JP6052343B2 - Hybrid drive device for vehicle - Google Patents

Description

  The present invention relates to a vehicle hybrid drive device, and more particularly to an improvement of a vehicle hybrid drive device having an EV travel mode, a series HEV travel mode, and a parallel HEV travel mode.

  An EV (Electric Vehicle) driving mode in which the engine is separated from the driving force transmission path and can be driven using only the second rotating machine as a driving force source, and the first rotating machine is connected to the engine separated from the driving force transmission path. A series HEV (Hybrid Electric Vehicle) that can travel using only the second rotating machine as a driving force source while rotating and generating electric power. Driving mode, the engine is connected to a driving force transmission path and the engine And a parallel HEV traveling mode capable of traveling using at least one of the first rotating machine and the second rotating machine as a driving force source is selected according to a mode switching condition determined based on at least one of the required driving force and the vehicle speed A vehicle hybrid drive device is known (see Patent Document 1).

JP 2009-274466 A

  However, the conventional hybrid drive system for vehicles does not change the mode switching condition even when the driver selects, for example, a power mode with emphasis on power performance. Even if the accelerator is operated greatly during EV traveling, the series HEV Since the travel mode is shifted to the parallel HEV travel mode, it takes time until a large driving force can be obtained in the parallel HEV travel mode, and a sufficiently satisfactory dribbling performance cannot always be obtained. In particular, even if the engine is started in the series HEV traveling mode, the driving force of the engine cannot be obtained until the parallel HEV traveling mode is entered, which may cause the driver to feel uncomfortable. Even when an eco mode or the like that emphasizes fuel efficiency is selected, the driving point (rotational speed and torque) of the engine is restricted by the vehicle speed or the like when the parallel HEV driving mode is set in accordance with a predetermined mode switching condition. In some cases, the fuel efficiency improvement effect as intended was not obtained.

  The present invention has been made in the background of the above circumstances, and the object of the present invention is EV driving mode, series HEV driving mode, and parallel HEV driving depending on the driver's intention such as emphasis on power performance and fuel efficiency. The purpose is to switch the mode appropriately.

In order to achieve such an object, the first invention is an EV traveling mode in which the engine can be separated from the driving force transmission path and traveled using only the second rotating machine as a driving force source, and the engine separated from the driving force transmission path. In the series HEV driving mode in which the first rotating machine is driven to rotate and generate electricity while using only the second rotating machine as a driving force source, the engine is connected to the driving force transmission path and the engine and the first For a vehicle in which a parallel HEV traveling mode capable of traveling using at least one of the rotating machine and the second rotating machine as a driving force source is selected in accordance with a mode switching condition determined based on at least one of the required driving force and the vehicle speed. in the hybrid drive system, (a) the mode changeover condition, the range of the EV running mode is selected, run the parallel HEV Mode range that is a range selected, and the series HEV mode is selected, are determined in a separate range based on at least one of the required driving force and the vehicle speed, the following (b) the mode changeover condition The range in which the series HEV driving mode is selected is changed according to the driver's intention.
According to a second aspect of the present invention, in the vehicle hybrid drive device of the first aspect, the range in which the series HEV travel mode is selected is changed according to the driver's intention without changing the range in which the EV travel mode is selected. It is characterized by that.
According to a third aspect of the present invention, in the hybrid drive device for a vehicle according to the first or second aspect, the mode switching condition is between a range in which the EV travel mode is selected and a range in which the parallel HEV travel mode is selected. The series HEV driving mode is set to be selected in an intermediate range.

According to a fourth aspect of the present invention, in the hybrid drive device for a vehicle according to any one of the first to third aspects, when the driver desires traveling with emphasis on power performance, the series HEV traveling mode is selected more than usual. The range is narrowed.

A fifth aspect of the invention is the vehicle hybrid drive apparatus according to the fourth aspect of the invention. (A) The mode switching condition is determined based on at least the required driving force, and from the EV traveling mode as the required driving force increases. The series HEV driving mode and the parallel HEV driving mode are set to be selected, and (b) when the driver desires driving focusing on power performance, the series HEV driving mode is selected. The upper limit of the range of the required driving force is set lower than usual.

According to a sixth aspect of the present invention, in the hybrid drive device for a vehicle according to any one of the first to fifth aspects, the series HEV travel mode is selected more than usual when the driver wants to travel with an emphasis on fuel consumption. The range is widened.

The seventh aspect of the invention provides the vehicle hybrid driving device of the sixth invention, before Symbol mode changeover condition is defined based on at least the vehicle speed, the series HEV mode from the EV drive mode in accordance with the increase of the vehicle speed, wherein the parallel HEV drive mode is set to be selected.

