JP4285579B2 - Power output device and hybrid vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a simple and compact power output device which is excellent in loading property for improving transmission efficiency of a power in a wider operation region, and a hybrid car equipped with the power output device. <P>SOLUTION: This hybrid car 20 is provided with an engine 22; motors MG1 and MG2; a power distribution integrated mechanism 40, which are coaxially arranged with one another; and a transmission 60 including a differential rotating mechanism 61 for transmission as a single pinion type planetary gear mechanism equipped with a sun gear 62, a ring gear 63 and a carrier 65 connected to a driving shaft 66, and configured so that those three elements can be differentially rotated with one another and a clutch C1 to be selectively engaged with either the carrier 45 or the sun gear 41 of the power distribution integrated mechanism 40 or both of them to the sun gear 62 of the differential rotating mechanism 61 for transmission. <P>COPYRIGHT: (C)2008,JPO&amp;INPIT

Description

  The present invention relates to a power output device that outputs power to a drive shaft and a hybrid vehicle including the same.

Conventionally, as this type of power output device, an internal combustion engine, two electric motors, a so-called Ravigneaux type planetary gear mechanism, and a parallel shaft capable of selectively connecting two output elements of the planetary gear mechanism to the output shaft 2. Description of the Related Art A power output device including a transmission is known (see, for example, Patent Document 1). Further, conventionally, a planetary gear device including an input element connected to an internal combustion engine and two output elements, and a parallel shaft transmission including a countershaft respectively connected to a corresponding output element of the planetary gear mechanism. The thing provided is also known (for example, refer patent document 2). In this power output device, the two output elements of the planetary gear device are respectively fixed to the inner periphery of the corresponding rotor of the electric drive unit. Conventionally, a power distribution mechanism including an input element connected to the internal combustion engine, a reaction force element connected to the first motor / generator, and an output element connected to the second motor / generator, and an output member There is also known one that includes two clutches for selectively connecting an axle shaft as an output element and a reaction force element of a power distribution mechanism (see, for example, Patent Document 3). In this power output device, when the first motor / generator is powered by negative rotation, the reaction force element of the power distribution mechanism is connected to the output member and the connection between the output element and the output member is released. The two clutches are controlled, thereby suppressing the occurrence of power circulation that drives the first motor / generator with the electric power generated by the second motor / generator using a part of the power of the output member.
Japanese Patent Laid-Open No. 2005-155891 JP 2003-106389 A Japanese Patent Laying-Open No. 2005-125876

  The power output apparatus as described above enables the internal combustion engine to be operated at an efficient operating point by outputting the required power to the drive shaft while converting the power from the internal combustion engine with two electric motors. However, the structure is complicated and it is difficult to make it compact, and there are some problems in terms of mountability on vehicles. In addition, there is still room for improvement in the conventional power output apparatus in terms of improving the power transmission efficiency in a wider travel region.

  Therefore, an object of the present invention is to provide a power output device that is simple, compact, and has excellent mountability, and a hybrid vehicle including the power output device. Another object of the present invention is to provide a power output device capable of improving power transmission efficiency in a wider driving range and a hybrid vehicle equipped with the power output device.

  The power output apparatus and the hybrid vehicle according to the present invention employ the following means in order to achieve the above-described object.

The power output device according to the present invention is:
A power output device that outputs power to a drive shaft,
An internal combustion engine;
A first electric motor capable of inputting and outputting power;
A second electric motor capable of inputting and outputting power;
A first element connected to the rotating shaft of the first electric motor, a second element connected to the rotating shaft of the second electric motor, and a third element connected to the engine shaft of the internal combustion engine. A power distribution and integration mechanism configured to allow the elements to differentially rotate relative to each other;
A differential rotation mechanism for shifting, which has an input element, a fixed element, and an output element connected to the drive shaft, and is configured so that the input element and the output element can differentially rotate with each other; Shift transmission means including connection means capable of selectively connecting either one or both of the first element and the second element of the mechanism to the input element of the transmission differential rotation mechanism;
Fixing means capable of fixing any one of the rotating shaft of the first motor and the rotating shaft of the second motor to be non-rotatable ;
When the first or second element of the power distribution and integration mechanism connected to the first or second electric motor not corresponding to the fixing means is coupled to the input element of the differential rotation mechanism for shifting. Control means for controlling the fixing means so that the rotation shaft of the second or first motor corresponding to the fixing means is fixed in a non-rotatable manner ;
Is provided.

