JP2013112318A - Drive device for automobile - Google Patents

Abstract

PROBLEM TO BE SOLVED: To drive two M/Gs simultaneously when a hybrid automobile runs as an electric automobile to do with M/Gs of smaller capacity.SOLUTION: A drive device for an automobile includes an input shaft 10, an output shaft 12, a power splitting planetary gear set which consists of a first planetary gear 20 having three rotary elements of a first sun gear 22, a first ring gear 24, and a first carrier 28, and permits power splitting, a first motor generator 56, and a second motor generator 58, wherein the input shaft 10 is connected to the first ring gear 24 or can be connected thereto, the output shaft 12 is connected to the first carrier 28, the first motor generator 56 is connected to the first sun gear 22, and the second motor generator 58 can be connected to the first carrier 28 via a mechanical connecting/releasing means 70 and to the first ring gear 24 via a first clutch 60.

Description

  The present invention relates to a drive device for a so-called hybrid vehicle having two types of power sources, that is, an internal combustion engine and an electric motor, and in particular, can transmit power input from the engine to an output shaft via a planetary gear, and a plurality of motors. It is related with the drive device for motor vehicles provided with.

  Conventionally, as this type of automobile drive device, there is known an example in which two motor generators (hereinafter referred to as M / G) and two planetary gear sets are provided, and hybrid drive is performed as an electric continuously variable transmission. (For example, refer to Patent Document 1).

US Pat. No. 6,478,705

  However, in the above-described conventional automobile drive device that includes two motor generators (hereinafter referred to as M / G), two planetary gear sets, and hybrid drive as an electric continuously variable transmission, a battery When only the electric power stored in the vehicle is used as a power source and the vehicle is driven in the same way as an electric vehicle, it can be driven by only one M / G and has two M / Gs. Regardless, there was a problem that both M / Gs could not be used effectively and a strong driving force could not be obtained.

The problem to be solved is that when only the electric power of the battery is used as a power source to drive the same as an electric vehicle, it can be driven by only one M / G, and thus exhibits a large driving force. Requires a large capacity M / G.
It is an object of the present invention to provide a hybrid vehicle with two M / Gs, which can be driven using two M / Gs simultaneously when traveling as an electric vehicle, thereby reducing the capacity. The purpose is to enable application of M / G.

The automobile drive device of the present invention is composed of a first planetary gear having three rotation elements: an input shaft capable of receiving power from the engine, an output shaft, a first sun gear, a first ring gear, and a first carrier. A power split planetary gear set capable of power split, a first motor generator, and a second motor generator, and the input shaft is connected to or connectable to the first ring gear, and the output shaft Is connected to the first carrier, the first motor / generator is connected to the first sun gear, and the second motor / generator is connected to the first carrier via the mechanical connection / release means and the first clutch via the first clutch. Each ring gear can be connected to each other.

The automobile drive device of the present invention can be simultaneously driven with two M / Gs in an electric vehicle (EV) traveling using only a battery as a power source while being for a hybrid vehicle (HV). Therefore, it is possible to reduce the total capacity of the two M / Gs, and to obtain a merit in terms of cost, weight, and size.

It is the skeleton figure which showed the principal part of the drive device for motor vehicles based on Example 1 of this invention. It is an expanded sectional view of the A section of FIG. It is the expanded sectional view cut | disconnected along the BB line of FIG. It is sectional drawing cut | disconnected along the HH line | wire of FIG. It is a figure which shows the operation | movement table | surface in the drive device for motor vehicles of Example 1. FIG. It is the skeleton figure which showed the principal part of the drive device for motor vehicles based on Example 2 of this invention. It is the skeleton figure which showed the principal part of the drive device for motor vehicles based on Example 3 of this invention. It is a figure which shows the operation | movement table | surface in the drive device for motor vehicles of Example 3. FIG. It is the skeleton figure which showed the principal part of the drive device for motor vehicles based on Example 4 of this invention. It is a figure which shows the operation | movement table | surface in the drive device for motor vehicles of Example 4. FIG. It is the skeleton figure which showed the principal part of the drive device for motor vehicles based on Example 5 of this invention. It is a figure which shows the action | operation table | surface in the drive device for motor vehicles of Example 5. FIG.

  DESCRIPTION OF EMBODIMENTS Hereinafter, an automobile drive device according to an embodiment of the present invention will be described with reference to the drawings based on each example.

FIG. 1 is a skeleton diagram of the main part of the automobile drive apparatus according to Embodiment 1 of the present invention.
The vehicle drive apparatus according to the first embodiment includes an input shaft 10 driven from the engine 1 and an output shaft 12 provided coaxially with the input shaft 10. The output shaft 12 drives the wheels of an automobile via a differential device (not shown).
Between the input shaft 10 and the output shaft 12, there are arranged three planetary gear sets, a first planetary gear set 20, a second planetary gear set 30, and a third planetary gear set 40. The first planetary gear set 20, the second planetary gear set 30, and the third planetary gear set 40 are all generally called single pinion types, and have the same configuration.

In other words, the first planetary gear set 20 includes a first carrier that rotatably supports a first sun gear 22, a first ring gear 24, and a plurality of first pinions 26 that mesh with the first sun gear 22 and the first ring gear 24. 28, and constitutes a power split planetary gear set of the present invention.
The second planetary gear set 30 includes a second carrier that rotatably supports a second sun gear 32, a second ring gear 34, and a plurality of second pinions 36 engaged with the second sun gear 32 and the second ring gear 34. 38, and constitutes the input transmission gear group of the present invention.
Similarly, the third planetary gear set 40 includes a third carrier that rotatably supports a third sun gear 42, a third ring gear 44, and a plurality of third pinions 46 that mesh with the third sun gear 42 and the third ring gear 44. 48 and three rotational elements, and constitutes the reduction gear of the present invention.

Next, the connection relationship between each of the rotating elements and other rotating members will be described.
The input shaft 10 is connected to the second carrier 38.
The second sun gear 32 can be fixed to the case (stationary portion) 52 by the brake 50 and can be connected to the second ring gear 34 only in one rotational direction by the first one-way clutch 54. The second ring gear 34 is connected to the first ring gear 24.