In such a vehicle hybrid drive device, the range in which the series HEV driving mode is selected according to the mode switching condition is changed according to the driver's intention. Can be obtained. For example, in the fourth invention, when the driver wants to drive with emphasis on power performance, the range in which the series HEV driving mode is selected is narrower than usual, so that the EV driving mode is quickly shifted to the parallel HEV driving mode. As a result, the drivability is improved, and the driving force by the engine can be obtained immediately after the engine is started so that the driver does not feel uncomfortable. In particular, when the upper limit of the required driving force range in which the series HEV traveling mode is selected as in the fifth aspect of the invention is made lower than usual, the mode shifts to the parallel HEV traveling mode with a smaller required driving force (accelerator operation amount, etc.). Therefore, excellent drivability performance can be obtained.

In the sixth aspect of the invention, the range in which the series HEV driving mode is selected is made wider than usual when the driver desires driving with an emphasis on fuel consumption, so that the time and opportunity for driving in the series HEV driving mode are increased. increases, can operate the engine without being affected by the vehicle speed at the optimal operating point, it improves fuel efficiency.

1 is a schematic configuration diagram of a vehicle hybrid drive device according to an embodiment of the present invention, and is a diagram that also shows a control system for switching a travel mode. FIG. FIG. 2 is a skeleton diagram illustrating an example of a forward / reverse switching device in FIG. 1. It is a figure which shows an example of the mode switching map which switches EV driving mode, series HEV driving mode, and parallel HEV driving mode. It is a figure explaining the various driving modes of the hybrid drive device for vehicles of Drawing 1, and the operating state of each part. It is a flowchart explaining the operation | movement of the mode switching condition setting means of FIG. 1 concretely. It is a schematic block diagram which shows another example of the hybrid drive device for vehicles with which this invention is applied suitably. FIG. 5 is a diagram illustrating still another example of a vehicle hybrid drive device to which the present invention is preferably applied, where (a) is a schematic configuration diagram, and (b) is a diagram illustrating a plurality of travel modes and operating states of each part. . FIG. 5 is a diagram illustrating still another example of a vehicle hybrid drive device to which the present invention is preferably applied, where (a) is a schematic configuration diagram, and (b) is a diagram illustrating a plurality of travel modes and operating states of each part. .

  The engine is an internal combustion engine that generates power by burning fuel. The rotating machine is a rotating electric machine, specifically, a generator, an electric motor, or a motor generator that can selectively obtain the functions of the rotating machine. In the EV traveling mode and the series HEV traveling mode, a driving force source is used. The second rotating machine used as a motor is required to have at least a function as an electric motor, and an electric motor or a motor generator is used. The first rotating machine that generates power in the series HEV traveling mode is required to have at least a function as a generator, but when used as a driving force source in the parallel HEV traveling mode, a motor generator that also functions as an electric motor is used. .

  In the EV traveling mode and the series HEV traveling mode, the engine is disconnected from the driving force transmission path by a connecting / disconnecting device such as a clutch or an automatic transmission capable of disconnecting power transmission. Is connected to the driving force transmission path, and it is possible to travel using the engine as a driving force source. In this parallel HEV traveling mode, it is possible to always travel using the engine and at least one of the first rotating machine and the second rotating machine as a driving force source. For example, a rotating machine with excellent responsiveness is used as an assist. It may be the case. That is, in the parallel HEV traveling mode, at least one of the engine, the first rotating machine, and the second rotating machine is connected to the power transmission path, and the engine and at least one of the first rotating machine and the second rotating machine are driven. In addition to the narrow parallel HEV travel mode that travels using as a power source, the engine travel mode that travels using only the engine as a drive power source, or the driving force of the engine and one of the first rotating machine and the second rotating machine A series parallel HEV traveling mode in which the other of the first rotating machine and the second rotating machine is controlled to generate power and travels while running as a source may be included. In other words, the engine is always used as a driving force source, and at least one of the first rotating machine and the second rotating machine may be used as a driving force source constantly or assistively.

Mode switching conditions, required driving force and determined based on at least one of vehicle speed, for example, the required driving force and the two-dimensional mode switching map or the like to the vehicle speed as a parameter is Ru is set. In general, it is determined that the EV traveling mode is selected on the low required driving force and the low vehicle speed side, and the series HEV traveling mode and the parallel HEV traveling mode are selected as the required driving force and vehicle speed increase. It is also possible to switch the running mode by adding other conditions such as the SOC (remaining power storage) and temperature of the battery that supplies power to the rotating machine. The required driving force can be replaced by an accelerator operation amount operated by the driver, but also includes a driving force request other than the accelerator operation such as during auto-cruise control.