The power output device includes an input element, a fixed element, an output element connected to a drive shaft, and a differential rotation mechanism for speed change configured so that the input element and the output element can be differentially rotated with each other. Shift transmission means is provided including connection means capable of selectively connecting one or both of the first element and the second element of the distribution and integration mechanism to the input element of the differential rotation mechanism for shifting. Such shift transmission means can be configured with relatively few parts, has a simple and compact configuration, and is excellent in mountability. Further, in this power output device, if one of the first and second elements of the power distribution and integration mechanism is connected to the input element of the transmission differential rotation mechanism by the connection means of the transmission transmission means, the power distribution and integration mechanism The power from the first or second element can be shifted to the drive shaft after being shifted by the shift differential rotation mechanism. Further, in this power output apparatus, the power from the internal combustion engine is fixed if both the first and second elements of the power distribution and integration mechanism are connected to the input elements of the speed change differential rotation mechanism by the connecting means of the speed change transmission means. The transmission ratio can be mechanically (directly) transmitted to the drive shaft. In this power output device, when the first element of the power distribution and integration mechanism is connected to the input element of the transmission differential rotation mechanism by the connecting means of the speed change transmission means, it is connected to the first element as the output element. The first motor can function as a motor, and the second motor connected to the second element serving as a reaction force element can function as a generator. Further, when the second element of the power distribution and integration mechanism is connected to the input element of the transmission differential rotation mechanism by the connecting means of the transmission transmission means, the second motor connected to the second element serving as the output element is used as the motor. The first motor connected to the first element serving as a reaction force element can function as a generator. Thereby, in this power output device, by appropriately switching the connection state by the connecting means, the second or the second functioning as a generator particularly when the rotation speed of the first or second motor functioning as the motor is increased. Generation of so-called power circulation can be suppressed by preventing the rotation speed of the first electric motor from becoming a negative value. Further, the power output device includes a fixing means capable of fixing any one of the rotating shaft of the first motor and the rotating shaft of the second motor in a non-rotatable manner, and the first or second motor not corresponding to the fixing means. When the first or second element of the power distribution and integration mechanism connected to is connected to the input element of the differential rotation mechanism for shifting, the rotation shaft of the second or first motor corresponding to the fixing means cannot rotate. And a control means for controlling the fixing means so as to be fixed to. As a result, the first or second element of the power distribution and integration mechanism connected to the first or second electric motor that does not correspond to the fixing means is driven by the connecting means of the transmission transmission mechanism via the transmission differential rotation mechanism. When the rotation shaft of the second or first motor corresponding to the fixing means is fixed to be non-rotatable by the fixing means, the power from the internal combustion engine is mechanically (directly) with a fixed gear ratio. ) Can be transmitted to the drive shaft. As a result, according to this power output apparatus, it becomes possible to improve the power transmission efficiency in a wider range of operation.

Further, the control means includes one of the first and second elements of the power distribution and integration mechanism connected to the second or first motor corresponding to the fixing means and the input of the differential rotation mechanism for shifting. Corresponding to the fixing means, a state in which the elements are connected, a state in which both the first and second elements of the power distribution and integration mechanism and the input element of the differential rotation mechanism for shifting are connected. A state in which the other of the first and second elements of the power distribution and integration mechanism connected to the first or second electric motor not connected to the input element of the differential rotation mechanism for shifting is connected to the power The other of the first and second elements of the distribution and integration mechanism and the input element of the differential rotation mechanism for shifting are connected to the second or first element connected to one of the first and second elements. The rotation shaft of the motor of the motor cannot rotate And a state to be fixed or may be controlled with the connecting means to be switched selectively between the fixing means.

Further, the shift differential rotation mechanism of the shift transmission means may be a three-element planetary gear mechanism. As a result, the shift transmission means can be configured more compactly .

The first and second electric motors may be disposed substantially coaxially with the internal combustion engine, and the power distribution and integration mechanism may be disposed between the first electric motor and the second electric motor and substantially coaxial with both electric motors. . As a result, the entire power output apparatus can be configured more compactly .

Further, when the internal combustion engine, the first and second electric motors, and the power distribution and integration mechanism are arranged substantially coaxially, the power output device according to the present invention is any one of the first and second elements of the power distribution and integration mechanism. A hollow shaft connected to one side and extending toward the speed change transmission means; and a connecting shaft connected to the other of the first and second elements and extending through the hollow shaft toward the speed change transmission means. The transmission means of the speed change transmission means can selectively connect either one or both of the hollow shaft and the connection shaft to the input element of the differential rotation mechanism for speed change. May be. As a result, the power from the first element and the power from the second element of the power distribution and integration mechanism can be output in substantially the same direction and in the same direction. The power distribution and integration mechanism can be arranged substantially coaxially. Therefore, this configuration is extremely suitable for a vehicle that travels mainly by driving the rear wheels .

  The power output apparatus according to the present invention includes a connection between the first electric motor and the first element and a release of the connection, a connection between the second electric motor and the second element, a release of the connection, and the internal combustion engine. There may be further provided a connection / disconnection means capable of executing either connection between the engine and the third element or release of the connection. In the power output apparatus provided with such connection / disconnection means, if the connection / disconnection means releases the connection, the internal combustion engine is substantially made to function as the first and second electric motors and the transmission gear by the function of the power distribution and integration mechanism. It becomes possible to separate from the means. Thus, in this power output device, when the connection / disconnection means releases the connection and stops the internal combustion engine, the power from at least one of the first and second motors is shifted by the transmission transmission means and driven. It is possible to efficiently transmit to the shaft. Therefore, according to this power output apparatus, it is possible to reduce the maximum torque required for the first and second electric motors, and it is possible to further reduce the size of the first and second electric motors.

  Further, one of the first and second elements of the power distribution and integration mechanism to which a larger torque is input from the third element connected to the engine shaft is the first motor or the second motor. You may connect with the said 1st electric motor or the said 2nd electric motor via the deceleration means which decelerates rotation of a rotating shaft. In this way, if the one with the larger torque distribution ratio from the internal combustion engine is connected to the first or second electric motor via the speed reduction means, the power distribution integration mechanism is connected to the speed reduction means. It is possible to more effectively reduce the torque burden on the first or second electric motor, thereby reducing the size of the electric motor and reducing the power loss.

