JP5395115B2 - Hybrid drive device - Google Patents

Description

  The present invention relates to a hybrid drive device that combines an engine, a motor / generator, and a transmission.

  Conventionally, there has been known a hybrid drive device in which an engine, a motor / generator, and a gear-type multi-stage transmission are combined with the aim of improving engine startability and power generation efficiency (see, for example, Patent Document 1).

  The hybrid drive apparatus described in FIG. 1 of Patent Document 1 drives an engine output shaft via a first one-way clutch by a motor / generator decelerated by a planetary gear. In addition, torque is exchanged between the hollow transmission input shaft of the gear type multi-stage transmission and the output of the motor / generator via a planetary gear and a second one-way clutch.

JP 2004-74990 A

  However, the conventional hybrid drive apparatus has a structure in which the output of the motor / generator is transmitted to the engine via a drive shaft built in the input shaft of a hollow transmission. As a result, the torque transmission path between the engine and the motor / generator becomes longer, the transmission input shaft has a hollow structure, and the drive shaft, which is the engine output shaft, and the transmission input shaft have a concentric biaxial structure. There is a need. As a result, there is a problem that the cost is increased.

  The present invention has been made paying attention to the above problem, and an object of the present invention is to provide a hybrid drive apparatus that can suppress an increase in cost.

In order to achieve the above object, the hybrid drive device of the present invention provides:
Engine,
A transmission capable of switching a plurality of transmission ratios between an input shaft and an output shaft;
A clutch for connecting and disconnecting torque transmission between the crankshaft of the engine and the input shaft;
A motor / generator having a rotor and a stator for power running and regeneration;
It is assumed that
In this hybrid drive device,
The crankshaft and the input shaft are arranged in series via the clutch.
The motor / generator is disposed on the transmission side with respect to the clutch.
The rotor shaft of the rotor protrudes from both ends of the rotor and is arranged in parallel with the crankshaft and the input shaft.
A first rotor shaft end projecting toward the engine side of the rotor shaft and a crankshaft of the engine are drivingly connected to each other by a first gear train and a first clutch.
Of the rotor shaft, a second rotor shaft end portion projecting to the opposite side of the first rotor shaft end portion and the input shaft are connected to be connected to each other by a second gear train and a second clutch. .

Thus, among the rotor shafts of the motor / generator, the end portion of the first rotor shaft on the engine side is drivingly connected to the crankshaft of the engine with the first gear train and the first clutch, and the side opposite to the engine side The second rotor shaft end projecting inward and the input shaft of the transmission are drivably connected by a second gear train and a second clutch. For this reason, the torque of the motor / generator is transmitted to the engine without passing the drive shaft of the engine to the opposite side of the engine through the input shaft of the hollow transmission as in the configuration of the prior art. And the torque transmission path can be shortened. This eliminates the need for a concentric biaxial structure for the drive shaft, which is the engine output shaft, and the hollow cylindrical transmission input shaft, thereby suppressing an increase in cost.
In the present invention, when the kinetic energy of the vehicle is recovered as regenerative energy, the input shaft of the transmission and the motor / generator are drivingly connected by the second gear train. The torque transmitted through the input shaft is input to the motor / generator. Therefore, if the transmission gear ratio is controlled during regeneration, the rotational speed of the motor / generator can be controlled according to the vehicle speed, and a planetary gear or the like for changing the rotational speed in the torque transmission path is not provided. In addition, the efficiency at the time of regeneration of the motor / generator can be improved.
As a result, the efficiency of the motor / generator during regeneration can be improved without causing an increase in cost.

1 is an overall configuration diagram illustrating a drive system of an FF hybrid vehicle to which a hybrid drive device according to a first embodiment is applied. FIG. 2 is a view in the direction of arrow A in FIG. 1 illustrating a first gear train in the hybrid drive device of the first embodiment. FIG. 3 is a view in the direction of arrow B in FIG. 1 illustrating a second gear train in the hybrid drive device of the first embodiment. It is the schematic which shows an example of the starting clutch used for the hybrid drive device of Example 1. FIG. FIG. 3 is a schematic diagram illustrating an example of a shift actuator used in the hybrid drive device according to the first embodiment. FIG. 6 is an operation explanatory diagram showing a mode control operation when the first one-way clutch is engaged in the hybrid drive device of the first embodiment. It is an effect explanatory view showing a mode control action at the time of the 2nd one-way clutch fastening in the hybrid drive device of Example 1. It is a whole block diagram which shows the drive system of FF hybrid vehicle to which the hybrid drive device of Example 2 was applied.

  Hereinafter, the best mode for realizing a hybrid drive device of the present invention will be described based on Example 1 and Example 2 shown in the drawings.

First, the configuration will be described.
FIG. 1 shows a drive system of an FF hybrid vehicle to which the hybrid drive apparatus of the first embodiment is applied. 2 and 3 show the first gear train and the second gear train in the hybrid drive apparatus of the first embodiment. The overall configuration of the hybrid drive system will be described below with reference to FIGS.

  As shown in FIG. 1, the drive system to which the hybrid drive device of the first embodiment is applied includes an engine 1, a geared multi-stage transmission 2 (transmission), a starting clutch 3 (clutch), and a motor / generator 4. A first gear train 5, a second gear train 6, a first one-way clutch 7 (first clutch), a second one-way clutch 8 (second clutch), a final reduction gear train 9, and a differential gear 10 A left drive shaft 11, a right drive shaft 12, a left front wheel 13, and a right front wheel 14.

  The engine 1 is an internal combustion engine such as a gasoline engine or a diesel engine, and performs engine start control, throttle valve opening control, fuel cut control, and the like based on an engine control command from an engine controller (not shown). . A flywheel 16 is provided on the crankshaft 15 of the engine 1.

  The gear-type multi-stage transmission 2 is a transmission called a single clutch type automatic MT that automatically switches a plurality of shift stages according to a vehicle speed, an accelerator opening, and the like. In the first embodiment, a hydraulic-less multi-stage transmission that has five forward speeds and one reverse speed and that performs shift control by a motor actuator without using a hydraulic actuator is employed. The gear-type multi-stage transmission 2 is also called a parallel two-shaft multi-stage transmission, and is a transmission input shaft 21 (input shaft) arranged coaxially with the crankshaft 15 and a transmission output arranged parallel to the transmission input shaft 21. A shaft 22 (output shaft).