  The mode switching condition is changed according to the driver's intention. This is not limited to the case where a selection operation member related to power performance or fuel consumption performance such as power mode or eco mode is operated by the driver, but also to an automatic transmission. When a sequential mode or manual mode that allows manual shifting can be selected, or when a low speed range such as the L range or 2 range is selected, the power performance is considered important and the mode switching conditions are changed. You may do it. Depending on the driver's driving preference such as the rate of change of accelerator operation amount, accelerator pedal or brake pedal operation tendency, acceleration / deceleration of vehicle speed, etc., the mode switching condition can be changed by judging whether power performance is important or fuel efficiency is important it can. Further, a selection switch for prohibiting the series HEV travel mode is provided, and when the selection switch is operated, the series HEV travel mode is prohibited, and the mode is switched directly between the EV travel mode and the parallel HEV travel mode. good. The change of the range in which the series HEV driving mode is selected includes a change that eliminates the selection range of the series HEV driving mode. When the power performance is important, the selection range of the series HEV driving mode is eliminated and the range is changed to the parallel HEV. It is also possible to enter the traveling mode.

  The mode switching conditions can be changed, for example, in three stages of emphasis on power performance, emphasis on fuel efficiency, and normal between them, but can be changed in two stages or four or more stages, or continuously. It is also possible to change.

As a method of narrowing the range in which the series HEV driving mode is selected in the fourth invention, for example, when the mode switching condition is determined by using the required driving force and the vehicle speed as parameters, May be made lower, the lower limit thereof may be made higher, or both may be made. In carrying out the first aspect of the invention, for example, the range in which the series HEV driving mode is selected may be shifted as a whole, that is, the upper and lower limits of the selection range are both shifted to the low required driving force side or the low vehicle speed side. Various aspects are possible.

In the fifth aspect of the invention, the upper limit of the required driving force range in which the series HEV travel mode is selected is set lower than usual so that the range in which the parallel HEV travel mode is selected is widened when power performance is emphasized. When the mode switching condition is determined with the required driving force and the vehicle speed as parameters, the upper limit of the vehicle speed side may be set lower than usual.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a schematic configuration diagram of a hybrid drive device 10 for a vehicle that is an embodiment of the present invention, and includes an engine 12, a first motor generator MG1 coupled to a crankshaft 14 of the engine 12, and an intermediate shaft 16. The forward / reverse switching device 22 connected to the first motor generator MG1 and connected to the automatic transmission 20 via the input shaft 18 is provided between the output shaft 24 of the automatic transmission 20 and the first gear 25. A starting clutch 26 that cuts off the power transmission, a counter shaft 30 provided with a second gear 28 that meshes with the first gear 25, a second motor generator MG2 connected to the counter shaft 30, and a counter shaft 30. A differential gear device 36 provided with a third gear 32 provided and a fourth gear 34 meshing with the third gear 32; Right axle 38L, precursor wheels 40L of the left and right that are connected via a 38R, and a 40R. The engine 12 is composed of an internal combustion engine that generates power by burning fuel, and the first motor generator MG1 and the second motor generator MG2 can be used as an electric motor and a generator, respectively. In the present embodiment, the first motor generator MG1 corresponds to the first rotating machine, and the second motor generator MG2 corresponds to the second rotating machine.

  As shown in FIG. 2, for example, the forward / reverse switching device 22 includes a double pinion planetary gear device 42, a forward clutch C1, and a reverse brake B1. Specifically, the sun gear of the planetary gear unit 42 is connected to the intermediate shaft 16 and the carrier is connected to the input shaft 18 and selectively connected to the intermediate shaft 16 via the forward clutch C1. The ring gear is selectively fixed to be non-rotatable via the reverse brake B1. When both the forward clutch C1 and the reverse brake B1 are released, the power transmission between the intermediate shaft 16 and the input shaft 18 is interrupted, and when the forward clutch C1 is connected and the reverse brake B1 is released, When the forward drive state in which the rotation of the intermediate shaft 16 is transmitted to the input shaft 18 as it is, the forward clutch C1 is released and the reverse brake B1 is fixed, the rotation of the intermediate shaft 16 is reversed and transmitted to the input shaft 18. It will be in a reverse drive state. The forward clutch C1 and the reverse brake B1 are configured by, for example, a hydraulic friction engagement device. In addition, various aspects, such as being able to comprise using a single pinion type planetary gear apparatus, are possible.