The first one-way clutch 54 is configured to lock (engage) the second sun gear 32 relative to the first ring gear 24 in the same direction as the rotational direction of the engine 1. In this embodiment, a well-known mechanical type is used, but it is also possible to use a hydraulic multi-plate clutch that is controlled to be engaged / released.
Accordingly, when the second carrier 38 connected to the input shaft 10 is driven by the engine 1 and the brake 50 is released and the second sun gear 32 tries to rotate in the same direction as the rotational direction of the engine 1, the first one-way clutch 54 The second planetary gear set 30 is integrated with the first ring gear 24.

On the contrary, when the second ring gear 34 tries to rotate in the direction opposite to the rotation direction of the engine 1, the first one-way clutch 54 is engaged with the second sun gear 32 and the second planetary gear 34 is engaged. The gear set 30 is integrated.
Further, the first one-way clutch 54 is not limited to the above, and the same function can be achieved if it is provided between the second carrier 38 and the second sun gear 32 or between the second carrier 38 and the second sun gear 32. it can.

The first sun gear 22 is connected to the first M / G 56.
The first carrier 28 is connected to the output shaft 12 and can be connected to the third carrier 48 as described later.
The third sun gear 42 is fixed to the case 52, and the third ring gear is connected to the second M / G 58.
Accordingly, the output torque of the second M / G 58 is always decelerated by the third planetary gear set 40 and is output from the third carrier 48, and in the opposite case, the torque input from the third carrier 48 is used to output the third planetary gear set 40. The second M / G 58 is driven to generate electric power.

The third carrier 38 and the first carrier 28 are connected to each other only in one rotation direction via the second one-way clutch 74, and can be connected regardless of the rotation direction by the engagement of the sleeve 70 and the dog clutch 28c. .
The sleeve 70 and the dog clutch 28c constitute the mechanical connection / release means of the present invention.
The sleeve 70 can be moved in the axial direction by a fork (not shown).
Therefore, when the output shaft 12 is driven from the third carrier 48 through the first carrier 28 by being decelerated by the third planetary gear set 40 with the torque of the second M / G 58, the second one-way clutch 74 is used during forward movement, which will be described later. When the vehicle is moving backward, it is driven through a sleeve 70 and a dog clutch 28c that are engaged with each other.

Here, the operation for releasing the engagement between the sleeve 70 and the dog clutch 28c will be described with reference to FIGS.
In the following description, the rotation in the same direction as the rotation direction of the engine 1 is defined as “forward rotation” and the opposite is defined as “reverse rotation”.

In general, when mechanical engagement is provided in parallel with the one-way clutch, a large force is required to release the mechanical engagement, and an impact may occur at the moment when the engagement is released.
That is, the torque acting between the target members (between the third carrier 48 and the first carrier 28 in this embodiment) is transmitted by the one-way clutch (second one-way clutch 74 in this embodiment) in one rotational direction, In the direction of rotation of the one-way clutch and the mechanical clutch (in this embodiment, the sleeve 70 and the dog clutch 28c), even if there is no torque acting between the target members after the mechanical engagement is transmitted, Torque remains between both meshes.

For this reason, when releasing the mechanical engagement, it is necessary to remove it against the residual torque. The following description is a configuration and operation for facilitating the release.
2 is an enlarged view showing a cross section of a portion A in FIG. 1, and FIG. 3 is an enlarged view showing a cross section taken along the line BB in FIG. 4 is a cross-sectional view taken along the line CC in FIG.

In FIG. 2, the first carrier 28 is formed with an outer peripheral surface 28b with which the sprag 74a of the second one-way clutch 74 contacts, and a dog clutch 28c with which the spline 70a of the sleeve 70 meshes.
The sleeve 70 moves to the right in the axial direction from the position shown in FIG. 2, so that the splines 70 a and 28 c are engaged with each other. The tips 70b and 28d of both the splines 70a and 28c are inclined.

The second one-way clutch 74 has a plurality of sprags 74 a that act as wedges between the outer peripheral surface 28 b of the first carrier 28 and the outer ring 74 b, and the first carrier 28 rotates forward with respect to the third carrier 48. Is free, but reverse rotation is prevented by the wedge action of the sprag 74a.
That is, when the third carrier 48 drives the first carrier 28 in the forward rotation direction, torque is transmitted by a wedge action, and when the first carrier 28 rotates forward at a higher speed than the third carrier 48, the wedge action is released. And become free.
As shown in FIGS. 2 and 3, the spline teeth 74 c formed on the outer side of the outer ring 74 b are engaged with the spline grooves 48 c formed on the third carrier 48. A spring 72 is inserted between the spline teeth 74c and the spline groove 48c, and there is a play of a rotation amount indicated by “D” in the rotation direction.

  The spring 72 is a leaf spring. The spring 72 has a ring shape in which the ring portion 72a shown in FIG. 2 corresponds to the outer ring 74b. The outer peripheral portion 72b enters the radial gap between the spline groove 52c and the spline teeth 74c from the radially outermost portion of the ring portion 72a and is bent radially inward from one end side portion of the outer peripheral portion 72b as shown in FIG. The tongue portion 72c is formed so as to press the spline teeth 74c in the rotation direction in the direction in which the play of the rotation amount D is packed against the wall surface of the spline groove 52c.

  Therefore, the spline teeth 74c are moved toward the left side (counterclockwise direction) of the spline groove 52c by the elasticity of the tongue portion 72c. When the second one-way clutch 74 drives the first carrier 28, the tongue 72c is bent and the play D is packed.

When the splines 70a and 28c shown in FIG. 4 are engaged, there is a slight play (gap) between the first carrier 28 and the third carrier 48 in the rotational direction. In this case, the first carrier 28 and the third carrier 48 are slightly rotated. This rotation amount is defined as “G” as a value corresponding to the rotation amount D described above.
When the torque is applied between the first carrier 28 and the third carrier 48 in the state where both of them are engaged, and the torque is in the forward rotation direction, the second one-way clutch 74 transmits the torque and the rotation direction is in the reverse rotation direction. Cancels the wedge action.