  In this case, the power distribution and integration mechanism includes a sun gear, a ring gear, and a carrier that holds at least one set of two pinion gears that mesh with each other and one meshes with the sun gear and the other meshes with the ring gear. In the planetary gear mechanism, the first element may be one of the sun gear and the carrier, the second element may be the other of the sun gear and the carrier, and the third element may be the ring gear. . The power distribution and integration mechanism is such that ρ <0.5 when the gear ratio of the power distribution and integration mechanism, which is a value obtained by dividing the number of teeth of the sun gear by the number of teeth of the ring gear, is ρ. The speed reduction means is configured so that the speed reduction ratio is a value in the vicinity of ρ / (1-ρ) and is arranged between the first motor or the second motor and the carrier. Good. In the power distribution and integration mechanism of such specifications, the distribution ratio of the torque from the internal combustion engine to the carrier is larger than that of the sun gear. Therefore, by disposing the speed reduction means between the carrier and the first or second motor, it is possible to reduce the size of the first or second motor and reduce its power loss. Further, if the reduction ratio of the reduction means is set to a value in the vicinity of ρ / (1-ρ), the specifications of the first and second motors can be made substantially the same. The cost can be reduced while improving the performance. Further, the power distribution and integration mechanism, which is a double pinion planetary gear mechanism, is configured such that when the gear ratio of the power distribution and integration mechanism, which is a value obtained by dividing the number of teeth of the sun gear by the number of teeth of the ring gear, is ρ> In this case, the speed reduction means is configured such that the speed reduction ratio becomes a value in the vicinity of (1-ρ) / ρ, and the first motor or the first You may arrange | position between 2 electric motors and the said sun gear.

  The power distribution and integration mechanism is a single pinion planetary gear mechanism that includes a sun gear, a ring gear, and a carrier that holds at least one pinion gear that meshes with both the sun gear and the ring gear, and the first element is The second element is the other of the sun gear and the ring gear, the third element is the carrier, and the number of teeth of the sun gear is divided by the number of teeth of the ring gear. When the gear ratio of the power distribution and integration mechanism is ρ, the reduction means is configured such that the reduction ratio becomes a value in the vicinity of ρ, and the first or second electric motor and the ring gear It may be arranged between. In such a power distribution and integration mechanism of various specifications, the distribution ratio of torque from the internal combustion engine to the ring gear is larger than that of the sun gear. Therefore, by disposing the speed reduction means between the ring gear and the first or second motor, it becomes possible to reduce the size of the first or second motor and reduce its power loss. Furthermore, if the reduction ratio of the speed reduction means is set to a value in the vicinity of ρ, the specifications of the first and second motors can be made substantially the same, which improves the productivity of the power output device and reduces the cost. Can be reduced.

  A hybrid vehicle according to the present invention includes any one of the power output devices described above, and includes drive wheels that are driven by power from the drive shaft. The power output device installed in this hybrid vehicle is simple, compact and easy to install, and can improve power transmission efficiency in a wider driving range. And can be improved satisfactorily.

  Next, the best mode for carrying out the present invention will be described using examples.

  FIG. 1 is a schematic configuration diagram of a hybrid vehicle 20 according to an embodiment of the present invention. A hybrid vehicle 20 shown in the figure is configured as a rear-wheel drive vehicle, and includes a power distribution and integration mechanism (difference) connected to an engine 22 disposed in the front portion of the vehicle and a crankshaft 26 that is an output shaft of the engine 22. Dynamic rotation mechanism) 40, a motor MG1 capable of generating electricity connected to the power distribution and integration mechanism 40, and a power generation unit disposed coaxially with the motor MG1 and connected to the power distribution and integration mechanism 40 via the reduction gear mechanism 50. Motor MG2, a transmission 60 that can shift the power from the power distribution and integration mechanism 40 and transmit it to the drive shaft 66, and a hybrid electronic control unit (hereinafter referred to as "hybrid ECU") that controls the entire hybrid vehicle 20. 70) etc.

  The engine 22 is an internal combustion engine that outputs power when supplied with hydrocarbon fuel such as gasoline or light oil. The engine 22 controls the fuel injection amount, ignition timing, and intake from an engine electronic control unit (hereinafter referred to as “engine ECU”) 24. The air volume is controlled. The engine ECU 24 receives signals from various sensors that are provided for the engine 22 and detect the operating state of the engine 22. The engine ECU 24 communicates with the hybrid ECU 70 to control the operation of the engine 22 based on a control signal from the hybrid ECU 70, a signal from the sensor, and the like, and to transmit data on the operation state of the engine 22 as necessary. It outputs to ECU70.