  The automatic transmission 20 uses a belt-type continuously variable transmission in this embodiment, and includes an input side pulley and an output side pulley. The input side pulley is arranged concentrically with the engine 12, the first motor generator MG1, and the forward / reverse switching device 22, and the output side pulley is arranged concentrically with the starting clutch 26 and the first gear 25. ing. The starting clutch 26 is a hydraulic friction engagement device, and corresponds to a connection / disconnection device that connects and disconnects power transmission between the output shaft 24 and the first gear 25. It should be noted that the forward / reverse switching device 22 capable of neutral that cuts off power transmission can also be used as a connection / disconnection device.

  The vehicle hybrid drive device 10 configured as described above includes an electronic control device 50 that performs hybrid control in which a drive force source is switched and the vehicle travels in a plurality of travel modes and the automatic transmission 20 performs shift control. The electronic control unit 50 includes a microcomputer, and performs signal processing in accordance with a program stored in advance in a ROM while using a temporary storage function of a RAM. An accelerator operation amount sensor 52, a vehicle speed sensor 54, a mode From the selection switch 56 and the SOC sensor 58, the accelerator operation amount θacc, which is the operation amount of the accelerator pedal, the vehicle speed V, the selection mode, and the SOC (power storage) of the battery 60 which is the power source of the first motor generator MG1 and the second motor generator MG2. A signal representing the remaining amount is supplied. In addition, although not shown in the drawings, various information necessary for various controls such as the rotational speed of the engine 12 and the rotational speeds of the first motor generator MG1 and the second motor generator MG2 are also detected by the rotational speed sensor. It is supplied from a sensor or the like.

  The mode selection switch 56 is a selection operation member that is provided on an instrument panel, a steering wheel, or the like and that allows the driver to select a power mode that emphasizes driving performance or an eco mode that emphasizes fuel efficiency. If neither is selected, the normal mode is set. The automatic transmission 20 has a power pattern that allows a predetermined input speed relative to the vehicle speed V to be maintained at a relatively high speed (low gear side), for example, different shift conditions determined in advance depending on whether the power mode or the eco mode, or The shift control is performed in accordance with an eco pattern in which the target input rotation speed with respect to the vehicle speed V is relatively low (high gear side). Moreover, SOC is calculated | required by calculating sequentially the charge amount and discharge amount of the battery 60, for example.

  The electronic control device 50 basically includes a hybrid control means 70 and a shift control means 80 in terms of functions. The shift control means 80 performs shift control of the automatic transmission 20 during parallel HEV traveling in which the engine 12 is used as a driving force source. For example, a required driving force such as an accelerator operation amount θacc and a vehicle speed V are predetermined as parameters. The pulley width is adjusted so that the input rotation speed changes according to the target input rotation speed map, and thereby the gear ratio γ is controlled.

  The hybrid control means 70 travels by switching a plurality of types of travel modes shown in FIG. 4 and functionally includes a travel mode switching means 72 and a mode switching condition setting means 74. In the EV traveling mode of FIG. 4, the engine 12 is disconnected from the driving force transmission path with the start clutch 26 in the disconnected state, and the second motor generator MG2 is controlled to perform powering to travel forward or backward. In the series HEV running mode, the engine 12 is operated to rotate the first motor generator MG1 while the start clutch 26 is disconnected and the engine 12 is disconnected from the driving force transmission path, and the first motor generator MG1 is driven. , The second motor generator MG2 is controlled in power running as in the EV traveling mode, and travels forward or backward. The electric power obtained by the first motor generator MG1 is supplied to the second motor generator MG2 or used for charging the battery 60. The power running control means that the motor generator is used as an electric motor, and the power generation control means that the motor generator is used as a generator.

  In the parallel HEV travel mode, the engine 12 and the first motor generator MG1 and the second motor generator MG2 can be traveled as a driving force source by connecting the starting clutch 26 and connecting the engine 12 to the driving force transmission path. There are three types of sub-modes. In the first sub-mode 1 (parallel HEV traveling mode in a narrow sense), the engine 12 is operated and the first motor generator MG1 is controlled by powering, whereby the engine 12 and the first motor generator MG1 are driven as a driving force source. The second motor generator MG2 is rotated freely with zero torque. Instead of the first motor generator MG1, the second motor generator MG2 may be subjected to power running control, or both the first motor generator MG1 and the second motor generator MG2 may be subjected to power running control to generate a driving force. . In the second sub-mode 2 (series parallel HEV travel mode), the engine 12 is operated and the second motor generator MG2 is controlled by powering, so that the engine 12 and the second motor generator MG2 are used as a driving force source. The first motor generator MG1 is controlled to generate electricity. The electric power obtained by the first motor generator MG1 is supplied to the second motor generator MG2 or used for charging the battery 60. In the sub mode 2, the first motor generator MG1 may be used as a driving force source by performing power running control, and the second motor generator MG2 may be controlled to generate power. The third sub-mode 3 (engine running mode) is a mode in which the engine 12 is operated to run using only the engine 12 as a driving force source. Both the first motor generator MG1 and the second motor generator MG2 are used. Torque is set to 0 and free rotation is performed.