  The transmission input shaft 21 has a first speed gear 21a, a third speed gear 21b, a second speed gear 21c, a fourth speed gear 21d, a fifth speed gear 21e, and a reverse gear 21f, and each gear 21a, 21b, 21c, 21d, 21e and 21f are provided integrally with the transmission input shaft 21 or fixed integrally with the transmission input shaft 21.

  The transmission output shaft 22 includes a first speed selection gear 22a, a third speed selection gear 22b, a second speed selection gear 22c, a fourth speed selection gear 22d, a fifth speed selection gear 22e, and a reverse selection gear 22f. Accordingly, the fixing to the transmission output shaft 22 is selected.

  The first gear to fifth gear 21a, 21b, 21c, 21d, 21e and the first gear selection gear to fifth gear selection gear 22a, 22b, 22c, 22d, 22e always have a pair of gears combined for each gear. It is in meshing state. However, the reverse gear 21f and the reverse selection gear 22f are engaged with each other via a reverse counter gear 23 for reversing the rotation direction (see FIG. 3). Each of the first to reverse gears is selected by a gear selection device 24.

  The gear selection device 24 includes a 1-3 dog clutch mechanism 24a, a 1-3 shift fork 24b, a 2-4 dog clutch mechanism 24c, a 2-4 shift fork 24d, a 5-R dog clutch mechanism 24e, 5- And an R shift fork 24f.

  The 1-3 dog clutch mechanism 24a and the 1-3 shift fork 24b are set at positions between the first speed selection gear 22a and the third speed selection gear 22b, and the transmission output of the first speed selection gear 22a or the third speed selection gear 22b. The fixing to the shaft 22 is selected by meshing.

  The 2-4 dog clutch mechanism 24c and the 2-4 shift fork 24d are set at a position between the 2nd speed selection gear 22c and the 4th speed selection gear 22d, and the transmission output of the 2nd speed selection gear 22c or the 4th speed selection gear 22d. The fixing to the shaft 22 is selected by meshing.

  The 5-R dog clutch mechanism 24e and the 5-R shift fork 24f are set at a position between the 5-speed selection gear 22e and the reverse selection gear 22f, and the transmission output shaft 22 of the 5-speed selection gear 22e or the reverse selection gear 22f. Select to fix to.

  The starting clutch 3 is a dry friction clutch that is interposed between the crankshaft 15 and the transmission input shaft 21 and connects and disconnects torque transmission between the crankshaft 15 and the transmission input shaft 21. The starting clutch 3 is controlled to be engaged and disengaged based on a control command from a shift controller (not shown) to the motor actuator. The crankshaft 15 and the transmission input shaft 21 are arranged in series via the start clutch 3. In this case, in series, the axis of the transmission input shaft 21 exists along the direction in which the axis of the crankshaft 15 extends, and the end surface of the crankshaft 15 and the end surface of the transmission input shaft 21 face each other. The crankshaft 15 and the transmission input shaft 21 do not need to be coaxial.

  The motor / generator 4 is a synchronous motor / generator having a rotor shaft 41, a rotor 42 having a permanent magnet embedded therein, and a stator 43 around which a stator coil is wound. The motor / generator 4 can operate as an electric motor that is driven to rotate by receiving power supplied from a battery (not shown) (hereinafter, this operation state is referred to as “powering”), and the rotor 42 is connected to the engine 1 or the left and right sides. When receiving rotational energy from the front wheels 13, 14, it functions as a generator that generates electromotive force at both ends of the stator coil, and can charge the battery (hereinafter, this operation state is referred to as “regeneration”). A rotor shaft 41 extending in both axial directions from the motor / generator 4 is arranged in parallel to the crankshaft 15 and the transmission input shaft 21.

  The first gear train 5 is a gear train that drives and connects the engine-side first rotor shaft end 41 a of the rotor shaft 41 and the crankshaft 15 of the engine 1. As shown in FIGS. 1 and 2, the first gear train 5 is fixed to the first motor gear 51 fixed to the first rotor shaft end 41 a and the crankshaft 15 from the engine 1. And an engine crank gear 52 that meshes with the engine crank gear 52.

  The second gear train 6 extends in the crankshaft direction from the second rotor shaft end portion 41 b on the transmission input shaft side of the rotor shaft 41 and the rear end portion of the transmission input shaft 21, that is, from the engine 1. Of the transmission input shaft 21, a gear train that connects and drives an end located on the side far from the engine 1. As shown in FIGS. 1 and 3, the second gear train 6 is disposed in the last train of each speed gear disposed on the transmission input shaft 21, and is reverse gear 21 f (synchronized with the transmission input shaft 21). A rear counter gear 23 that meshes with the reverse gear 21f, a second motor gear 61 that is fixed to the second rotor shaft end 41b, and an additional counter shaft 63 that is fixed to the second motor gear 61 and the reverse counter. And an additional counter gear 62 that meshes with the gear 23 simultaneously.

  The first one-way clutch 7 is interposed between the first rotor shaft end portion 41a and the first motor gear 51 of the first gear train 5, and includes an inner race and an outer race (not shown). The inner race is fixed to the first rotor shaft end portion 41a, and is a clutch that is fastened by mechanical engagement only when the rotational speed of the inner race is greater than or equal to the rotational speed of the outer race (hereinafter simply referred to as “ It is described as “a clutch that is fastened by mechanical engagement only when the motor rotational speed is equal to or higher than the engine rotational speed”. The first one-way clutch 7 is disengaged mechanically when the inner race rotational speed is less than the outer race rotational speed, and idles. Thereby, only torque from the motor / generator 4 side to the engine 1 side is transmitted in torque transmission between the motor / generator 4 and the engine 1.

  The second one-way clutch 8 is interposed between the second rotor shaft end portion 41b and the second motor gear 61 of the second gear train 6, and includes an outer race and an inner race (not shown). The inner race is fixed to the second rotor shaft end 41b. In this case, a clutch that is fastened by mechanical engagement only when the outer race rotation speed is greater than or equal to the inner race rotation speed (hereinafter simply referred to as “when the transmission input shaft rotation speed is equal to or higher than the motor rotation speed). And a clutch that is fastened by mechanical engagement only. It should be noted that the second one-way clutch 8 is disengaged mechanically and idles when the rotational speed of the outer race is less than the rotational speed of the inner race. Thereby, in the torque transmission between the gear type multi-stage transmission 2 and the motor / generator 4, only the torque from the gear type multi-stage transmission 2 side to the motor / generator 4 side is transmitted.