  Both the motor MG1 and the motor MG2 are configured as well-known synchronous generator motors that operate as a generator and can operate as a motor, and exchange power with a battery 35 that is a secondary battery via inverters 31 and 32. Do. The power line 39 connecting the inverters 31 and 32 and the battery 35 is configured as a positive electrode bus and a negative electrode bus shared by the inverters 31 and 32, and the electric power generated by one of the motors MG1 and MG2 is supplied to the other. It can be consumed with the motor. Therefore, the battery 35 is charged / discharged by electric power generated from one of the motors MG1 and MG2 or insufficient power, and is not charged / discharged if the balance of electric power is balanced by the motors MG1 and MG2. Become. The motors MG1 and MG2 are both driven and controlled by a motor electronic control unit (hereinafter referred to as “motor ECU”) 30. The motor ECU 30 receives signals necessary for driving and controlling the motors MG1 and MG2, such as signals from rotational position detection sensors 33 and 34 for detecting the rotational positions of the rotors of the motors MG1 and MG2, and current sensors (not shown). The detected phase current applied to the motors MG1 and MG2 is input, and the motor ECU 30 outputs switching control signals and the like to the inverters 31 and 32. The motor ECU 30 executes a rotation speed calculation routine (not shown) based on signals input from the rotation position detection sensors 33 and 34, and calculates the rotation speeds Nm1 and Nm2 of the rotors of the motors MG1 and MG2. Further, the motor ECU 30 communicates with the hybrid ECU 70, and controls the drive of the motors MG1, MG2 based on a control signal from the hybrid ECU 70, and transmits data related to the operating state of the motors MG1, MG2 to the hybrid ECU 70 as necessary. Output.

  The battery 35 is managed by a battery electronic control unit (hereinafter referred to as “battery ECU”) 36. The battery ECU 36 receives signals necessary for managing the battery 35, for example, a voltage between terminals from a voltage sensor (not shown) installed between terminals of the battery 35, and a power line 39 connected to the output terminal of the battery 35. A charging / discharging current from an attached current sensor (not shown), a battery temperature Tb from a temperature sensor 37 attached to the battery 35, and the like are input. The battery ECU 36 outputs data related to the state of the battery 35 to the hybrid ECU 70 and the engine ECU 24 by communication as necessary. Further, the battery ECU 36 also calculates the remaining capacity SOC based on the integrated value of the charge / discharge current detected by the current sensor in order to manage the battery 35.

  The power distribution and integration mechanism 40 is housed in a transmission case (not shown) together with the motors MG1 and MG2, the reduction gear mechanism 50, and the transmission 60, and is arranged coaxially with the crankshaft 26 at a predetermined distance from the engine 22. The power distribution and integration mechanism 40 of the embodiment includes a sun gear 41 as an external gear, a ring gear 42 as an internal gear arranged concentrically with the sun gear 41, one of the sun gear 41 and the other as a ring gear 42. A carrier 45 that holds at least one set of two pinion gears 43 and 44 that mesh with each other so as to rotate and revolve. A sun gear 41 (second element), a ring gear 42 (third element), and a carrier 45 (first element). Is a double pinion type planetary gear mechanism configured to be capable of differential rotation with respect to each other. In the embodiment, the power distribution and integration mechanism 40 is configured such that the gear ratio ρ (the value obtained by dividing the number of teeth of the sun gear 41 by the number of teeth of the ring gear 42) is ρ <0.5. The sun gear 41, which is the second element of the power distribution and integration mechanism 40, includes a hollow sun gear shaft 41a that extends from the sun gear 41 to the side opposite to the engine 22 (rear side of the vehicle) to form a series of hollow shafts and a hollow first gear. A motor MG1 (hollow rotor) as a second electric motor is connected via the motor shaft 46. Further, the carrier 45 as the first element has a reduction gear mechanism 50 disposed between the power distribution and integration mechanism 40 and the engine 22 and a hollow first extending from the reduction gear mechanism 50 (sun gear 51) toward the engine 22. A motor MG2 (hollow rotor) as a first electric motor is connected via a two-motor shaft (second shaft) 55. Furthermore, the crankshaft 26 of the engine 22 is connected to the ring gear 42 as the third element via a ring gear shaft 42a extending through the second motor shaft 55 and the motor MG2 and the damper 28.

  The reduction gear mechanism 50 includes an external gear sun gear 51, an internal gear ring gear 52 arranged concentrically with the sun gear 51, a plurality of pinion gears 53 meshing with both the sun gear 51 and the ring gear 52, and a plurality of gears This is a single pinion type planetary gear mechanism including a carrier 54 that holds the pinion gear 53 so as to rotate and revolve. In the embodiment, the reduction gear mechanism 50 is in the vicinity of ρ / (1−ρ) when the reduction ratio (the number of teeth of the sun gear 51 / the number of teeth of the ring gear 52) is ρ as the gear ratio of the power distribution and integration mechanism 40. It is comprised so that it may become the value of. The sun gear 51 of the reduction gear mechanism 50 is connected to the rotor of the motor MG2 via the second motor shaft 55 described above. Further, the ring gear 52 of the reduction gear mechanism 50 is fixed to the carrier 45 of the power distribution and integration mechanism 40, whereby the reduction gear mechanism 50 is substantially integrated with the power distribution and integration mechanism 40. The carrier 54 of the reduction gear mechanism 50 is fixed to the transmission case. Accordingly, the power from the motor MG2 is decelerated by the action of the reduction gear mechanism 50 and input to the carrier 45 of the power distribution and integration mechanism 40, and the power from the carrier 45 is increased and input to the motor MG2. become. If the reduction gear mechanism 50 is arranged between the motor MG2 and the power distribution integration mechanism 40 and integrated with the power distribution integration mechanism 40 as in the embodiment, the power output device can be made more compact. Can do.