For this reason, after the torque in the forward rotation direction acts and the second one-way clutch 74 transmits the torque by the wedge action, the first carrier 28 is maximized in the forward rotation direction to release the engagement between the sleeve 70 and the dog clutch 28c. If the rotation is rotated by the rotation amount G, the meshing can be smoothly released.
Therefore, by setting the rotation amount D to be larger than the rotation amount G, it is sufficient if there is enough force to overcome the elastic force of the tongue portion 72c when the engagement between the sleeve 70 and the dog clutch 28c is released. I don't get up.

Next, the operation of the automobile drive device shown in FIG. 1 will be described with reference to the operation table shown in FIG.
In the operation table of FIG. 5, a traveling mode and each driving mode to be described are assigned in the vertical direction, and fastening elements such as a brake and M / G are assigned in the horizontal direction. That is, the clutch 60 is “C”, the brake 50 is “B”, the sleeve 70 is “S”, the first one-way clutch 54 is “OWC1”, the second one-way clutch 74 is “OWC2”, and the first M / G 56 is “M”. / G1 "and the second M / G58 were" M / G2 ".

  In the table, ◯ indicates engagement / engagement in the engagement element such as the clutch 60, and in 1M / G56 and 2M / G58, it indicates driving, and △ indicates 1M / G56 and 2M. / G58 represents power generation. In addition, the sign “−” in the first M / G 56 and the second M / G 58 indicates that the stop is possible.

Although not shown, the automobile drive device shown in FIG. 1 is provided with a hydraulic pump, a battery, various sensors, a controller, an actuator, and the like as necessary in order to operate it. Based on the instructions.
Further, the gear ratio of each planetary gear set (the number of teeth of the sun gear / the number of teeth of the ring gear) is α1 for the first planetary gear set 20, α2 for the second planetary gear set 30, and the third planetary gear. In the gear set 40, α3 is set.
Therefore, the transmission ratio between the third ring gear 44 connected to the second M / G 58 and the third carrier 48 (the rotational speed of the third ring gear 44 / the rotational speed of the third carrier) is (1 + α3). And

First, EV travel that runs as an electric vehicle (EV) using only the electric power stored in the battery as a power source will be described.
There are five types of EV driving modes: forward E-1 mode to E-4 mode and reverse ER mode.
The E-1 mode is driving using only the second M / G 58. That is, the third sun gear 42 is fixed to the case 52, and the third carrier 48 is connected to the first carrier 28 by the wedge action of the second one-way clutch 74, so that the output shaft 12 is driven to decelerate.
The output torque To in this case is T2 · I where the torque of the second M / G 58 is T2. At this time, the first M / G 56 can be stopped.

Next, the E-2 mode is performed by engaging the brake 50 and automatically engaging the first one-way clutch 54. As a result, the second planetary gear set 30 is integrally fixed to the case 52, so that the first M / G 56 drives the output shaft 12 at a reduced speed via the first planetary gear set 20.
The output torque To in this case is T1 (1 + α1) / α1 when the torque of the first M / G 56 is T1. At this time, since the engagement of the second one-way clutch 74 is automatically released, the second M / G 58 can be stopped.

  Next, the E-3 mode is driven by engaging the brake 50 and automatically engaging the second one-way clutch 74. In this case, the first one-way clutch 54 is also automatically engaged, and the driving is a combination of the E-1 mode and the E-2 mode. Therefore, the output torque To in this case is T1 (1 + α1) / α1 + T2 · I.

Next, in the E-4 mode, the brake 50 is released and the clutch 60 is engaged to drive.
As a result, the second M / G 58 is connected to the first ring gear 24 via the third planetary gear set 40, so that the output shaft 12 is driven in a coordinated manner by the first M / G 56 and the second M / G 58. Become. In this case, the output torque To is T1 + T2 · I.
Therefore, the E-1 mode to E-3 mode, which are all driven at a reduced speed, are suitable for low to medium speed travel, and the E-4 mode is suitable for high speed travel. In particular, the E-1 mode to the E-3 mode can be freely switched and driven according to the traveling load of the automobile.
Further, in the E-1 mode to the E-3 mode, when the capacities of the first M / G 56 and the second M / G 58 are different from each other, there are three types of capacities in total, that is, driving each independently and driving both at the same time. Since the vehicle can be decelerated by M / G, the optimum drive mode can be selected according to the driving load of the automobile.

Next, the ER mode in which the vehicle travels backward by EV traveling will be described.
In the ER mode, the third carrier 48 and the first carrier 28 are connected by engaging the sleeve 70 and the dog clutch 28c, so that the reverse drive by the second M / G 58 is possible.
The output shaft torque in the ER mode is the same as that in the E-1 mode although the rotation direction is different.

  Next, the operation of driving the vehicle without driving either the first M / G 56 or the second M / G 58 while the engine 1 is stopped during forward travel, or generating power to brake the vehicle will be described. . This travel is described in the EB column of the operation table.

The EB traveling has the same fastening relationship as that in the E-4 mode, and generates power in both the first M / G 56 and the second M / G 58. The output shaft torque in this case is the same as that in the E-4 mode, although there is a difference between power generation and drive. The B-1 mode covers a wide range of travel from high speed to low speed, and the braking force control is also highly flexible.
The electric power generated by the EB traveling is stored in a battery and used for the next acceleration or the like, thereby performing so-called energy regeneration to reduce the power consumption of the automobile.

Next, a description will be given of the HV traveling that starts the engine 1 and travels as a hybrid vehicle (HV) that travels by using the engine 1 and one of the first M / G 56 and the second M / G 58 together.
HV traveling is used for general traveling when the battery charge is low, acceleration or climbing that requires a large driving force that cannot be obtained by EV traveling, and high-speed traveling.