  The final reduction gear train 9 includes a transmission output gear 91 provided at an end position of the transmission output shaft 22, a drive output reduction gear 92 that meshes with the transmission output gear 91 and rotates the differential case of the differential gear 10. , A gear train having The drive output to the differential case of the differential gear 10 is equally distributed to the left and right, transmitted to the left front wheel 13 via the left drive shaft 11, and transmitted to the right front wheel 14 via the right drive shaft 12.

FIG. 4 shows an example of the starting clutch 3 used in the hybrid drive device of the first embodiment. Hereinafter, a schematic configuration of the starting clutch 3 will be described with reference to FIG.
As shown in FIG. 4, the starting clutch 3 includes a clutch plate 31, an engine-side pressure plate 32, and a transmission-side pressure plate 34.

  The clutch plate 31 is splined to the end position of the transmission input shaft 21. And it is interposed between a fixed engine side pressure plate 32 that is spline-fitted to the crankshaft 15 and a transmission side pressure plate 34 that is movable in the axial direction. That is, among the three plates 31, 32, 34, the clutch releasing state is achieved by releasing the fastening force from the transmission-side pressure plate 34. Then, a clutch fastening state is established by applying a fastening force from the transmission-side pressure plate 34 and closing the gap to integrate the three plates 31, 32, 34.

  The motor actuator that applies the fastening force to the starting clutch 3 is an actuator that is driven without using any hydraulic pressure, and includes a motor 35, a ball screw 36, a spring 37, a roller 38, and an engagement lever 39. Configured. That is, when the ball screw 36 is moved by the motor 35, the roller 38 serving as a fulcrum of the engagement lever 39 moves in the vertical direction in FIG. By this fulcrum movement of the engagement lever 39, a fastening force based on a biasing force by the spring 37 is applied to the first pressure plate 33 and the second pressure plate. As described above, since the output from the motor 35 is not used as the fastening force, there is an advantage that the fastening force can be sufficiently applied to the starting clutch 3 even with a small motor output.

FIG. 5 shows an example of a shift actuator used in the hybrid drive device of the first embodiment. The schematic configuration of the shift actuator will be described below with reference to FIG.
The shift actuator moves the 1-3 shift fork 24b, the 2-4 shift fork 24d, and the 5-R shift fork 24f in the axial direction in accordance with the position of the selected gear position. 26.

  The cylindrical drum 25 has a 1-3 shift cam groove 25a for guiding the axial movement of the 1-3 shift fork 24b, a 2-4 shift cam groove 25b for guiding the axial movement of the 2-4 shift fork 24d, and 5 A 5-R shift cam groove 25c for guiding the axial movement of the -R shift fork 24f is formed along the cylindrical surface.

  The motor mechanism 26 decelerates the DC motor 27 and rotates the cylindrical drum 25 in accordance with the selected gear position. With the rotation of the cylindrical drum 25, each shift cam groove 25a is switched so that the 1-3 shift fork 24b, the 2-4 shift fork 24d, and the 5-R shift fork 24f are switched from the speed stage before selection to the speed stage after selection. , 25b, 25c along the axial direction. As described above, since the three shift forks 24b, 24d, and 24f are driven by one motor mechanism 26, there is an advantage that the configuration of the shift actuator can be simplified.

Next, the operation will be described.
The operation of the hybrid drive device of the first embodiment is divided into “simplification operation of the hybrid drive structure”, “mode control operation when the first one-way clutch is engaged”, and “mode control operation when the second one-way clutch is engaged”. To do.

[Simplification of hybrid drive structure]
The hybrid drive device needs to have a configuration that not only has two drive sources but also switches the torque transmission path in accordance with various travel modes. For this reason, it is necessary to devise how to simplify the hybrid drive structure, which is inevitable to increase in complexity and size. Hereinafter, the simplification action of the hybrid drive structure reflecting this will be described.

  First, a hybrid drive device described in FIG. 1 of Japanese Patent Application Laid-Open No. 2004-74990 is used as a comparative example. In this comparative example, the transmission input shaft of the gear type multi-stage transmission is used as a hollow transmission input shaft, and the engine output shaft is extended from the inside of the hollow transmission input shaft to the end of the gear type multi-stage transmission. The rotor shaft of the motor / generator and the rear end portion of the engine output shaft are drivingly connected via a first one-way clutch, a first gear train, and a planetary gear. Further, the rotor shaft of the motor / generator and the second-speed drive gear provided in the middle of the hollow transmission input shaft are drivingly connected to the second one-way clutch via the gear.

  With the above configuration, in the comparative example, the engine output shaft is driven via the first one-way clutch by the motor / generator decelerated by the planetary gear. In addition, torque is exchanged between the hollow transmission input shaft of the gear-type multi-stage transmission and the output of the motor / generator via a second-speed drive gear and a second one-way clutch.

  However, in the comparative example, a structure is employed in which the output of the motor / generator is transmitted to the engine output shaft via the planetary gear. For this reason, the planetary gear space is required, the engine output shaft and the hollow transmission input shaft need to have a concentric two-shaft structure, and the planetary gear needs pinion lubrication, and the structure is complicated. And size increase. As a result, if the engine / starting clutch / gear-type multi-stage transmission mounted on the drive system of the engine vehicle is used as a base and it is intended to be a hybrid drive device, the scale of modification will increase and the cost will increase. The physique of the multi-stage transmission is also increased.

  On the other hand, in the first embodiment, when the engine 1, the starting clutch 3 and the gear type multi-stage transmission 2 mounted in the drive system of the engine vehicle are used as a base, and this is to be made into a hybrid drive device, 1 in FIG. As indicated by the dotted chain C, only the motor / generator 4, the first gear train 5, a part of the second gear train 6, the first one-way clutch 7, and the second one-way clutch 8 are added. Just do it.

  That is, the first rotor shaft end portion 41a of the motor / generator 4 and the crankshaft 15 are drive-coupled by the first gear train 5 (the first motor gear 51, the engine crank gear 52) and the first one-way clutch 7 so that they can be connected and disconnected. . Then, the second rotor shaft end 41b of the motor / generator 4 and the transmission input shaft 21 are connected to the second gear train 6 (reverse gear 21f, reverse counter gear 23, second motor gear 61, additional counter gear 62) and the second gear train 6. The hybrid drive device can be achieved by connecting the two one-way clutches 8 so that they can be connected and disconnected. Of the second gear train 6, the reverse gear 21f and the reverse counter gear 23 constitute a reverse gear, so that the gear can be shared as an intermediate gear for inter-shaft adjustment.