  Further, as shown in FIG. 1, a clutch C0 (connection / disconnection means) is provided between the sun gear shaft 41a and the first motor shaft 46 for connecting and releasing the connection. In the embodiment, the clutch C0 is, for example, a dog fixed to the tip of the sun gear shaft 41a and the tip of the first motor shaft 46 via an engagement member driven by an electric, electromagnetic, or hydraulic actuator 100. The dog is configured as a dog clutch capable of connecting the fixed dog with less loss and releasing the connection between the two. When the connection between the sun gear shaft 41a and the first motor shaft 46 by the clutch C0 is released, the connection between the motor MG1 as the second electric motor and the sun gear 41 as the second element of the power distribution and integration mechanism 40 is released. Thus, the engine 22 can be substantially separated from the motors MG1 and MG2 and the transmission 90 by the function of the power distribution and integration mechanism 40. Further, in the vicinity of the power distribution and integration mechanism 40, there is provided a brake B0 that functions as a fixing means that can fix the second motor shaft 55, which is the rotation shaft of the motor MG2, so as not to rotate. In the embodiment, the brake B0 includes a dog fixed to the carrier 45 via an engagement member driven by, for example, an electric, electromagnetic or hydraulic actuator 102 and a fixing dog fixed to the transmission case. It is configured as a dog clutch that can be connected with little loss and can be disconnected. When the dog of the carrier 45 and the dog for fixing on the transmission case side are connected by the brake B0, the carrier 45 becomes non-rotatable. Therefore, the sun gear 51 of the reduction gear mechanism 50 and the second motor are functioned by the function of the power distribution and integration mechanism 40. The shaft 55 (motor MG2) can be fixed so as not to rotate.

  Then, the first motor shaft 46 that can be connected to the sun gear 41 of the power distribution and integration mechanism 40 via the clutch C0 is further extended from the motor MG1 to the side opposite to the engine 22 (rear of the vehicle). 60 can be connected. A carrier shaft (connection shaft) 45a extends from the carrier 45 of the power distribution and integration mechanism 40 through the hollow sun gear shaft 41a and the first motor shaft 46 on the opposite side (rear side of the vehicle) from the engine 22; The carrier shaft 45 a can also be connected to the transmission 60. Accordingly, in the embodiment, the power distribution and integration mechanism 40 is disposed coaxially with the motors MG1 and MG2 between the motor MG1 and the motor MG2 disposed coaxially with each other, and the engine 22 is disposed coaxially with the motor MG2. At the same time, the transmission 60 is opposed to the transmission 60 with the power distribution and integration mechanism 40 interposed therebetween. In other words, in the embodiment, the components of the power output device such as the engine 22, the motors MG1 and MG2, the power distribution and integration mechanism 40, and the transmission 60 are the engine 22, the motor MG2, (the reduction gear mechanism 50), the power from the front of the vehicle. The distribution and integration mechanism 40, the motor MG1, and the transmission 60 are arranged in the order of being substantially coaxial. As a result, the power output apparatus can be made compact and excellent in mountability and suitable for the hybrid vehicle 20 that travels mainly by driving the rear wheels.

The transmission 60 includes a transmission differential rotation mechanism 61 that is a single-pinion planetary gear mechanism (deceleration mechanism) capable of decelerating and outputting input power at a predetermined reduction ratio, and a clutch C1 as a connecting means. Including. The transmission differential rotation mechanism 61 has a sun gear 62 as an input element, a ring gear 63 as a fixed element arranged concentrically with the sun gear 62, and an output that holds a plurality of pinion gears 64 that mesh with both the sun gear 62 and the ring gear 63. An element carrier 65 is included, and the sun gear 62 and the carrier 65 are configured to be capable of differential rotation with respect to each other. As shown in FIG. 1, the ring gear 63 of the transmission differential rotation mechanism 61 is fixed to the transmission case so as not to rotate. A drive shaft 66 extending toward the rear of the vehicle is connected to the carrier 65 of the transmission differential rotation mechanism 61. The drive shaft 66 is connected to rear wheels 69a and 69b as drive wheels via a differential gear 68. Connected.