First, the start of the engine 1 will be described.
When starting the engine 1 while the automobile is stopped or traveling at a low speed, the brake 50 is engaged, and then power is supplied to the first M / G 56 to reversely rotate. As a result, the first ring gear 24 and the second ring gear 34 are rotated forward by the action of the first planetary gear set 20, the second carrier 38 is driven to decelerate by the action of the second planetary gear set 30, and the engine 1 connected thereto is operated. It rotates forward. Therefore, the engine 1 is started by a general method such as fuel supply or ignition operation.
During the start of the engine 1, the reverse rotation direction torque acts on the first carrier 28 by the drive by the first M / G 56. In order to prevent the reverse movement of the automobile due to this, the forward rotation direction torque is output to the second M / G 58. Let
Of course, the engine 1 can be started by the drive by the first M / G 56 during the forward drive in the E-1 mode by the drive of the second M / G 58.

  Further, when starting the engine 1 while the automobile is traveling at the speed equal to or higher than a constant speed, the second ring gear 34 is rotating in the forward direction, so that the engine 1 is controlled by braking the second sun gear 32 with the brake 50. Rotate at a reduced speed. At this time, the brake 50 may be applied with braking force (braking rotation of the second sun gear 32) rather than being engaged (fixing the second sun gear 32).

  After the engine 1 is started, the mode shifts from the H-1 mode (low speed mode in HV traveling) to the H-2 mode (same medium speed mode) according to the speed of the automobile.

First, the H-1 mode is driven by the engagement of the first one-way clutch 54 and the second one-way clutch 74. That is, when the input shaft 10 rotates forward by the engine 1, the second planetary gear set 30 is integrated with the input shaft 10 by the engagement of the first one-way clutch 54 to drive the first ring gear 24.
The first ring gear 24 drives the first carrier 28 integrated with the output shaft 12 at a reduced speed in the first planetary gear set 20 and reversely rotates the first M / G 56 with the reaction torque to generate electric power. That is, here, the torque of the engine 1 is divided into torque that mechanically drives the first carrier 28 to decelerate and torque that causes the first M / G 56 to generate power.

Then, the electric power generated by the first M / G 56 is supplied to the second M / G 58, and the output shaft 12 is driven to decelerate via the third planetary gear set 40 in the same manner as in the E-1 mode. At this time, the torque To of the output shaft 12 is T1 (1 + α1) / α1 + T2 · I, and when the torque of the engine 1 is Te, To = Te (1 + α1) + T2 · I.
When the vehicle speed increases in the H-1 mode, the first M / G 56 rotates at a very low speed together with the first sun gear 22 and the power generation efficiency is in an operating range. Therefore, before that happens, the mode is switched to the H-2 mode.

The H-2 mode is driven by fastening the brake 50. As a result, the first ring gear 24 that has the same rotational speed as the input shaft 10 in the H-1 mode is driven to be accelerated by the second planetary gear set 30.
Therefore, if the rotational speed of the output shaft 12 is the same as before switching, the rotational speeds of the first sun gear 22 and the first M / G 56 are increased, and the power transmission efficiency is reduced as a result of exiting from the operating range where the power generation efficiency is poor. improves.
At this time, the torque To of the output shaft 12 is T1 (1 + α1) / α1 + T2 · I. On the other hand, if the torque of the engine 1 is Te, it is also To = Te (1 + α1) / (1 + α2) + T2 · I.

Subsequently, in the H-3 mode, when the engagement of the brake 50 is released and the clutch 60 is engaged, when the input shaft 10 rotates forward by the engine 1, the second planetary gear set 30 is moved by the action of the first one-way clutch 54. Since the second M / G 58 and the first ring gear 24 are driven integrally with the input shaft 10 and the third carrier 48 and the first carrier 28 are connected by the action of the second one-way clutch 74, the first planetary gear set 20 is also integrated.
That is, the input shaft 10 and the output shaft 12 are mechanically integrally connected, and the first M / G 56 and the second M / G 58 need not generate or drive.

When the second M / G 58 generates power in the H-3 mode and supplies the first M / G 36 to drive it, the mode is switched to the H-4 mode.
At this time, the torque Te of the engine 1 is divided into a torque for driving the second M / G 58 and a torque for driving the first ring gear 24, whereby the second M / G 58 generates electric power and supplies the electric power to the first M / G 56. Then, the first sun gear 22 is driven. Therefore, the output shaft 12 is driven by the first ring gear 24 and the first M / G 56 that are driven by a part of the torque of the engine 1.
As a result, overdrive is achieved in which the rotational speed of the output shaft 12 is faster than the rotational speed of the input shaft 10.
At this time, the torque of the output shaft 12 is Te + T1−T2 · I, which is also T1 (1 + α1) / α1.

Of the torque Te of the engine 1, the torque that is divided and drives the first ring gear 24 is the torque that acts on the first ring gear 24 as the reaction force of the torque that the first M / G 56 drives the first sun gear 22, T1 / Α1.
When the vehicle speed increases in the H-4 mode, the rotational speed of the first M / G 56 increases, and the driving efficiency of the first M / G 56 becomes poor. Therefore, before that happens, the mode is switched to the H-5 mode.

In the H-5 mode, the brake 50 is engaged together with the clutch 60 to drive.
As a result, the rotation of the input shaft 10 is accelerated in the second planetary gear set 30, and the second M / G 58 and the first ring gear 24 are driven at a rotational speed (1 + α2) times that of the input shaft 10.
Since the third carrier 48 and the first carrier 28 are connected by the action of the second one-way clutch 74 as in the H-3 mode, the first planetary gear set 20 is integrated, and the output shaft 12 is also the input shaft 10. Therefore, the first M / G 56 and the second M / G 58 do not need to generate power or drive.
The torque of the output shaft 12 is Te / (1 + α2).

When the second M / G 58 generates power in the state of the H-5 mode, and the electric power is supplied and driven by the first M / G 36, the mode is switched to the H-6 mode.
In the H-6 mode, when the rotational speed of the output shaft 12 is the same as that before the switching and in the H-5 mode, the rotational speeds of the second sun gear 32 and the second M / G 58 are reduced, and the above-described operating range where the power generation efficiency is poor. As a result, the power transmission efficiency is improved as compared with the H-5 mode.
As a result, as in the H-4 mode, the second M / G 58 generates power, supplies the power to the first M / G 56, and drives the first sun gear 22. Therefore, the output shaft 12 is driven by the first ring gear 24 and the first M / G 56 that are driven by a part of the torque of the engine 1.
At this time, the torque of the output shaft 12 is Te / (1 + α2) + T1−T2, and is also T1 (1 + α1) / α1.
The rotation speed ratio in the H-6 mode is higher than 1 / (1 + α1) in the H-5 mode.