  Therefore, the scale of modification is extremely small compared to the comparative example that requires the addition of a planetary gear, the cost increase is suppressed, and the transmission input shaft does not need to have a hollow shaft structure as in the comparative example. The physique of the gear type multi-stage transmission 2 does not increase.

  Further, the first rotor shaft end portion 41 a which is one end portion of the rotor shaft 41 of the motor / generator 4 is drivingly connected to the crankshaft 15 of the engine 1. On the other hand, the second rotor shaft end portion 41 b which is the other end portion of the rotor shaft 41 is drivingly connected to the reverse counter gear 23 of the gear type multi-stage transmission 2. That is, the span from one end portion to the other end portion of the rotor shaft 41 is equal to the axial length of the transmission input shaft 21 of the gear type multi-stage transmission 2 or more than the axial length of the transmission input shaft 21. Length is secured.

  Therefore, the motor / generator 4 arranged in parallel with the crankshaft 15 and the transmission input shaft 21 can be a motor / generator 4 having an elongated structure. For this reason, the rotor diameter of the motor / generator 4 can be reduced, and the motor inertia (a value proportional to the fourth power of the rotor diameter), which becomes a load when the engine is driven, can be kept small.

As described above, in the first embodiment, the rotor shaft 41 of the motor / generator 4 is arranged in parallel with the crankshaft 15 and the transmission input shaft 21. Then, the first rotor shaft end portion 41a and the crankshaft 15 are drive-coupled by the first gear train 5 and the first one-way clutch 7 so that they can be connected and disconnected. The reverse gear 21f disposed in the last row of the second rotor shaft end 41b and the transmission input shaft 21 is replaced with the second gear train 6 (reverse gear 21f, reverse counter gear 23, second motor gear 61, additional counter gear 62). And the second one-way clutch 8 is connected to be connected to be connectable.
As a result, the motor inertia that is a load when the engine is driven can be suppressed to a low level without causing an increase in cost.

In the first embodiment, the reverse gear 21f is used as a rear end gear that is arranged in the last row of the transmission input shaft 21 of the gear type multi-stage transmission 2 and rotates synchronously with the transmission input shaft 21.
As shown in FIG. 3, the reverse gear 21 f is a gear that meshes with the reverse selection gear 22 f via the reverse counter gear 23, and the gear shaft of the reverse counter gear 23 is higher than that of the transmission input shaft 21. Can be placed on the side. For this reason, the tooth surface of the reverse counter gear 23 protrudes to the motor / generator 4 side. Therefore, even if the distance between the rotor shaft 41 to which the torque is transmitted and the transmission input shaft 21 is large and it is difficult to transmit the torque with a set of gear trains, the reverse gear 21f is used as the rear end gear. The configuration to be added to the second gear train 6 by transmitting the torque to the motor / generator 4 via the reverse counter gear 23 using only the combination of the second motor gear 61 and the small gear of the additional counter gear 62 is only Become.
That is, in the configuration of the first embodiment, the motor / generator 4 has two operation states of power running and regeneration, such as starting the engine 1 and recovering kinetic energy during traveling, but depending on the traveling state, Since the operating state shifts from power running to regeneration and from regeneration to power running, both rotation directions are required to be the same. As described above, when the intermediate shaft is provided in order to adjust the distance between the rotor shaft 41 and the transmission input shaft 21 while adjusting the rotation direction of the motor / generator during power running and regeneration, the intermediate shaft is Two will be needed.
On the other hand, in the first embodiment, the reverse counter shaft 23 is used as the intermediate shaft. Therefore, only one additional counter shaft 63 and an additional counter gear 62 are added to the existing configuration. The direction of rotation of the motor / generator 4 during regeneration can be adjusted. In other words, when the power running of the motor / generator 4 and the rotation direction of regeneration are matched, even if the space between the shafts is widened and an intermediate shaft is required, the newly added intermediate shaft can be reduced.

In the first embodiment, in the gear type multi-stage transmission 2, as a clutch mechanism for selectively changing a torque transmission path with a shift, a dog clutch mechanism (1-3 dog clutch mechanism 24a, 2-4 dog clutch mechanism 24c, 5- A configuration using an R dog clutch mechanism 24e) was adopted.
For example, the most common mechanism as a clutch mechanism that selectively changes a torque transmission path with a shift is a synchro mechanism having a rotation synchronization function. However, the synchro mechanism has a complicated structure and a long axial dimension. On the other hand, by providing the motor / generator 4 with a rotation synchronization function, a simple mesh clutch mechanism, a simple structure, and a dog clutch mechanism with a short axial dimension are provided.
As described above, since the synchro mechanism is abolished and the dog clutch is used, the axial dimension of the gear type multi-stage transmission 2 can be shortened.

[Mode control action when the first one-way clutch is engaged]
In the hybrid drive device of Example 1, the first one-way clutch 7 is interposed at one end of the rotor shaft 41 of the motor / generator 4 and the second one-way clutch 8 is interposed at the other end. Hereinafter, the mode control operation when the first one-way clutch is engaged will be described.

  When the motor / generator 4 performs motor control (torque control, rotational speed control) by powering, as shown in FIG. 6, the motor rotational speed becomes equal to or higher than the engine rotational speed, the first one-way clutch 7 is engaged, and the second one-way is engaged. The clutch 8 idles. As typical control modes when the first one-way clutch 7 is engaged, there are “engine start mode”, “power assist mode”, and “downshift mode”. Hereinafter, the control action in each mode will be described.

* Engine start mode For example, immediately after boarding or after idle stop control, an engine start mode for starting the stopped engine 1 is executed. When the engine is started, the starting clutch 3 is released and the motor / generator 4 is controlled by the motor (rotational speed control).
The power running energy from the rotor shaft 41 of the motor / generator 4 by this motor control is transmitted from the first one-way clutch 7 → the first motor gear 51 → the engine crank gear 52 → the crankshaft 15, and engine cranking that rotates the engine 1 is performed. Done. When the predetermined engine speed is reached, the engine 1 is started by performing fuel injection and ignition.
That is, the motor / generator 4 exhibits the engine starter motor function and can start the engine 1.

