver shock sensitivity while setting the differential region separately based on the above concept.

(CL2 slip-in control action in the defugat packing area)
FIG. 4 shows a time chart when the deftagnation determination is made during EV travel without intervention of the engine start request. In the differential stuffing determination region from time t1 to time t3, the CL2 torque is reduced at a level that keeps the second clutch CL2 fully engaged, and the motor torque is increased at a predetermined gradient, and then a constant torque is maintained. Thereby, the backlash generated before and after time t3 is reduced.

FIG. 5 is a time chart when the CL2 slip-in control according to the first embodiment intervenes based on the engine start request issued during the EV traveling and in the middle of the defattering determination region.
In FIG. 5, time t1 is a deftagnation determination start time, time t2 is a start start time (CL2 slip-in control start time), and time t3 is a deftagnation determination end time.
From the deftagnation determination start time t1 to the start start time t2, it is the same as in FIG. 4 without the intervention of the engine start request. Then, when the CL2 slip-in control is started at time t2, the torque command to the second clutch CL2 is reduced to a command for giving a capacity equivalent to the driver requested drive torque. At the same time, since it is the differential stuffing determination region, the motor torque increase slope is set to the first gradient α1, and the motor torque rises with a gentle slope from time t2 to defgata stuffing determination end time t3. Then, after the differential rattling determination end time t3, as in FIG. 6 or FIG. 7, the motor torque increase gradient is set to the second gradient α2 or the third increase gradient α3, and the motor torque increases according to the set gradient. .
In this way, by setting the motor torque increase slope in the differential backlash determination region to the first slope α1 aiming at reducing the backlash shock, even if there is an engine start request intervention, the backlash generated before and after time t3. Shock is reduced.

(CL2 slip-in control action when accelerator is constant and slow acceleration)
FIG. 6 is a time chart when the CL2 slip-in control according to the first embodiment is performed based on an engine start request issued during EV traveling with constant acceleration / slow acceleration.
In FIG. 6, time t1 is a start start time (CL2 slip-in control start time), and time t2 is a CL2 slip determination time.
When the CL2 slip-in control is started at time t1, the torque command to the second clutch CL2 is lowered to a command for giving a capacity equivalent to the driver-requested driving torque. At the same time, based on the determination that the driver shock sensitivity is high due to constant acceleration and slow acceleration, the motor torque rise gradient is set to the second gradient α2 (> α1), and the motor torque from time t1 to time t2 Rises at the slope of the second slope α2. When the CL2 slip is determined at time t2, the CL2 slip-in control is ended, and the engine start control by engine cranking is started.
In this way, by setting the motor torque increase slope when the driver shock sensitivity is high to the second gradient α2, the CL2 slip-in shock can be suppressed to be small as is clear from the comparison with FIG.

(CL2 slip-in control action when the accelerator is depressed)
FIG. 7 is a time chart when the CL2 slip-in control according to the first embodiment is performed based on an engine start request issued during EV traveling by an accelerator depression operation.
In FIG. 7, time t1 is a start start time (CL2 slip-in control start time), and time t2 is a CL2 slip determination time.
When the CL2 slip-in control is started at time t1, the torque command to the second clutch CL2 is lowered to a command for giving a capacity equivalent to the driver-requested driving torque. At the same time, based on the determination that the driver shock sensitivity is low due to depression of the accelerator, the motor torque increase slope is set to the third gradient α3 (> α2), and the motor torque is increased from time t1 to time t2. It rises at the slope of slope α3. When the CL2 slip is determined at time t2, the CL2 slip-in control is ended, and the engine start control by engine cranking is started.
In this way, by setting the motor torque increase gradient when the driver shock sensitivity is low to the third gradient α3, the CL2 slip-in time (time t1 to time t2) becomes clear as is clear from the comparison with FIG. It can be kept short.

[Characteristic action of CL2 slip-in control]
In the first embodiment, during CL2 slip-in control, the added motor torque increase slope is decreased as the driver shock sensitivity is higher, and is increased as the driver shock sensitivity is lower.
In other words, during CL2 slip-in control, the magnitude of the rising slope of the motor torque is determined according to the level of driver shock sensitivity. Therefore, when the driver shock sensitivity is high, such as when the accelerator is constant or when the vehicle is slowly accelerating, the rising slope of the motor torque is reduced, so that the occurrence of slip-in shock can be kept low. On the other hand, when the driver shock sensitivity is low, such as when the accelerator is depressed, the slip-in control is completed early by increasing the rising slope of the motor torque.
As a result, at the time of CL2 slip-in control of the second clutch CL2, both reduction of slip-in shock and improvement of slip-in response can be achieved.