The above H-1 mode to H-6 mode, except for the H-3 mode and H-5 mode, which are mechanical drives, in the first planetary gear set 20 which is a power split planetary gear set of the present invention, Since part of the torque of the engine 1 is mechanically transmitted and the rest is electrically transmitted to the output shaft 12 for driving, the mechanical power transmission ratio is always high, and therefore the power transmission efficiency is high.
In addition, as described above, it is possible to drive while avoiding an operation region where power generation efficiency and drive efficiency are poor.

Next, the HR mode that is the reverse of HV traveling will be described.
When the engine 1 is rotated backward, the sleeve 70 and the dog clutch 28 c are engaged with each other, and the second sun gear 32 is fixed to the case 52 by the brake 50 and driven.
This is a drive connected in the same manner as in the H-2 mode as will be described later. In that case, the operation is substantially the same as in the H-2 mode, only the rotation direction of the second M / G 58 is reversed.
That is, for example, the torque of the output shaft 12 when the rotation direction of the second M / G 58 is reversed with the same connection relationship as the forward H-1 mode is Te (1 + α1) −T2 · I, As described in the HR mode in FIG. 5, the torque of the output shaft 12 when the same engagement as in the H-2 mode is Te (1 + α1) / (1 + α2) −T2 · I. The latter is more powerful.

That is, the torque transmitted mechanically among the torque of the engine 1 is always the forward torque, so that the reverse drive torque can be largely secured by reducing the torque.
Accordingly, the fastening HR mode similar to the H-2 mode is suitable for the backward movement such as when the remaining amount of the battery is low.

  In addition, although said HV driving | running demonstrated on the assumption that the electric power which one of the 1st M / G56 and the 2nd M / G58 generated generated is driven to the other, it is not restricted to this, but a part of the generated electric power is used. It can be used for charging the battery, or it can be driven by supplying additional power from the battery.

  As described above, in the automobile drive device of the first embodiment, the brake 50 and the first one-way clutch 54 are simultaneously engaged as the fixing means for fixing the first ring gear 24 to the case 52 (stationary portion). did. When the first ring gear 24 is fixed and the engine 1 is stopped, the first M / G 56 can drive the output shaft 12 at a reduced speed via the first planetary gear set 20, and the second M / G 58 is also output at the same time. The shaft 12 can be driven at a reduced speed.

  Therefore, it is a feature that both the first M / G 56 and the second M / G 58 can be fully utilized in EV traveling, including simultaneous driving. As a result, the total capacity of the first M / G 56 and the second M / G 58 only needs to satisfy the motor capacity required by the automobile, so that the M / G can be compared with the conventional example that can be driven by only one M / G. Total capacity can be reduced. As a result, it is possible to obtain advantages in terms of cost, weight, and size, including an inverter that is generally included in a controller.

In EV traveling, driving with both the second M / G 58 and the first M / G 56 is possible as required, and driving with only the first M / G 56 and driving with only the second M / G 58 can be selected. The optimal control can be performed according to the running load of the automobile.
In particular, in the E-1 mode and the E-2 mode of low load traveling, one of the first M / G 56 and the second M / G 58 can be driven and the other can be stopped, so that unnecessary traveling is avoided. This also has the effect of reducing power consumption.

In addition, it is an effect of the present embodiment that there are only two friction elements for obtaining the above function, the brake 50 and the clutch 60. This is because the sleeve 70 and the dog clutch 28 c are provided in parallel with the second one-way clutch 74.
Since the third planetary gear set 40 exists and the second M / G 58 can drive the output shaft 12 at a reduced speed, the second M / G 58 of the low torque high speed rotation type can be used. can do.

  Further, the speed-up action by the second planetary gear set 30 avoids driving in a region where the power generation efficiency and driving efficiency in the H-1 mode and H-4 mode deteriorate, and the H-2 mode and H-6 mode. Therefore, the power transmission efficiency can be maintained at a high level, and the degree of freedom in selecting the drive mode can be increased.

As described above, in EB traveling, the clutch 60 is engaged and braking is performed while the first M / G 56 and the second M / G 58 generate electric power. However, when the clutch 60 is released, the first M / G 56 and the second M / G 58 are released. It is also possible to stop both.
For example, when the accelerator pedal is loosened during high speed driving in HV driving and acceleration is not performed but aggressive braking is not desired, when the engine 1 is stopped and coasted, at least one M / G rotates in the conventional example. Therefore, it is necessary to supply some electric power so that it does not cause braking by generating electric power, which consumes electric power.
Since the first M / G 56 and the second M / G 58 need not be rotated by the control as described above, there is an effect that excessive power consumption can be suppressed, and the fuel efficiency is improved accordingly.

  Therefore, taking advantage of the fact that both the first M / G 56 and the second M / G 58 can be fully utilized, the engine 1 is used when, for example, a short distance such as traveling in an urban area travels mainly as an electric vehicle and the battery power decreases. It is suitable for use as a drive device of a vehicle called so-called plug-in hybrid vehicle that travels with the power of

Next, an automobile drive device according to a second embodiment of the present invention will be described.
FIG. 6 is a skeleton diagram of the main part of the automobile drive device according to the second embodiment of the present invention.
Here, the description will focus on parts that are different from the first embodiment, the same reference numerals are given to parts that are substantially the same as those of the first embodiment, and descriptions thereof are omitted.

The difference between the second embodiment and the first embodiment is that there is no third planetary gear set 40 in the first embodiment.
The connection relationship of each rotating member is as follows.
The second M / G 58 can be connected to the first carrier 28 via the second one-way clutch 74, and in parallel with this, the connection via the sleeve 70 and the dog clutch 28c is possible as in the first embodiment. It is.
The second M / G 58 can be connected to the second ring gear 34 and the first ring gear 24 via the clutch 60.
Although the arrangement of the brake 50 is different from that of the first embodiment, there is no difference in function.
Other connection relationships are the same as those in the first embodiment.