  The clutch C1 is an input element of the differential rotation mechanism 61 for shifting either or both of the carrier shaft 45a extending from the carrier 45 as the first element of the power distribution and integration mechanism 40 and the sun gear 41 as the second element. The sun gear 62 can be selectively connected. In the embodiment, the clutch C1 includes, for example, a dog fixed to one end (right end in the figure) of the carrier shaft 45a, a dog fixed to one end (right end in the figure) of the first motor shaft 46, and the sun gear 62. The dog clutch includes a dog fixed to a sun gear shaft 62a extending forward, and an engagement member that can be engaged with the dog and driven by an electric, electromagnetic, or hydraulic actuator 101. As shown in FIG. 1, the clutch position, which is the position of the engaging member, can be selectively switched between “R position”, “M position”, and “L position”. In other words, when the clutch position of the clutch C1 of the embodiment is set to the R position, the dog of the carrier shaft 45a and the dog of the sun gear shaft 62a are connected with less loss via the engaging member, whereby the carrier shaft 45a And the carrier 45, which is the first element of the power distribution and integration mechanism 40, and the drive shaft 66 are connected via the transmission differential rotation mechanism 61 (hereinafter, the connection state by the clutch C1 is appropriately referred to as “first Element connected state). Further, when the clutch position of the clutch C1 is set to the M position, the dog of the carrier shaft 45a, the dog of the sun gear shaft 62a, and the dog of the first motor shaft 46 are connected with less loss through the engaging member, As a result, both the carrier shaft 45a and the first motor shaft 46, that is, both the carrier 45 and the sun gear 41 of the power distribution and integration mechanism 40 are connected to the drive shaft 66 via the transmission differential rotation mechanism 61 (hereinafter, referred to as “the transmission shaft”). Such a connected state by the clutch C1 is appropriately referred to as a “third connected state”). Further, when the clutch position of the clutch C1 is set to the L position, the dog of the first motor shaft 46 and the dog of the sun gear shaft 62a are connected with less loss through the engaging member, whereby the clutch C0 is connected. If connected, the sun gear 41, which is the second element of the power distribution and integration mechanism 40, and the drive shaft 66 are connected via the sun gear shaft 41a, the first motor shaft 46, and the transmission differential rotation mechanism 61 (hereinafter referred to as "this"). Such a connected state by the clutch C1 is appropriately referred to as a “second element connected state”).

  The hybrid ECU 70 is configured as a microprocessor centered on the CPU 72. In addition to the CPU 72, the ROM 74 that stores a processing program, the RAM 76 that temporarily stores data, an input / output port and a communication port (not shown) Is provided. The hybrid ECU 70 detects the ignition signal from the ignition switch (start switch) 80, the shift position SP from the shift position sensor 82 that detects the shift position SP that is the operation position of the shift lever 81, and the depression amount of the accelerator pedal 83. The accelerator opening Acc from the accelerator pedal position sensor 84, the brake pedal position BP from the brake pedal position sensor 86 for detecting the depression amount of the brake pedal 85, and the vehicle speed V from the vehicle speed sensor 87 are input via the input port. As described above, the hybrid ECU 70 is connected to the engine ECU 24, the motor ECU 30, and the battery ECU 36 via a communication port, and exchanges various control signals and data with the engine ECU 24, the motor ECU 30, and the battery ECU 36. . The hybrid ECU 70 also controls the actuators 100, 101, and 102 that drive the brake B0, the clutch C0, and the clutch C1 of the transmission 60.

  Next, the operation of the hybrid vehicle 20 according to the embodiment will be described with reference to FIGS.

  FIGS. 2 to 5 show the power distribution and integration mechanism 40 when the speed ratio of the transmission 60 is changed in the upshift direction in accordance with the change in the vehicle speed when the hybrid vehicle 20 is driven with the operation of the engine 22. 4 is an explanatory diagram illustrating the relationship between the rotational speed and torque of main elements of the transmission 60. FIG. FIG. 6 is a chart showing the clutch position setting state of the clutch C0 and the brake B0 and the clutch C1 of the transmission 60 when the hybrid vehicle 20 is traveling. When the hybrid vehicle 20 travels in the state shown in FIGS. 2 to 5, the engine ECU 24 causes the motor ECU 30 to control the engine 22 under the overall control of the hybrid ECU 70 based on the depression amount of the accelerator pedal 83 and the vehicle speed V. Thus, the motors MG1, MG2 are controlled, and the actuators 100, 101, 102 (the clutch C0, the clutch C1 of the transmission 60, the brake B0) are directly controlled by the hybrid ECU 70. 2 to 5, the S axis represents the rotation speed of the sun gear 41 of the power distribution and integration mechanism 40 (the rotation speed Nm1 of the motor MG1, that is, the first motor shaft 46), and the R axis represents the ring gear 42 of the power distribution and integration mechanism 40. , The rotation speed of the carrier 45 of the power distribution and integration mechanism 40 (rotation speed of the carrier shaft 45a and the ring gear 52 of the reduction gear mechanism 50), and the 54 axis is the reduction gear. The rotation speed of the carrier 54 of the mechanism 50 and the 51th axis indicate the rotation speed of the sun gear 51 of the reduction gear mechanism 50 (the rotation speed Nm2 of the motor MG2, that is, the second motor shaft 55). Further, the 62 axis indicates the rotation speed of the sun gear 62 of the transmission differential rotation mechanism 61 of the transmission 60, the 65 and 66 axes indicate the rotation speed of the carrier 65 and the drive shaft 66 of the transmission differential rotation mechanism 61, and the 63 axis. Indicates the number of rotations of the ring gear 63 of the transmission differential rotation mechanism 61.