In the first embodiment, the driver shock sensitivity is determined using the vehicle speed VSP and the accelerator opening change speed ΔAPO. The lower the vehicle speed VSP is and the smaller the accelerator opening change speed ΔAPO is, the more the driver shock sensitivity is. It was set as the structure judged to be high.
In other words, by adding the vehicle speed VSP to the driver shock sensitivity determination, for example, when the accelerator opening change speed ΔAPO is the same in a constant or slow acceleration range, the slip-in shock worsens in the low vehicle speed range, but slips in the high vehicle speed range. I don't feel in shock. At this time, it is determined that the driver shock sensitivity is high in the low vehicle speed region, and it is determined that the driver shock sensitivity is low in the high vehicle speed region.
Therefore, the difference in the slip-in shock sensitivity with respect to the vehicle speed is reflected in addition to the difference in the shock sensitivity due to the accelerator operation in the determination of the driver shock sensitivity.

In the first embodiment, it is determined that the driver shock sensitivity is high when the condition that the vehicle speed VSP is equal to or less than the specified value and the accelerator opening change speed ΔAPO is equal to or less than the specified value, and the rising gradient of the motor torque is expressed by the second gradient α2. give. Then, if the vehicle speed condition and the accelerator opening change speed condition are not satisfied, it is determined that the driver shock sensitivity is low, and the rising gradient of the motor torque is given by the third gradient α3 larger than the second gradient α2.
That is, in the slow acceleration traveling scene where the slip-in shock reduction request is required, the accelerator constant traveling scene, the system starting traveling scene, etc., the second gradient α2 is given as the motor torque increase slope, and the slip-in shock reduction request can be met. On the other hand, the third gradient α3 (> α2) is given as the motor torque increase slope in a travel scene of accelerator depression start where slip-in shock sensitivity is low and a slip-in response is required, and the slip-in response request can be met. .
Therefore, it is possible to meet the slip-in shock reduction request and the slip-in response request based on accurate determination of the driver shock sensitivity.

In the first embodiment, separately from the determination of the driver shock sensitivity, a differential filling area in which the driver requested driving torque is switched from negative to positive is determined. The first gradient α1 is smaller than the gradient α2.
That is, the backlash area has a large backlash sensitivity generated by sudden reversal of torque direction. On the other hand, the motor torque increase gradient was reduced by the setting different from the determination of the driver shock sensitivity (first gradient α1).
Accordingly, by setting the differential backlash filling area separately, the backlash of the differential gear 8 can be prevented without impairing the engine start response.

In the first embodiment, the driver requested drive torque is switched from negative to positive to determine the start of the defging area, and when the driver requested driving torque is equal to or less than a predetermined positive value, the end of the defitting area is determined. .
Therefore, by monitoring the driver requested driving torque, the start and end determinations of the defagged area can be performed with high accuracy.

In the first embodiment, when the CL2 slip-in control is started based on the engine start request, a clutch torque command for reducing the engagement capacity of the second clutch CL2 to the equivalent of the driver request drive torque is output.
For example, it is possible to start the slip of the second clutch CL2 only by increasing the motor torque. However, in this case, it is necessary to wait until the motor torque exceeds the engagement capacity of the second clutch CL2, which increases the CL2 slip-in time.
On the other hand, the CL2 slip-in time is shortened by using both the decrease in the CL2 engagement capacity and the increase in the motor torque.

Next, the effect will be described.
In the control apparatus for the FF hybrid vehicle of the first embodiment, the following effects can be obtained.

(1) A friction clutch (second clutch CL2) is provided between the motor (motor generator 4) and the driving wheels (left and right front wheels 10R, 10L) using an engine (horizontal engine 2) and a motor (motor generator 4) as driving sources. ) In a hybrid vehicle (FF hybrid vehicle) having a drive system interposed
When there is an engine start request, the slip-in control (CL2 slip-in control) of the friction clutch (second clutch CL2) adds the motor torque to the driver requested drive torque, and the motor torque and the clutch capacity (CL2 clutch capacity) A controller (hybrid control module 81) is provided that performs the difference,
The controller (hybrid control module 81), during slip-in control (CL2 slip-in control), increases the increasing slope of the motor torque as the driver shock sensitivity is higher and increases as the driver shock sensitivity is lower.
For this reason, at the time of slip-in control (at the time of CL2 slip-in control) of the friction clutch (second clutch CL2), both reduction of slip-in shock and improvement of slip-in response can be achieved.

(2) The controller (hybrid control module 81) uses the vehicle speed VSP and the accelerator opening change speed ΔAPO to determine the driver shock sensitivity. The lower the vehicle speed VSP is, the more the accelerator opening change speed ΔAPO is. The smaller the value, the higher the driver shock sensitivity.
For this reason, in addition to the effect of (1), the difference in slip-in shock sensitivity with respect to the vehicle speed can be reflected in the determination of the level of driver shock sensitivity in addition to the difference in shock sensitivity due to the accelerator operation.

(3) The controller (hybrid control module 81) determines that the driver shock sensitivity is high when the condition that the vehicle speed VSP is less than the specified value and the accelerator opening change speed ΔAPO is less than the specified value is satisfied, and the motor torque increases. If the condition is not satisfied, it is determined that the driver shock sensitivity is low, and the rising gradient of the motor torque is given by a third gradient α3 larger than the second gradient α2.
For this reason, in addition to the effect of (2), it is possible to meet a slip-in shock reduction request and a slip-in response request based on accurate determination of driver shock sensitivity.