Subsequently, the operation of the second embodiment will be described.
The operation of the second embodiment is the same as that of the first embodiment including the operation table of FIG.
However, since there is no third planetary gear set 40, the first carrier 28 of the second M / G 58, the second ring gear 34, and the first ring gear 24 are directly connected without using a gear as described above. Therefore, in the calculation formula of the torque of the output shaft 12 described in the first embodiment, the portion that has been the reduction ratio I may be replaced with 1.

The vehicle drive apparatus of the second embodiment is also similar to the first embodiment in that it can be driven simultaneously by both the first M / G 56 and the second M / G 58 during EV traveling.
As a result, it is possible to reduce the total capacity of the two M / Gs 56 and 58 and to bring out advantages in terms of cost, weight, and size, including the inverter that is generally included in the controller.
In EV traveling, it is possible to travel by selecting a driving mode according to the traveling speed and load of the automobile, and there is an effect of avoiding unnecessary M / G accompanying and reducing power consumption.
In addition, it is an effect of the present embodiment that there are only two friction elements for obtaining the above function, the brake 50 and the clutch 60. This is because the sleeve 70 and the dog clutch 28 c are provided in parallel with the second one-way clutch 74.

In addition, when the engagement of the clutch 60 is released during EB travel, both the first M / G 56 and the second M / G 58 can be prevented from rotating.
The second embodiment is also suitable for use as a drive device for a vehicle called a so-called plug-in hybrid vehicle.

Next, an automobile drive device according to Embodiment 3 of the present invention will be described.
FIG. 7 is a skeleton diagram of the main part of the automobile drive device according to the third embodiment of the present invention.
Here, the description will focus on parts that are different from the first embodiment, the same reference numerals are given to parts that are substantially the same as those of the first embodiment, and descriptions thereof are omitted.

The difference of the third embodiment from the first embodiment is that the second planetary gear set 30 and the third planetary gear set 40 in the first embodiment are not provided.
The connection relationship of each rotating member is as follows.
The input shaft 10 and the first ring gear 24 can be connected by a first clutch 60.
The second M / G 58 can be connected to the first carrier 28 via the second one-way clutch 74, and in parallel with this, the connection via the sleeve 70 and the dog clutch 28c is possible in the first embodiment. It is the same.
Further, the second M / G 58 can be connected to the first ring gear 24 via the second clutch 68.

Further, a fixing device 52a capable of mechanically fixing the input shaft 10 to a stationary part (the case 52 or the main body of the engine 1) is provided.
That is, the dog clutch 10a is formed on the input shaft 10, and the fixing device 52a is engaged with the dog clutch 10a to fix the input shaft 10. In principle, the fixing device 52a is engaged (engaged) with the dog clutch 10a while the engine 1 is stopped.
As will be described later, the fixing device 52a can fix the first ring gear 24 in combination with the engagement of the first clutch 60 in the ER mode.
The fixing device 52a may be the same as a parking lock mechanism used in a general automatic transmission, and the dog clutch 10a may be formed not only on the input shaft 10 but also on the outer periphery of the flywheel of the engine 1.
Other connection relationships are the same as those in the first embodiment.

Next, the operation of Example 3 will be described with reference to the operation table shown in FIG.
FIG. 8 is the same as FIG. 5 of the first embodiment except that the first clutch 60 is “C1”, the second clutch 68 is “C2”, the fixing device 52a is “L”, and the second one-way clutch 74 is “OWC”. It is the same.

First, in the E-1 mode, the second M / G 58 directly drives the output shaft 12 via the first carrier 24 by the action of the second one-way clutch 74. The torque of the output shaft 12 is T2.
At this time, the first M / G 56 can be stopped.
In the E-2 mode, the second M / G 58 and the first ring gear 24 are connected by engaging the second clutch 68, so that the first M / G 56 and the second M / G 58 are cooperatively driven.
However, since there is the second one-way clutch 74, the rotation speed of the output shaft 12 is always the same as or higher than that of the second M / G 58.

  In the ER mode, the first ring gear 24 is fixed by the fastening of the fixing device 52a and the fastening of the first clutch 60 described above, and the vehicle reverses by the deceleration driving by the first M / G 56 and the driving by the second M / G 58. The torque of the output shaft 12 is − {T1 (1 + α1) / α1 + T2}.

The EB traveling is basically the same as the second embodiment because there is no third planetary gear set 40.
Subsequently, since the HV traveling does not have the second planetary gear set 30 and the third planetary gear set 40, there is no H-2 mode, H-5 mode, and H-6 mode in the second embodiment.
Therefore, the H-1 mode is the same as that of the second embodiment, the H-2 mode is the same as the H-3 mode of the second embodiment, and the H-3 mode is the same as the H-4 mode of the second embodiment.

In the automobile drive device of the third embodiment, the second M / G 58 can drive the output shaft 12 simultaneously with the first M / G 56.
Therefore, the feature is that both the first M / G 56 and the second M / G 58 can be utilized in EV traveling, as in the first embodiment.

As a result, it is possible to reduce the total capacity of the two M / Gs 56 and 58 and to bring out advantages in terms of cost, weight, and size, including the inverter that is generally included in the controller.
In EV traveling, it is possible to travel by selecting an optimum drive mode according to the traveling load of the automobile, and there is an effect of avoiding unnecessary M / G rotation and reducing power consumption.

Furthermore, in HV traveling, it is possible to maintain high power transmission efficiency, such as enabling mechanical driving in the H-2 mode, and increase the degree of freedom in selecting the driving mode, so that improvement in fuel consumption can be expected.
In addition, it is a great effect of the present invention that there are only two friction elements for obtaining the above function, the first clutch 60 and the second clutch 68. This is because the sleeve 70 and the dog clutch 28 c are provided in parallel with the second one-way clutch 74.