* Power assist mode For example, when starting or during intermediate acceleration, a power assist mode for assisting the driving force of the engine 1 with the driving force of the motor / generator 4 is executed. At the time of this power assist, the motor / generator 4 is motor-controlled (torque control) while the start clutch 3 is kept engaged.
The power running energy from the rotor shaft 41 of the motor / generator 4 by this motor control is transmitted from the first one-way clutch 7 → the first motor gear 51 → the engine crank gear 52 → the crankshaft 15, and the driving force from the engine 1 is Driving force from the motor / generator 4 is applied. The combined driving force passes through the starting clutch 3 and is transmitted to the transmission input shaft 21. From the gear of the selected gear stage, the transmission output shaft 22 → the final reduction gear train 9 → It is transmitted to the differential gear 10. Further, the drive output transmitted to the differential case of the differential gear 10 is equally distributed to the left and right, is transmitted to the left front wheel 13 via the left drive shaft 11, and is transmitted to the right front wheel 14 via the right drive shaft 12. .
That is, the motor / generator 4 can exhibit a power assist function for assisting the driving force of the engine 1 and can increase the driving force from the driving source.

* Downshift mode For example, when a downshift command is output across the downshift line of the shift map during traveling, the downshift mode is executed. At the time of this downshift, first, based on the downshift command, the start clutch 3 is released, and at the same time, the dog clutch engaged in the gear position before the downshift is removed. When the dog clutch reaches the neutral position, the starting clutch 3 is engaged, and motor control (rotational speed control) of the motor / generator 4 is started.
The power running energy from the rotor shaft 41 of the motor / generator 4 by this motor control is transmitted to the first one-way clutch 7 → the first motor gear 51 → the engine crank gear 52 → the crankshaft 15 → the starting clutch 3 → the transmission input shaft 21. Is done. Then, the motor / generator 4 performs rotation synchronization control for increasing the rotation speeds of the crankshaft 15 and the transmission input shaft 21 to the specified rotation speed after the downshift. When the rotation synchronization is completed, the dog clutch corresponding to the gear position after the downshift is engaged. In addition, since the inertia of the motor / generator 4 is suppressed to be small, the rotation synchronization that raises to the specified rotation speed after the downshift is instantaneously performed.
That is, the motor / generator 4 exhibits a function of synchronously controlling the number of revolutions during downshifting, and downshifting can be performed with a good shift quality without shock or delay while using a dog clutch mechanism.

[Mode control action when the second one-way clutch is engaged]
In the hybrid drive device of Example 1, the first one-way clutch 7 is interposed at one end of the rotor shaft 41 of the motor / generator 4 and the second one-way clutch 8 is interposed at the other end. Hereinafter, the mode control action when the second one-way clutch is engaged will be described.

  When the motor / generator 4 performs generator control by regeneration (torque control, rotational speed control), as shown in FIG. 7, the transmission input shaft rotational speed becomes equal to or higher than the motor rotational speed, the second one-way clutch 8 is engaged, The first one-way clutch 7 idles. Typical control modes when the second one-way clutch 8 is engaged include “engine energy regeneration mode”, “coast energy regeneration mode”, and “upshift mode”. Hereinafter, the control action in each mode will be described.

* Engine energy regeneration mode For example, the engine energy regeneration mode is executed when the battery charge capacity decreases during traveling and the battery needs to be charged using a part of the engine energy. During the regeneration of the engine energy, the motor / generator 4 is subjected to generator control (torque control) while the start clutch 3 is kept engaged.
Therefore, a part of the energy from the crankshaft 15 of the engine 1 is generated by the starting clutch 3 → the transmission input shaft 21 → the reverse gear 21f → the reverse counter gear 23 → the additional counter gear 62 → the second motor gear 61 → the second one-way clutch 8 → Transmitted to the rotor shaft 41. Then, the motor / generator 4 takes a part of the engine energy as regenerative energy, and charges the electric power obtained by the power generation by the motor / generator 4 as battery charging power.
That is, the motor / generator 4 exhibits an engine energy regeneration function that takes in part of the engine energy as regenerative energy, and the battery can be charged as necessary during traveling.

* Coast energy regeneration mode For example, the coast energy regeneration mode is executed when the vehicle decelerates by an accelerator release operation or when the vehicle decelerates and stops. At the time of coast energy regeneration, the starting clutch 3 is released and the motor / generator 4 is subjected to generator control (torque control).
Therefore, the energy from the left and right front wheels 13 and 14 is changed from the drive shafts 11 and 12 to the differential gear 10 → the final reduction gear train 9 → the transmission output shaft 22 → the meshing gear at the selected stage → the transmission input shaft 21 → the reverse gear 21f. → Reverse counter gear 23 → additional counter gear 62 → second motor gear 61 → second one-way clutch 8 → rotor shaft 41 Then, the motor / generator 4 takes in the energy from the left and right front wheels 13 and 14 by coasting as regenerative energy, and charges the electric power obtained by the power generation by the motor / generator 4 as battery charging power.
That is, the motor / generator 4 exhibits a coast energy regeneration function that takes in the energy from the left and right front wheels 13 and 14 by coast traveling as regeneration energy, and the battery can be charged during coast traveling. Further, during coast energy regeneration, torque is transmitted from the transmission output shaft 22 via the transmission input shaft 21, so that the rotation of the motor / generator 4 during regeneration is controlled by controlling the gear position according to the vehicle speed. The speed can be controlled, and the power generation efficiency of the motor / generator 4 can be improved.

* Upshift mode For example, during a run, the upshift mode is executed when an upshift command is output across the upshift line of the shift map. At the time of this upshift, first, based on the upshift command, the starting clutch 3 is released, and at the same time, the dog clutch engaged in the gear position before the upshift is removed. When the dog clutch reaches the neutral position, the starting clutch 3 is engaged, and generator control (rotational speed control) of the motor / generator 4 is started.
By this generator control, a brake torque due to a power generation load acts on the rotor shaft 41 of the motor / generator 4. The brake torque of the rotor shaft 41 is transmitted to the second one-way clutch 8 → the second motor gear 61 → the additional counter gear 62 → the reverse counter gear 23 → the reverse gear 21 f → the transmission input shaft 21 → the starting clutch 3 → the crankshaft 15. Is done. Then, rotation synchronization control is performed to reduce the rotation speed of the crankshaft 15 and the transmission input shaft 21 to the specified rotation speed after the upshift by the brake torque of the rotor shaft 41 of the motor / generator 4. When the rotation synchronization is completed, the dog clutch corresponding to the speed stage after the upshift is engaged. Note that since the inertia of the motor / generator 4 is kept small, the rotation synchronization is reduced instantaneously to the specified rotational speed after the upshift.
In other words, the motor / generator 4 exhibits a function of synchronous control of the number of revolutions during upshifting, and upshifting can be performed with good shift quality with no shock or delay while using the dog clutch mechanism.