(4) The controller (hybrid control module 81) determines the defatter stuffing area where the driver requested drive torque switches from negative to positive separately from the judgment of the driver shock sensitivity. The rising gradient of the torque is given by a first gradient α1 smaller than the second gradient α2.
For this reason, in addition to the effects of (1) to (3), by setting the differential backlash filling area separately, it is possible to prevent backlash of the differential (differential gear 8) without impairing the engine start response. it can.

(5) The controller (hybrid control module 81) determines the start of the defging area by switching the driver-requested driving torque from negative to positive, and when the driver-requesting driving torque falls below a predetermined positive value, Determine the end of.
For this reason, in addition to the effect of (4), it is possible to determine the start and end of the defagged area with high accuracy by monitoring the driver request drive torque.

(6) When the slip-in control (CL2 slip-in control) is started based on the engine start request, the controller (hybrid control module 81) sets the engagement capacity of the friction clutch (second clutch CL2) to the driver requested drive torque. Outputs a clutch torque command to lower
For this reason, in addition to the effects of (1) to (5), the slip-in time of the second clutch CL2 can be shortened by using both the decrease in the engagement capacity of the second clutch CL2 and the increase in the motor torque.

  As mentioned above, although the control apparatus of the hybrid vehicle of this invention was demonstrated based on Example 1, it is not restricted to this Example 1 about a concrete structure, The invention which concerns on each claim of a claim Design changes and additions are permitted without departing from the gist of the present invention.

  In the first embodiment, an example in which a belt type continuously variable transmission 6 in which a belt 6c is stretched between the primary pulley 6a and the secondary pulley 6b and the primary pulley pressure Ppri and the secondary pulley pressure Psec are used as the transmission hydraulic pressure is used as the transmission. . However, as an example of a transmission, an automatic transmission called step AT, an AMT that automatically shifts with a manual transmission structure, a DCT that has two clutches and that automatically shifts with a manual transmission structure, and the like may be used. good.

  In the first embodiment, an example in which the control device of the present invention is applied to an FF hybrid vehicle with a drive format of 1 motor and 2 clutches is shown. However, the control device of the present invention can also be applied to an FR hybrid vehicle or a hybrid vehicle other than the one motor / two clutch drive type. In short, the present invention can be applied to a hybrid vehicle including an engine and a motor as drive sources and a drive system in which a friction clutch is interposed between the motor and drive wheels.

2 Horizontal engine (engine)
3 First clutch 4 Motor generator (motor)
5 Second clutch (friction clutch)
6 Belt type continuously variable transmission 10L, 10R Left and right front wheels (drive wheels)
14 Main oil pump 81 Hybrid control module (controller)
82 Engine control module 83 Motor controller 84 CVT control unit 85 Brake control unit 86 Lithium battery controller

Claims (6)

In a hybrid vehicle including an engine and a motor as a drive source, and having a drive system in which a friction clutch is interposed between the motor and the drive wheel,
When there is an engine start request, a controller is provided that performs slip-in control of the friction clutch by adding a motor torque to a driver request drive torque and causing a difference between the motor torque and the clutch capacity,
The controller for a hybrid vehicle, wherein the controller decreases the increase slope of the added motor torque when the driver shock sensitivity is high and increases the driver shock sensitivity when the slip-in control is performed. In the hybrid vehicle control device according to claim 1,
The controller uses the vehicle speed and the accelerator opening change speed to determine the driver shock sensitivity, and determines that the driver shock sensitivity is higher as the vehicle speed is lower and the accelerator opening change speed is lower. A hybrid vehicle control device. In the hybrid vehicle control device according to claim 2,
The controller determines that the driver shock sensitivity is high when a condition that the vehicle speed is equal to or less than a specified value and the accelerator opening change speed is equal to or less than a specified value, and gives an increasing gradient of the motor torque as a second gradient, If the condition is not satisfied, it is determined that the driver shock sensitivity is low, and the rising gradient of the motor torque is given by a third gradient larger than the second gradient. In the control apparatus of the hybrid vehicle as described in any one of Claim 1- Claim 3,
In addition to determining the driver shock sensitivity, the controller determines a defatter-filling region where the driver-requested drive torque switches from negative to positive. During the determination that the driver-requested driving torque is a defugat-packing region, the controller increases the rising slope of the motor torque. A control device for a hybrid vehicle, characterized by being given a first gradient smaller than two gradients. In the hybrid vehicle control device according to claim 4,
The controller determines the start of the defging area by switching the driver-requested driving torque from negative to positive, and determines the end of the defitting area when the driver-requesting driving torque becomes a predetermined positive value or less. A hybrid vehicle control device. In the hybrid vehicle control device according to any one of claims 1 to 5,
When the slip-in control is started based on an engine start request, the controller outputs a clutch torque command for reducing the engagement capacity of the friction clutch to a driver request drive torque equivalent. .