  Further, when the engagement of the second clutch 68 is released during the EB traveling, both the first M / G 56 and the second M / G 58 can be prevented from rotating.

As can be seen from FIG. 7, the first clutch 60 and the second clutch 68 can be arranged at positions separated from components that require lubrication, such as gears and one-way clutches. Therefore, it is possible to use a dry clutch, and accordingly, it is easy not to use a hydraulic pump provided in a general automatic transmission.
The third embodiment is also suitable for use as a drive device for a vehicle called a so-called plug-in hybrid vehicle.

Next, an automobile drive device according to Embodiment 4 of the present invention will be described.
FIG. 9 is a skeleton diagram of the main part of the automobile drive device according to the fourth embodiment of the present invention.
Here, the description will focus on the parts that are different from the first and third embodiments, the same reference numerals are given to substantially the same parts, and the description thereof is omitted.

The difference of the fourth embodiment from the first embodiment is that there is no second planetary gear set 30 in the first embodiment and the connection relationship of the third planetary gear set 40 is different.
The connection relationship of each rotating member is as follows.
Similarly to the third embodiment, the input shaft 10 and the first ring gear 24 can be connected by the first clutch 60.

The second M / G 58 is connected to the third sun gear 42, the third carrier 48 is fixed to the case 52, and the third ring gear 44 can be connected to the first carrier 28 via the second one-way clutch 74. In parallel, the sleeve 70 and the dog clutch 28c can be connected.
The third ring gear 44 can also be connected to the first ring gear 24 via the second clutch 68.
Other connection relationships are the same as those in the first embodiment.

Next, the operation of Example 4 will be described with reference to the operation table shown in FIG.
The drawing method of FIG. 10 is the same as that of the third embodiment, but there is no “L” of the fixing device 52a.
The E-1 mode is basically the same as that of the first embodiment, but the torque of the output shaft 12 is different because the connection relationship of the third planetary gear set 40 is different. That is, since the third planetary gear set 40 drives the second M / G 58 to reverse and decelerate, the speed ratio is −1 / α3.
The torque of the output shaft 12 in the E-1 mode is −T2 (−1 / α3) = T2 / α3.
Hereinafter, the torque driven by the second M / G 58 is T2 / α3.
Similarly, the E-2 mode corresponds to the E-4 mode in the first embodiment, and the torque of the output shaft 12 is T1 + T2 / α3.
In the E-R mode, the second M / G 58 is driven only by the engagement of the sleeve 70 and the dog clutch 28c. The torque of the output shaft 12 is −T2 / α3.
The EB travel is the same as in the first embodiment.

The subsequent H-1 mode of HV traveling is basically the same as that of the first embodiment, and the torque of the output shaft 12 is Te (1 + α1) + T2 / α3, and is also T1 (1 + α1) / α1 + T2 / α3.
The H-2 mode is the same as the H-3 mode of the first embodiment, and is a mechanical direct drive.
The H-3 mode is the same as the H-4 mode in the first embodiment and is overdrive. At this time, the torque of the output shaft 12 is Te + T1−T2 · α3, and is also T1 (1 + α1) / α1.
The HR mode is basically the same as that in the first embodiment, and the torque of the output shaft 12 is Te (1 + α1) −T2 / α3.

In the automobile drive device of Example 4, the second M / G 58 can drive the output shaft 12 simultaneously with the first M / G 56.
Therefore, the feature is that both the first M / G 56 and the second M / G 58 can be utilized in EV traveling, as in the first embodiment.
As a result, it is possible to reduce the total capacity of the two M / Gs 56 and 58 and to bring out advantages in terms of cost, weight, and size, including the inverter that is generally included in the controller.
In EV traveling, it is possible to travel by selecting an optimum drive mode according to the traveling load of the automobile, and there is an effect of avoiding unnecessary M / G rotation and reducing power consumption.

Furthermore, in HV traveling, it is possible to maintain high power transmission efficiency, such as enabling mechanical driving in the H-2 mode, and increase the degree of freedom in selecting the driving mode, so that improvement in fuel consumption can be expected.
In addition, it is a great effect of the present embodiment that there are only two friction elements for obtaining the above function, the first clutch 60 and the second clutch 68. This is because the sleeve 70 and the dog clutch 28 c are provided in parallel with the second one-way clutch 74.

Further, when the engagement of the second clutch 68 is released during the EB traveling, both the first M / G 56 and the second M / G 58 can be prevented from rotating.
And like Example 3, the 1st clutch 60 and the 2nd clutch 68 can be made into a dry clutch, and it is easy not to use a hydraulic pump.
The fourth embodiment is also suitable for use as a drive device for vehicles such as so-called plug-in hybrid vehicles.

Next, an automobile drive device according to Embodiment 5 of the present invention will be described.
FIG. 11 is a skeleton diagram of the main part of the automobile drive device according to the fifth embodiment of the present invention.
Here, the description will focus on parts that are different from the first embodiment, the same reference numerals are given to parts that are substantially the same as those of the first embodiment, and descriptions thereof are omitted.

The difference between the fifth embodiment and the first embodiment is that a third clutch 72 that can connect the third ring gear 44 and the first carrier 28 is provided.
That is, the third clutch 72 can connect the third ring gear 44 and the intermediate member 72 a, and the intermediate member 72 a is always connected to the first carrier 28 via the sleeve 70. The sleeve 70 is movable in the axial direction while always meshing with both the intermediate member 72a and the first carrier 28 with a spline (not shown), and can also mesh with the dog clutch 48c when moving to the left in FIG.

The arrangement and connection relationship between the sleeve 70 and the dog clutch 48c are slightly different from those in the first embodiment, but they constitute the mechanical connection / release means of the present invention.
Since other connection relations are the same as those in the first embodiment, description thereof is omitted.

Next, the operation of the fifth embodiment will be described with reference to the operation table shown in FIG.
The drawing method of FIG. 11 is the same as that of the first embodiment, but the first clutch 60 is “C1” and the third clutch 72 is “C3”.
Since the operational difference from the first embodiment is only the drive mode related to the third clutch 72, only that portion will be described.