Next, the effect will be described.
In the hybrid drive device according to the first embodiment, the effects listed below can be obtained.

(1) Engine 1 and
A transmission (gear-type multi-stage transmission 2) capable of switching a plurality of transmission ratios between an input shaft (transmission input shaft 21) and an output shaft (transmission output shaft 22);
A clutch (starting clutch 3) for connecting and disconnecting torque transmission between the crankshaft 15 of the engine 1 and the input shaft (transmission input shaft 21);
A motor / generator 4 having a rotor 42 and a stator 43 and performing power running and regeneration;
In a hybrid drive device with
The crankshaft 15 and the input shaft (transmission input shaft 21) are arranged in series via the clutch (start clutch 3),
The motor / generator 4 is disposed on the transmission (gear-type multi-stage transmission 2) side with respect to the clutch (starting clutch 3),
The rotor shaft 41 of the rotor 42 protrudes from both ends of the rotor 42 and is arranged in parallel with the crankshaft 15 and the input shaft (transmission input shaft 21).
The first rotor shaft end 41a of the rotor shaft 41 projecting toward the engine 1 side and the crankshaft 15 of the engine 1 are disconnected by the first gear train 5 and the first clutch (first one-way clutch 7). The drive connection is possible
The second gear train 6 includes a second rotor shaft end 41b that protrudes on the opposite side of the rotor shaft 41 from the first rotor shaft end 41a, and the input shaft (transmission input shaft 21). The second clutch (second one-way clutch 8) was driven and connected to be able to be connected and disconnected.
For this reason, the efficiency of the motor / generator 4 at the time of regeneration can be improved without causing an increase in cost.

(2) The transmission is a gear-type multi-stage transmission 2 capable of switching a plurality of shift stages between the input shaft (transmission input shaft 21) and the output shaft (transmission output shaft 22). ,
The first gear train 5 is
A first motor gear 51 disposed at the first rotor shaft end 41a;
An engine crank gear 52 that is disposed on the crankshaft 15 and meshes with the first motor gear 51,
The second gear train 6 is
A second motor gear 61 disposed at the second rotor shaft end 41b;
Of the plurality of gears 21 a, 21 b, 21 c, 21 d, 21 e, 21 f disposed on the input shaft (transmission input shaft 21), the second motor gear 61 is disposed at a position farthest from the engine 1. And a rear end gear (reverse gear 21f) that meshes with the rear end.
For this reason, in addition to the effect of (1), the motor / generator 4 can have an elongated configuration corresponding to the axial length of the gear-type multi-stage transmission 2, and as a result, space is not increased and the engine is driven. The motor inertia which becomes a load can be suppressed small.

(3) The gear-type multi-stage transmission 2 is a clutch mechanism that selectively changes a torque transmission path between the input shaft (transmission input shaft 21) and the output shaft (transmission output shaft 22) as the gear shifts. The dog clutch mechanism (1-3 dog clutch mechanism 24a, 2-4 dog clutch mechanism 24c, 5-R dog clutch mechanism 24e) is used.
For this reason, in addition to the effect of (1) or (2), the synchro mechanism is abolished and the dog clutch is formed by a simple meshing mechanism, so that the axial dimension of the gear type multi-stage transmission 2 can be shortened. it can.

(4) The first clutch is interposed between the first rotor shaft end 41a and the first motor gear 51, and is engaged only when torque is transmitted from the motor / generator 4 to the engine 1. The first one-way clutch 7
The second clutch is interposed between the second rotor shaft end portion 41 b and the second motor gear 61, and torque is transmitted from the input shaft (transmission input shaft 21) to the motor / generator 4. This is the second one-way clutch 8 that is engaged only occasionally.
For this reason, in addition to the effects (1) to (3), the first one-way clutch 7 is automatically engaged when the motor / generator 4 is powered, and the second one-way clutch 8 is automatically engaged when the motor / generator 4 is regenerated. By engaging, clutch control is omitted when various mode controls are performed, and the mode control can be simplified.

(5) The first gear train 5 is
An engine crank gear 52 disposed on the crankshaft 15;
A first motor gear 51 disposed at the first rotor shaft end 41a and meshing with the engine crank gear 52;
The second gear train 6 is
A reverse gear 21f disposed on the input shaft (transmission input shaft 21) and rotating synchronously with the input shaft;
A reverse counter gear 23 that meshes with the reverse gear 21f and transmits torque input to the input shaft (transmission input shaft 21) to the output shaft (transmission output shaft 22) by changing the rotation direction;
An additional counter gear 62 meshing with the reverse counter gear 23;
The second motor gear 61 is arranged at the second rotor shaft end portion 41 b and meshes with the additional counter gear 62.
For this reason, in addition to the effects of (3) and (4), the motor / motor can be obtained by adding only one additional counter gear 62 with the configuration in which the reverse gear 21f and the reverse counter gear 23 are part of the second gear train 6. The power running of the generator 4 and the rotation direction of regeneration can be matched.

(6) The reverse gear 21f is arranged at a position farthest from the engine 1 among the plurality of gears 21a, 21b, 21c, 21d, 21e, 21f arranged on the input shaft (transmission input shaft 21). Rear end gear.
Therefore, in addition to the effect of (5), the reverse gear 21f and the reverse counter gear 23 are used as a part of the second gear train 6, and the motor / generator 4 is connected to the shaft of the transmission (gear-type multistage transmission 2). By arranging along the direction, it is possible to configure the hybrid drive device while minimizing the number of parts and space increase from the existing engine 1 + transmission (gear-type multi-stage transmission 2).

  The second embodiment is an example in which a counter shaft provided with a shift gear is additionally disposed between the transmission input shaft and the transmission output shaft, and the drive shaft is connected between the counter shaft and the motor / generator.