  The sub mode 1 (parallel HEV travel mode in the narrow sense) can generate a larger driving force than the sub mode 3 (engine travel mode). For example, the acceleration operation amount θacc rapidly increases or the vehicle is driven at a high speed. When the first motor generator MG1 is power running controlled in an assistive manner, the sub mode 3 is quickly switched to the sub mode 1. Sub mode 2 (series parallel HEV running mode) is also performed in the same manner as sub mode 1, but sub mode 1 is executed when the SOC of battery 60 is relatively high, and sub mode 2 is set when the SOC is relatively low. Executed. In these parallel HEV travel modes, the forward / reverse switching device 22 switches between the forward drive state and the reverse drive state in accordance with the operation position of a shift lever (not shown).

  In addition, when the accelerator operation amount θacc is substantially 0 and the accelerator is decelerated, the decelerating mode is implemented. This decelerating running mode is generated while the engine 12 is disconnected from the driving force transmission path with the start clutch 26 disconnected and the second motor generator MG2 is controlled to generate power, thereby applying braking force to the vehicle with rotational resistance by power generation control. The battery 60 is charged with the electrical energy. Further, for example, another traveling mode may be provided such as charging the battery 60 by controlling the power generation of the first motor generator MG1 during engine traveling (submode 3).

  Returning to FIG. 1, the traveling mode switching means 72 travels by switching the plurality of types of traveling modes according to the mode switching conditions set by the mode switching condition setting means 74. As shown in FIG. 3, the mode switching condition is set in advance as a two-dimensional mode switching map using the required driving force such as the accelerator operation amount θacc and the vehicle speed V as parameters, and has a lower required driving force than the ES switching line. The EV region where the low vehicle speed side travels in the EV traveling mode, and the region between the SP1 to SP3 switching line and the ES switching line is the series HEV region which travels in the series HEV traveling mode, and the required driving force is higher than the SP1 to SP3 switching line. The high vehicle speed side is a parallel HEV region where the vehicle travels in the parallel HEV travel mode. These switching lines are provided with hysteresis in order to prevent frequent switching of the driving mode due to slight changes in vehicle speed or required driving force. The mode switching condition setting means 74 changes SP1-SP3 switching lines at the boundary between the series HEV region and the parallel HEV region according to the driver's intention, and executes signal processing according to the flowchart of FIG.

  In step S1 of FIG. 5, it is determined whether or not the driver's intention desires traveling with emphasis on power performance. Specifically, when the power mode is selected by the mode selection switch 56, it is determined that the user desires traveling with an emphasis on power performance. In addition, when the sequential mode or manual mode in which the gear ratio γ of the automatic transmission 20 can be switched manually is selected, or when the change rate (increase rate) of the accelerator operation amount θacc is large, the driving is performed. It is determined whether or not the user wants to travel with an emphasis on power performance from the driving state. Then, if it is determined that traveling with emphasis on power performance is desired, step S3 is executed, and an SP2 switching line indicated by a one-dot chain line in FIG. 3 is set.

  If the determination in step S1 is NO (ie, negative), that is, if the driver's intention does not desire traveling with emphasis on power performance, step S2 is executed, and whether or not the driver desires traveling with emphasis on fuel efficiency. Determine whether. Specifically, when the eco mode is selected by the mode selection switch 56, it is determined that the user wants to travel with an emphasis on fuel consumption. In addition, it is determined whether or not the driver wants to travel with an emphasis on fuel consumption from the driving state of the driver, such as the operating tendency of the accelerator pedal and the brake pedal, and acceleration / deceleration of the vehicle speed. Then, if it is determined that traveling with an emphasis on fuel efficiency is desired, step S4 is executed, and an SP3 switching line indicated by a dotted line in FIG. 3 is set. Further, if the determination in step S2 is NO, that is, if it cannot be determined that the driver's intention is to focus on both power performance and fuel efficiency, step S5 is executed, and normal (normal) indicated by a solid line in FIG. Value) SP1 switching line.