  When the hybrid vehicle 20 is driven with the operation of the engine 22, the brake B0 is basically deactivated (off) and the clutch C0 is connected, and the motor MG1, that is, the first motor shaft 46 is connected to the sun gear shaft 41a. To the sun gear 41 of the power distribution and integration mechanism 40. When the vehicle speed V of the hybrid vehicle 20 is relatively low, the clutch C1 of the transmission 60 is set to the R position (see FIG. 6). Hereinafter, this state is referred to as a “first shift state (first speed)” of the transmission 60 (FIG. 2). Under such a first speed change state, the carrier 45, which is the first element of the power distribution and integration mechanism 40, is connected to the drive shaft 66 via the carrier shaft 45a, the clutch C1, and the speed change differential rotation mechanism 61. Thereby, under the first speed change state, the carrier 45 of the power distribution and integration mechanism 40 serves as an output element, and the motor MG2 connected to the carrier 45 via the reduction gear mechanism 50 functions as an electric motor and It becomes possible to drive and control the motors MG1 and MG2 so that the motor MG1 connected to the sun gear 41 serving as the force element functions as a generator. At this time, the power distribution and integration mechanism 40 distributes the power from the engine 22 input via the ring gear 42 to the sun gear 41 side and the carrier 45 side according to the gear ratio ρ, and the power from the engine 22 The power from the motor MG2 functioning as an electric motor is integrated and output to the carrier 45 side. Hereinafter, a mode in which the motor MG1 functions as a generator and the motor MG2 functions as an electric motor will be referred to as a “first torque conversion mode”. FIG. 7 shows an example of a collinear diagram showing the relationship between the rotational speed and torque in each element of the power distribution and integration mechanism 40 and each element of the reduction gear mechanism 50 in the first torque conversion mode. In FIG. 7, the S, R, C, 54, and 51 axes are the same as those in FIGS. 2 to 5, ρ is the gear ratio of the power distribution and integration mechanism 40, and ρr is the reduction gear. The reduction ratio of the mechanism 50 is shown respectively. In FIG. 7, thick arrows indicate the torque acting on each element. When the arrow is upward in the figure, the torque value is positive, and when the arrow is downward in the figure, the torque value is Is negative (the same applies to FIGS. 2 to 5, 8, and 9). Under the first torque conversion mode, the power from the engine 22 is torque-converted by the power distribution and integration mechanism 40 and the motors MG1 and MG2 and output to the carrier 45, and by controlling the rotation speed of the motor MG1, The ratio between the rotational speed of the engine 22 and the rotational speed of the carrier 45 as an output element can be continuously and continuously changed. The power output to the carrier 45 is transmitted to the sun gear 62 of the transmission differential rotation mechanism 61 via the carrier shaft 45a and the clutch C1, and the gear ratio ρx of the transmission differential rotation mechanism 61 (FIG. 2), the speed is changed (decelerated) at a speed ratio (ρx / (1 + ρx)), and then output to the drive shaft 66.

  When the vehicle speed V of the hybrid vehicle 20 increases in the state shown in FIG. 2, that is, in the state where the transmission 60 is in the first shift state and the torque conversion mode is the first torque conversion mode, the carrier 45 of the power distribution and integration mechanism 40 eventually The rotational speed and the rotational speed of the sun gear 41 are substantially matched. Thus, the clutch C1 is set to the M position, the dog of the carrier shaft 45a, the dog of the sun gear shaft 62a and the dog of the first motor shaft 46 are connected, and both the carrier 45 and the sun gear 41 of the power distribution and integration mechanism 40 are connected. Can be coupled to the transmission differential rotation mechanism 61. If the torque command for the motors MG1 and MG2 is set to 0 with the clutch C1 of the transmission 60 set to the M position, the motors MG1 and MG2 perform both power running and regeneration as shown in FIG. The engine rotates idly without being executed, and the power (torque) from the engine 22 is fixed (constant) without any conversion to electric energy (shift based on the gear ratio ρx of the transmission differential rotation mechanism 61). Ratio) is mechanically (directly) transmitted to the drive shaft 66. Hereinafter, such a mode in which both the carrier 45 and the sun gear 41 of the power distribution and integration mechanism 40 are connected to the transmission differential rotation mechanism 61 by the clutch C1 is referred to as a “simultaneous engagement mode”. 3 is referred to as “1-2 speed simultaneous engagement state”.

  3, since the rotational speeds of the carrier shaft 45a and the first motor shaft 46 coincide with each other, the clutch position of the clutch C1 of the transmission 60 is set to the M position. It is possible to easily switch from the L position to the L position to release the connection between the carrier shaft 45a and the transmission differential rotation mechanism 61. Hereinafter, the state where the clutch C0 is engaged and the brake B0 is turned off and the clutch C1 is set to the L position is referred to as a second speed change state (second speed) of the transmission 60 (FIG. 4). Under such a second speed change state, the sun gear 41 as the second element of the power distribution and integration mechanism 40 is driven via the sun gear shaft 41a, the first motor shaft 46, the clutch C1, and the transmission differential rotation mechanism 61. 66. Thus, under the second speed change state, the sun gear 41 of the power distribution and integration mechanism 40 serves as an output element, and the motor MG1 connected to the sun gear 41 functions as an electric motor and serves as a reaction force element on the carrier 45. It becomes possible to drive and control the motors MG1 and MG2 so that the connected motor MG2 functions as a generator. At this time, the power distribution and integration mechanism 40 distributes the power from the engine 22 input via the ring gear 42 to the sun gear 41 side and the carrier 45 side according to the gear ratio ρ, and the power from the engine 22 The power from the motor MG1 functioning as an electric motor is integrated and output to the sun gear 41 side. Hereinafter, a mode in which the motor MG2 functions as a generator and the motor MG1 functions as an electric motor will be referred to as a “second torque conversion mode”. FIG. 8 shows an example of a collinear diagram showing the relationship between the rotational speed and torque in each element of the power distribution and integration mechanism 40 and each element of the reduction gear mechanism 50 in the second torque conversion mode. The reference numerals in FIG. 8 are the same as those in FIG. Under the second torque conversion mode, the power from the engine 22 is torque-converted by the power distribution and integration mechanism 40 and the motors MG1 and MG2 and output to the sun gear 41, thereby controlling the rotational speed of the motor MG2. The ratio between the rotational speed of the engine 22 and the rotational speed of the sun gear 41 as an output element can be continuously and continuously changed. The power output to the sun gear 41 is transmitted to the sun gear 62 of the transmission differential rotation mechanism 61 via the sun gear shaft 41a, the first motor shaft 46, and the clutch C1, and the transmission differential rotation mechanism 61. After being shifted (decelerated) at a speed ratio (ρx / (1 + ρx)) based on the gear ratio ρx, the speed is output to the drive shaft 66.