First, the configuration will be described.
FIG. 8 shows a drive system of an FF hybrid vehicle to which the hybrid drive device of the second embodiment is applied. Hereinafter, the overall configuration of the hybrid drive system will be described with reference to FIG.

  As shown in FIG. 8, the drive system to which the hybrid drive device of the second embodiment is applied includes an engine 1, a geared multi-stage transmission 2 (transmission), a starting clutch 3 (clutch), and a motor / generator 4. A first gear train 5, a second gear train 6, a first one-way clutch 7 (first clutch), a second one-way clutch 8 (second clutch), a final reduction gear train 9, and a differential gear 10 A left drive shaft 11, a right drive shaft 12, a left front wheel 13, and a right front wheel 14.

Differences in configuration from the first embodiment shown in FIG. 1 will be described.
(a) The transmission input shaft 21 in FIG. 1 is divided into a transmission input shaft 21 and a counter shaft 64 that are parallel to each other, and the transmission input shaft 21 and the counter shaft 64 are connected by drive transmission gears 28 and 29. That point.
Along with this shaft division, the gears 21a, 21b, 21c, 21d, 21e, 21f for shifting are provided on the counter shaft 64.
(b) The additional counter gear 62 of FIG. 1 is eliminated, and the reverse counter gear 23 ′ provided on the reverse counter shaft 65 is configured to mesh with the second motor gear 61, the reverse gear 21f, and the reverse selection gear 22f, respectively.

That is, in the second embodiment, the second gear train 6 is composed of three gears, that is, the reverse gear 21f, the reverse counter gear 23 ′, and the second motor gear 61.
Since other configurations are the same as those of the first embodiment, the corresponding components are denoted by the same reference numerals and description thereof is omitted.

Next, the operation will be described.
In the gear type multi-stage transmission of the second embodiment that transmits the torque input to the transmission input shaft 21 to the transmission output shaft 22 via the counter shaft 64, the reverse gear 21f provided on the counter shaft 64, Torque from the counter shaft 64 is transmitted to the motor / generator 4 via the reverse counter gear 23 ′ engaged with the reverse gear 21 f.
As described above, in the second embodiment, since the rotation direction is changed once from the transmission input shaft 21 to the counter shaft 64, the use of the reverse counter gear 23 'eliminates the need for the additional counter gear 62 of the first embodiment. Become.
For this reason, even if the distance between the transmission input shaft 21 and the rotor shaft 41 becomes large, the second gear train 6 that makes the rotation direction of the motor / generator 4 the same during power running and regeneration is replaced with a new intermediate gear. Without adding a shaft, it can be configured while avoiding cost increase.
Since other operations are the same as those of the first embodiment, description thereof is omitted.

Next, the effect will be described.
In the hybrid drive device according to the second embodiment, the following effects can be obtained.

(7) Engine 1 and
A gear capable of transmitting torque input to the input shaft (transmission input shaft 21) to the counter shaft 64 and switching a plurality of shift stages between the counter shaft 64 and the output shaft (transmission output shaft 22). Type multi-stage transmission 2,
A clutch (starting clutch 3) for connecting and disconnecting torque transmission between the crankshaft 15 of the engine 1 and the input shaft (transmission input shaft 21);
A motor / generator 4 having a rotor 42 and a stator 43 and performing power running and regeneration;
In a hybrid drive device with
The crankshaft 15 and the input shaft (transmission input shaft 21) are arranged in series via the clutch (start clutch 3),
The motor / generator 4 is arranged on the gear-type multi-stage transmission 2 side with respect to the clutch (starting clutch 3),
The rotor shaft 41 of the rotor 42 protrudes from both ends of the rotor 42 and is arranged in parallel with the crankshaft 15 and the counter shaft 64.
The first rotor shaft end 41a of the rotor shaft 41 projecting toward the engine 1 side and the crankshaft 15 of the engine 1 are disconnected by the first gear train 5 and the first clutch (first one-way clutch 7). The drive connection is possible
Of the rotor shaft 41, a second rotor shaft end portion 41b that protrudes on the opposite side to the first rotor shaft end portion 41a, and an end portion of the counter shaft 64 that is located on the opposite side to the engine 1 side Are connected to each other by a second gear train 6 and a second clutch (second one-way clutch 8) such that they can be connected and disconnected.
For this reason, the efficiency of the motor / generator 4 at the time of regeneration can be improved without incurring an increase in cost, and the second gear train 6 (with the same rotational direction of the motor / generator 4 at the time of power running and regeneration) ( The reverse gear 21f, the reverse counter gear 23 ′, and the second motor gear 61) can be configured without using the additional counter gear 62.

  As mentioned above, although the hybrid drive device of the present invention has been described based on the first and second embodiments, the specific configuration is not limited to these embodiments, and the invention according to each claim of the claims Design changes and additions are permitted without departing from the gist of the present invention.

  In the first embodiment, as the transmission, forward movement is achieved by two axes of the transmission input shaft 21 and the transmission output shaft 22, and reverse movement is achieved by the transmission input shaft 21, the reverse counter shaft, and the transmission output shaft 22. The example using the gear type multi-stage transmission 2 having the forward fifth speed / first reverse speed is shown. However, if the gear-type multi-stage transmission is capable of switching between a plurality of shift speeds, the specific shift speed is not limited to the fifth forward speed / first reverse speed of the first embodiment. Furthermore, instead of these gear-type multi-stage transmissions, for example, a belt-type continuously variable transmission can be applied. In this case, the input shaft opposite to the engine across the primary pulley may be drivingly connected to the rotor shaft of the motor / generator by the second gear train.

  In the first and second embodiments, an example in which a dog clutch mechanism by meshing is used as a clutch mechanism that selectively changes the torque transmission path in accordance with the shift of the gear type multi-stage transmission 2 has been described. However, the clutch mechanism may be an example using a known synchro mechanism. Furthermore, a cone clutch mechanism that suppresses a sudden torque drop by meshing with the tapered surface may be used.

  In the first and second embodiments, an example in which a motor actuator suitable for reducing hydraulic pressure is used as the gear selection operation actuator of the gear type multi-stage transmission 2 has been described. However, another actuator such as an electromagnetic actuator or a hydraulic actuator may be used as the gear selection actuator.