  Here, the SP2 switching line that is set when it is determined that traveling with emphasis on power performance is desired is the required driving force at which the series HEV traveling mode is selected as shown by the white arrow A in FIG. The upper limit of the range is made lower than that of the normal SP1 switching line, and the series HEV region is narrower than that of the SP1 switching line. When the series HEV region is narrowed to the low required driving force side in this way, the parallel HEV region capable of generating a larger driving force is expanded and the EV traveling mode is quickly shifted to the parallel HEV traveling mode. As a result, the dribbling performance when the accelerator pedal is depressed is improved.

  The SP2 switching line is substantially matched with the ES switching line in the intermediate vehicle speed range V1 to V2, the series HEV region is partially disappeared, and the EV region and the parallel EV region are in contact with each other. In this case, when shifting from the EV traveling mode to the parallel HEV traveling mode, for example, the engine 12 is cranked by the inertia of the output by adjusting the torque (engagement hydraulic pressure) of the start clutch 26, and the engine is performed by fuel injection and ignition. After starting 12, the start clutch 26 is completely engaged, whereby the parallel HEV travel mode can be quickly switched. On the vehicle speed side lower than the vehicle speed V1, since inertia from the output that can crank the engine 12 is not obtained, the series HEV region is left a little, and the required driving force increases to reach the series HEV region. Transition to the series HEV traveling mode is performed by normal engine start control in which the engine 12 is cranked and started by the first motor generator MG1. After that, when the SP2 switching line is exceeded, the engine 12 and the first motor generator MG1 perform synchronous control so that the front and rear rotations of the start clutch 26 substantially coincide with each other, and the start clutch 26 is connected to the parallel HEV travel mode. Migrate to Similarly to the vehicle speed side lower than the vehicle speed V1, the region on the higher vehicle speed side than the vehicle speed V2 shifts from the EV traveling mode to the series HEV traveling mode, and further shifts to the parallel HEV traveling mode step by step.

  On the other hand, the SP3 switching line that is set when it is determined that traveling with an emphasis on fuel efficiency is desired, as indicated by the white arrow B in FIG. 3, is within the range of the vehicle speed V in which the series HEV traveling mode is selected. The upper limit is set higher than that of the normal SP1 switching line, and the series HEV region is widened as compared with the case of the SP1 switching line. When the series HEV region is expanded to the high vehicle speed side in this way, the parallel HEV region is narrowed correspondingly, and fuel efficiency is improved. That is, in the series HEV travel mode, the engine 12 is operated to generate power with the first motor generator MG1, but the start clutch 26 is disconnected and the engine 12 is disconnected from the driving force transmission path. 12 can be operated at the most efficient driving point, whereas in the parallel HEV driving mode, the starting clutch 26 is connected and the operating point of the engine 12 is restricted according to the vehicle speed V or the like. It gets worse.

  As described above, in the vehicle hybrid drive device 10 of the present embodiment, the range in which the series HEV travel mode is selected is changed according to the driver's intention according to the mode switching condition, and thus matches the driver's intention. Drivability performance and fuel efficiency performance can be obtained.

  Specifically, when the driver desires driving with emphasis on power performance, the range in which the series HEV driving mode is selected is changed from the SP1 switching line at the normal time to the SP2 switching line, and is narrower than that at the normal time. As a result, the EV traveling mode quickly shifts to the parallel HEV traveling mode, the drivability is improved, and the driving force by the engine 12 can be obtained quickly after the engine is started, causing the driver to feel uncomfortable. I will not let you. In particular, since the upper limit of the range of required driving force in which the series HEV driving mode is selected is set lower than that in the normal state, the mode shifts to the parallel HEV driving mode with a smaller required driving force, that is, the accelerator operation amount θacc. Drive performance can be obtained.

  In addition, when the driver desires driving with an emphasis on fuel consumption, the range in which the series HEV driving mode is selected is changed from the SP1 switching line at the normal time to the SP3 switching line, and is wider than that at the normal time. The time and opportunity to travel in the series HEV travel mode are increased, the engine 12 can be operated at the optimum operating point without being affected by the vehicle speed V, and the fuel efficiency is improved. In particular, since the upper limit of the range of the vehicle speed V in which the series HEV travel mode is selected is set higher than that in the normal state, the parallel HEV travel mode region where the fuel efficiency is poor is reduced accordingly, and a further excellent fuel efficiency improvement effect is obtained.