In the E-4 mode, when the third clutch 72 is engaged, the second M / G 58 and the output shaft 12 are directly connected. Therefore, the torque of the output shaft 12 is T2.
In the H-7 mode, the input shaft 10 and the output shaft 12 are mechanically coupled by engaging the third clutch 72 in addition to the brake 50 and the first clutch 60 in the H-6 mode.
That is, the speed is increased by the second planetary gear set 30 and the third planetary gear set 40, and the gear ratio is 1 / (1 + α2) (1 + α3).
Therefore, the torque of the output shaft 12 is Te / (1 + α2) (1 + α3).

In the automobile drive device of Example 5, the second M / G 58 can drive the output shaft 12 simultaneously with the first M / G 56.
Therefore, the feature is that both the first M / G 56 and the second M / G 58 can be utilized in EV traveling, as in the first embodiment.
As a result, it is possible to reduce the total capacity of the two M / Gs 56 and 58 and to bring out advantages in terms of cost, weight, and size, including the inverter that is generally included in the controller.
In EV traveling, it is possible to travel by selecting an optimum drive mode according to the traveling load of the automobile, and there is an effect of avoiding unnecessary M / G rotation and reducing power consumption.

Furthermore, in HV driving, mechanical drive is possible in the H-3 mode, H-5 mode, and H-7 mode, and the power transmission efficiency is maintained at a high level, and the degree of freedom in selecting the drive mode is increased. Improvement can be expected.
In addition, only three brake elements, the brake 50, the first clutch 60, and the third clutch 72, are required to obtain the above functions, which is a great effect of this embodiment. This is because the sleeve 70 and the dog clutch 28 c are provided in parallel with the second one-way clutch 74.

Further, when the engagement of the first clutch 60 is released during the EB traveling, both the first M / G 56 and the second M / G 58 can be prevented from rotating.
The fifth embodiment is also suitable for use as a drive device for a vehicle called a so-called plug-in hybrid vehicle.

As described above, in the automobile drive device of the present invention, the output shaft can be driven by both the first M / G 56 and the second M / G 58 during EV travel with the engine 1 stopped. It is.
As a result, it is possible to reduce the total capacity of the two M / Gs 56 and 58 and to bring out advantages in terms of cost, weight, and size, including the inverter that is generally included in the controller.

And in EV driving | running | working, there is also an effect which avoids unnecessary M / G accompanying and reduces power consumption.
Therefore, taking advantage of the fact that both the first M / G 56 and the second M / G 58 can be fully utilized, the engine 1 is used when, for example, a short distance such as traveling in an urban area travels mainly as an electric vehicle and the battery power decreases. It is suitable for use as a drive device of a vehicle called so-called plug-in hybrid vehicle that travels with the power of

  In addition, each embodiment has the above-described characteristics, but is characterized in that the number of friction elements is as small as two or three. Therefore, the cost including the control device is reduced.

  Further, in each of the above-described embodiments, the first planetary gear set 20, the second planetary gear set 30, and the like use a planetary gear set called a single pinion type, but it is also possible to replace this with a double pinion type. . Although not shown in the figure, the connection relationship in the case of the double pinion type may be such that the carrier and the ring gear are switched with respect to the single pinion type.

  The automobile driving device of the present invention selects an optimum driving mode according to the driving condition of the automobile based on general knowledge of those skilled in the art, and performs driving in a zone having the highest efficiency of M / G. Auto, when traveling on long hills, at the entrance of highways, and when the temperature is low and there are not enough heating sources for cars, based on information such as GPS (Global Positioning System) and car navigation systems. In particular, it can be carried out in a mode combined with a device in terms of control such as switching to HV traveling.

The automobile drive device of the present invention can be applied to a small passenger car or the like that places particular emphasis on travel cost and is required to reduce the environmental load, but is not limited to these, and uses various internal combustion engines and electric motor generators. It can be applied to various vehicles.

1 Engine 10 Input shaft 12 Output shaft 20 First planetary gear set (power split planetary gear set)
22 1st sun gear 24 1st ring gear 26 1st pinion 28 1st carrier 30 2nd planetary gear set (input transmission gear group)
32 Second sun gear 34 Second ring gear 36 Second pinion 38 Second carrier 40 Third planetary gear set (reduction gear)
42 3rd sun gear 44 3rd ring gear 46 3rd pinion 48 3rd carrier 50 Brake, (1st fastening element, fixing means)
52 Case (stationary part)
52a Fixing device (fixing means, mechanical connection / release means)
54 1st one way clutch (2nd fastening element, fixing means)
56 1st M / G
58 2nd M / G
60 Clutch (first fastening element, fixing means)
68 Second clutch 70 Sleeve (Mechanical connection / release means)
72 Spring 74 Second one-way clutch

Claims (5)

An input shaft capable of receiving power from the engine;
An output shaft;
A power split planetary gear set composed of a first planetary gear having three rotating elements, a first sun gear, a first ring gear, and a first carrier, and capable of power split;
A first motor generator;
A second motor generator;
With
The input shaft is connected to or connectable to the first ring gear;
The output shaft is connected to the first carrier;
The first motor generator is connected to the first sun gear,
The automobile drive device according to claim 1, wherein the second motor generator is connectable to the first carrier via a mechanical connection / release means and to the first ring gear via a first clutch.   The input shaft and the first ring gear are connected by a second planetary gear having three rotating elements, a second sun gear, a second ring gear, and a second carrier, and an input gear group that can be driven at an increased speed. The vehicle drive device according to claim 1, wherein   The second motor / generator is composed of a third planetary gear having three rotating elements, ie, a third sun gear, a third ring gear, and a third carrier, and is capable of reduction driving and the mechanical connecting / releasing means. The vehicle drive device according to claim 1, wherein the vehicle drive device can be connected to the output shaft via the.   The second motor / generator is connected to the third ring gear, and the third carrier is connectable to the output shaft via the mechanical connection / release means, and the third carrier is fixed to a case, The vehicle driving device according to claim 3, wherein the vehicle driving device is fixed. The automobile drive device according to claim 4, wherein the third ring gear and the output shaft are connectable.

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