  In the first and second embodiments, an example in which a motor actuator suitable for reducing hydraulic pressure is used as the clutch connection / disconnection operation actuator of the start clutch 3 has been described. However, other actuators such as an electromagnetic actuator and a hydraulic actuator may be used as the clutch connection / disconnection operation actuator. The start clutch type may be a dry type or a wet type, and may be a single plate type or a multi-plate type. In addition to the starting clutch, a torque converter as a starting element is provided between the engine and the transmission, and the lock-up clutch provided in the torque converter is used as a clutch for connecting and disconnecting torque transmission between the crankshaft and the input shaft. It can also be applied.

  In the first and second embodiments, the first one-way clutch 7 is used as the first clutch, and the second one-way clutch 8 is used as the second clutch. However, as the first clutch or the second clutch, an electromagnetic clutch, a hydraulic clutch, or the like that is connected / disconnected by an external command may be used.

  In the first and second embodiments, the reverse gear 21f is used as the rear end gear. However, any gear other than the reverse gear may be used as long as it is arranged in the last row of the transmission input shaft of the gear type multi-stage transmission and rotates synchronously with the transmission input shaft. In the first embodiment, the second gear train 6 is composed of four gears. However, when the distance between the input shaft and the rotor shaft is somewhat short, the additional counter gear 62 is added without using the reverse counter gear 23. Instead, it may be constituted by two of a reverse gear and a second motor gear.

  In the first and second embodiments, the example in which the hybrid drive device of the present invention is applied to the drive system of the FF hybrid vehicle is shown. However, the hybrid drive device of the present invention can also be applied to a drive system of an FR hybrid vehicle, a drive system of a 4WD hybrid vehicle, and the like.

1 Engine 15 Crankshaft 2 Gear type multi-stage transmission (transmission)
21 Transmission input shaft (input shaft)
22 Transmission output shaft (output shaft)
24a 1-3 dog clutch mechanism (dog clutch mechanism)
24c 2-4 dog clutch mechanism (dog clutch mechanism)
24e 5-R dog clutch mechanism (dog clutch mechanism)
28, 29 Drive transmission gear 3 Start clutch (clutch)
4 Motor / generator 41 Rotor shaft 41a First rotor shaft end portion 41b Second rotor shaft end portion 42 Rotor 43 Stator 5 First gear train 51 First motor gear 52 Engine crank gear 6 Second gear train 21f Reverse gear (rear gear) )
23, 23 'Reverse counter gear 61 Second motor gear 62 Additional counter gear 64 Counter shaft 65 Reverse counter shaft 7 First one-way clutch (first clutch)
8 Second one-way clutch (second clutch)

Claims (7)

Engine,
A transmission capable of switching a plurality of transmission ratios between an input shaft and an output shaft;
A clutch for connecting and disconnecting torque transmission between the crankshaft of the engine and the input shaft;
A motor / generator having a rotor and a stator for power running and regeneration;
In a hybrid drive device with
The crankshaft and the input shaft are arranged in series via the clutch,
The motor / generator is disposed on the transmission side with respect to the clutch,
The rotor shaft of the rotor protrudes from both ends of the rotor, and is arranged in parallel with the crankshaft and the input shaft.
A first rotor shaft end projecting to the engine side of the rotor shaft and a crankshaft of the engine are connected to be connected to and disconnected by a first gear train and a first clutch;
Of the rotor shaft, a second rotor shaft end portion projecting to the opposite side of the first rotor shaft end portion and the input shaft are connected to be connected to each other by a second gear train and a second clutch. A hybrid drive device characterized by that. In the hybrid drive device according to claim 1,
The transmission is a gear-type multi-stage transmission capable of switching a plurality of shift stages between the input shaft and the output shaft,
The first gear train is
A first motor gear disposed at an end of the first rotor shaft;
An engine crank gear arranged on the crankshaft and meshing with the first motor gear,
The second gear train is
A second motor gear disposed at the end of the second rotor shaft;
A hybrid drive apparatus comprising: a rear end gear that is arranged at a position farthest from the engine among a plurality of gears arranged on the input shaft and meshes with the second motor gear. In the hybrid drive device according to claim 2,
The gear type multi-stage transmission uses a dog clutch mechanism by meshing as a clutch mechanism that selectively changes a torque transmission path between the input shaft and the output shaft in accordance with a shift. In the hybrid drive device according to any one of claims 1 to 3,
The first clutch is a first one-way clutch that is interposed between the first rotor shaft end and the first motor gear and that is engaged only when torque is transmitted from the motor / generator to the engine. ,
The second clutch is a second one-way clutch that is interposed between the second rotor shaft end and the second motor gear and that is engaged only when torque is transmitted from the input shaft to the motor / generator. A hybrid drive device characterized by that. In the hybrid drive device according to any one of claims 3 to 4,
The first gear train is
An engine crank gear disposed on the crankshaft;
A first motor gear arranged at the first rotor shaft end and meshing with the engine crank gear;
The second gear train is
A reverse gear disposed on the input shaft and rotating synchronously with the input shaft;
A reverse counter gear that meshes with the reverse gear and transmits torque input to the input shaft to the output shaft by changing the rotation direction;
An additional counter gear meshing with the reverse counter gear;
A hybrid drive device comprising: a second motor gear arranged at the end of the second rotor shaft and meshing with the additional counter gear. In the hybrid drive device according to claim 5,
The reverse gear is a rear end gear arranged at a position farthest from the engine among a plurality of gears arranged on the input shaft. Engine,
A gear-type multi-stage transmission that transmits torque input to the input shaft to the counter shaft and is capable of switching a plurality of shift speeds between the counter shaft and the output shaft;
A clutch for connecting and disconnecting torque transmission between the crankshaft of the engine and the input shaft;
A motor / generator having a rotor and a stator for power running and regeneration;
In a hybrid drive device with
The crankshaft and the input shaft are arranged in series via the clutch,
The motor / generator is disposed on the gear-type multi-stage transmission side with respect to the clutch,
The rotor shaft of the rotor protrudes from both ends of the rotor, and is arranged in parallel to the crankshaft and the countershaft,
A first rotor shaft end projecting to the engine side of the rotor shaft and a crankshaft of the engine are connected to be connected to and disconnected by a first gear train and a first clutch;
Of the rotor shaft, a second rotor shaft end portion that protrudes on the opposite side to the first rotor shaft end portion, and an end portion of the counter shaft that is located on the opposite side to the engine side are provided with a second gear. A hybrid drive device characterized in that it is drive-coupled so as to be able to be connected and disconnected by a row and a second clutch.