  Next, another embodiment of the present invention will be described. In the following embodiments, parts that are substantially the same as those in the above embodiments are denoted by the same reference numerals, and detailed description thereof is omitted.

  FIG. 6 is a schematic configuration diagram illustrating another example of a vehicle hybrid drive device to which the present invention is preferably applied. The vehicle hybrid drive apparatus 100 is configured such that the engine 12 is cranked by a starter motor 102 connected to a crankshaft 14 via a belt or the like, and a plurality of clutches and brakes are disengaged. A stepped automatic transmission 104 such as a planetary gear type in which a plurality of shift stages and neutrals are established according to the state is provided, and power is transmitted between the input shaft 106 and the crankshaft 14 of the automatic transmission 104. A starting clutch 108 is provided for disconnecting the connection. The starter motor 102 corresponds to a first rotating machine, and is configured by a motor generator that also has a function as a generator. In this embodiment, the starting clutch 108 corresponds to a connecting / disconnecting device, but an automatic transmission 104 capable of neutral can be used as the connecting / disconnecting device. The first gear 25 is provided on the output shaft 110 of the automatic transmission 104, and the driving force is transmitted to the front drive wheels 40L and 40R. The second motor generator MG2 is not provided.

  On the other hand, this vehicle hybrid drive device 100 is provided with a rear wheel drive device 120, and by rotating and driving a differential gear device 126 through a fifth gear 122 and a sixth gear 124 by a rear motor generator RMG. The left and right rear drive wheels 130L and 130R are rotationally driven via the left and right axles 128L and 128R. The rear motor generator RMG corresponds to a second rotating machine.

  The vehicle hybrid drive apparatus 100 also includes hybrid control means 70 as in the vehicle hybrid drive apparatus 10 of the above-described embodiment. The vehicle hybrid drive apparatus 100 travels by switching between the various travel modes shown in FIG. The mode switching condition is changed by the setting means 74 according to the driver's intention according to the flowchart of FIG. In FIG. 4, the first motor generator MG1 is replaced with a starter motor 102, the second motor generator MG2 is replaced with a rear motor generator RMG, and the starting clutch 26 is replaced with a starting clutch 108. Also in the present embodiment, substantially the same effect as the above-described embodiment can be obtained.

  In the engine travel mode (sub-mode 3 of the parallel HEV travel mode), the rear drive wheels 130L and 130R can be driven to rotate by the rear motor generator RMG as necessary to travel in a four-wheel drive state. . Further, a connecting / disconnecting device such as a reduction gear or a clutch may be provided between the rear motor generator RMG and the fifth gear 122 as necessary. Further, as the driving device for driving the front wheels, a device obtained by removing the second motor generator MG2 from the above embodiment can be employed as it is.

  7A and 7B are diagrams for explaining still another example of a vehicle hybrid drive device to which the present invention is preferably applied. FIG. 7A is a schematic configuration diagram, and FIG. 7B is a diagram for explaining various travel modes. . In the vehicle hybrid drive device 150, the engine 12, the first clutch 152, the first motor generator MG1, the second clutch 154, and the second motor generator MG2 are connected in series on a common axis, and the second clutch An output gear 156 provided between 154 and the second motor generator MG2 is meshed with the fourth gear 34. Also in this hybrid drive device 150 for a vehicle, as shown in FIG. 7 (b), the EV travel mode, the series HEV travel mode, the parallel HEV travel mode having three sub modes, the deceleration, as in the above-described embodiment. Driving modes are possible, and the hybrid control means 70 switches between these driving modes and travels, and the mode switching condition setting means 74 changes the mode switching conditions according to the driver's intention according to the flowchart of FIG. . Also in the present embodiment, substantially the same effect as the above-described embodiment can be obtained.

  In this embodiment, since the vehicle cannot be moved backward in the engine travel mode (sub-mode 3 in the parallel HEV travel mode), the reverse travel is performed in the EV travel mode or the series HEV travel mode. The second clutch 154 that disconnects the engine 12 from the driving force transmission path in the EV traveling mode and the series HEV traveling mode functions as a connection / disconnection device.

  FIG. 8 is a diagram for explaining still another example of a vehicle hybrid drive apparatus to which the present invention is preferably applied. FIG. 8 (a) is a schematic configuration diagram, and FIG. 8 (b) is a diagram for explaining various travel modes. . The vehicle hybrid drive device 160 is connected to an engine 12, a first motor generator MG1, a second motor generator MG2, and an output gear 164 via a planetary gear device 162, and the engine 12 and the first motor generator MG1 are connected to each other. The first clutch 166 is provided between the first motor generator MG1 and the ring gear of the planetary gear unit 162 via the second clutch 168. The ring gear is fixed by a brake 170 so as not to rotate. The second motor generator MG <b> 2 is connected to the sun gear of the planetary gear device 162, the output gear 164 is connected to the carrier, and the output gear 164 is meshed with the second gear 28.

  In this vehicle hybrid drive device 160, as shown in FIG. 8 (b), the EV travel mode, the series HEV travel mode, the parallel HEV travel mode, and the deceleration travel mode are possible as in the above embodiment. The hybrid control means 70 travels by switching these travel modes, and the mode switching condition setting means 74 changes the mode switching conditions according to the driver's intention according to the flowchart of FIG. Also in the present embodiment, substantially the same effect as the above-described embodiment can be obtained.

  In FIG. 8 (b), in the EV traveling mode, the brake 170 is fixed and the second motor generator MG2 is controlled to perform power running. However, the brake 170 is released and the second clutch 168 is connected to the first motor generator. It is also possible to travel with both MG1 and second motor generator MG2 under power running control. In the parallel HEV travel mode, two sub modes are possible, and the upper sub mode 1 is a narrow parallel HEV travel mode, and travels using both the engine 12 and the second motor generator MG2 as driving force sources. The lower sub mode 2 is a series parallel HEV running mode, and in the sub mode 1, the first motor generator MG1 is controlled to generate power. The reverse travel may be performed in the EV travel mode or the series HEV travel mode. The second clutch 168 that disconnects the engine 12 from the driving force transmission path in the EV traveling mode and the series HEV traveling mode functions as a connection / disconnection device.

  As mentioned above, although the Example of this invention was described in detail based on drawing, these are one Embodiment to the last, This invention is implemented in the aspect which added the various change and improvement based on the knowledge of those skilled in the art. be able to.

  10, 100, 150, 160: Vehicle hybrid drive device 12: Engine 50: Electronic control device 74: Mode switching condition setting means 102: Starter motor (first rotating machine) MG1: First motor generator (first rotating machine) MG2: second motor generator (second rotating machine) RMG: rear motor generator (second rotating machine)

Claims (7)

An EV travel mode in which the engine is separated from the driving force transmission path and travels using only the second rotating machine as a driving force source, and the first rotating machine is rotationally driven by the engine separated from the driving force transmission path while generating electric power. A series HEV travel mode in which only the second rotating machine can be used as a driving force source, and the engine is connected to a driving force transmission path to connect the engine and at least one of the first rotating machine and the second rotating machine. In the hybrid drive device for a vehicle, a parallel HEV travel mode that can be traveled using as a drive force source is selected according to a mode switching condition determined based on at least one of a required drive force and a vehicle speed.
The mode switching condition is that the range in which the EV driving mode is selected, the range in which the parallel HEV driving mode is selected, and the range in which the series HEV driving mode is selected are at least one of the required driving force and the vehicle speed. Based on different scopes,
Vehicular hybrid drive unit, characterized in that the range of the series HEV mode in accordance with the mode changeover condition is selected is changed according to the intention of the driver. The range in which the series HEV driving mode is selected is changed according to the driver's intention without changing the range in which the EV driving mode is selected.
The hybrid drive device for a vehicle according to claim 1, wherein: The mode switching condition is determined so that the series HEV driving mode is selected in an intermediate range between a range in which the EV driving mode is selected and a range in which the parallel HEV driving mode is selected.
The hybrid drive device for a vehicle according to claim 1, wherein the hybrid drive device is for a vehicle. When the driver wants to travel with an emphasis on power performance, than usual according to any one of claims 1 to 3, characterized in that the series HEV drive mode is narrowed range selected Hybrid drive device for vehicles. The mode switching condition is determined based on at least the required driving force, and is set so that the series HEV driving mode and the parallel HEV driving mode are selected from the EV driving mode as the required driving force increases. And
When the driver wants to travel with an emphasis on power performance, according to claim 4, characterized in that the upper limit of the range of the required driving force, wherein the series HEV drive mode is selected is lower than the normal Hybrid drive device for vehicles. If desiring running the driver with emphasis on fuel economy, than usual according to any one of claim 1 to 5, characterized in that the series HEV drive mode is wider range selected Hybrid drive device for vehicles. Wherein the mode switching condition is determined based on at least the vehicle speed, the series HEV mode from the EV drive mode in accordance with the increase of vehicle speed, that the parallel HEV drive mode is set to be selected The hybrid drive device for a vehicle according to claim 6 , wherein the vehicle is a hybrid drive device.

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