  When the vehicle speed V of the hybrid vehicle 20 increases in the state shown in FIG. 4, that is, when the transmission 60 is in the second shift state and the torque conversion mode is the second torque conversion mode, the motor MG2, the second motor shaft 55, and The rotation speed of the carrier 45 as the first element of the power distribution and integration mechanism 40 approaches the value 0. As a result, the brake B0 is activated (turned on) so that the second motor shaft 55 (motor MG2) and the carrier 45 can be fixed in a non-rotatable manner. Then, the torque command for the motors MG1 and MG2 is set while the second motor shaft 55 and the carrier 45 are fixed to be non-rotatable by the brake B0 while the first motor shaft 46 is connected to the transmission differential rotation mechanism 61 by the clutch C1. If set to 0, the motors MG1 and MG2 idle without performing either power running or regeneration, and the power (torque) from the engine 22 is fixed without being converted into electric energy ( The gear is shifted at a constant speed ratio (a gear ratio ρ based on the gear ratio ρ of the power distribution and integration mechanism 40 and the gear ratio ρx of the transmission differential rotation mechanism 61) and then directly transmitted to the drive shaft 66. Become. Hereinafter, the second motor shaft 55 and the carrier 45 cannot be rotated by the brake B0 while the first motor shaft 46 is connected to the transmission differential rotation mechanism 61 by the clutch C1 of the transmission 60 with the clutch C0 connected in this manner. The mode to be fixed to is also referred to as “simultaneous engagement mode”, and in particular, the state shown in FIG. 5 is referred to as “second speed fixed state”. It should be noted that when changing the gear ratio of the transmission 60 in the shift-down direction, a procedure reverse to the above description may be basically executed.

  As described above, in the hybrid vehicle 20 of the embodiment, the first torque conversion mode and the second torque conversion mode are alternately switched in accordance with the switching of the first and second shift states of the transmission 60. When the rotational speed Nm2 or Nm1 of the functioning motor MG2 or MG1 increases, the rotational speed Nm1 or Nm2 of the motor MG1 or MG2 functioning as a generator can be prevented from having a negative value. Therefore, in the hybrid vehicle 20, the motor MG2 generates power and uses the motor MG2 using a part of the power output to the carrier 45 when the rotational speed of the motor MG1 becomes negative under the first torque conversion mode. The power output to the sun gear 41 when the rotational speed of the motor MG2 becomes negative under the power circulation in which the motor MG1 consumes the electric power generated by the motor MG1 to output the power and the second torque conversion mode. It is possible to suppress the generation of power circulation in which the motor MG1 generates power using a part of the motor MG1 and the motor MG2 consumes the electric power generated by the motor MG1 and outputs power. The transmission efficiency can be improved. Moreover, since the maximum number of rotations of the motors MG1 and MG2 can be suppressed along with such suppression of power circulation, the motors MG1 and MG2 can be downsized. Furthermore, if the hybrid vehicle 20 is run under the above-described simultaneous engagement mode, the power from the engine 22 can be mechanically (directly) transmitted to the drive shaft 66 at a fixed gear ratio. The opportunity to mechanically output power from the engine 22 to the drive shaft 66 without conversion into energy can be increased, and the power transmission efficiency can be further improved in a wider operating range. In general, in a power output device using an engine, two electric motors, and a power distribution and integration mechanism such as a planetary gear mechanism, the engine power is converted into electric energy when the reduction ratio between the engine and the drive shaft is relatively large. Since the power transmission efficiency deteriorates and the motors MG1 and MG2 tend to generate heat, the simultaneous engagement mode described above particularly compares the reduction ratio between the engine 22 and the drive shaft. This is particularly advantageous when the size is large. Further, in the hybrid vehicle 20 according to the embodiment, when the transmission state of the transmission 60 is changed, the simultaneous engagement mode is temporarily executed between the first torque conversion mode and the second torque conversion mode. There is no so-called torque loss when the state is changed, and the change of the shift state, that is, the switching between the first torque conversion mode and the second torque conversion mode can be performed extremely smoothly and without shock.

  Subsequently, with reference to FIGS. 6 and 9 and the like, the motor MG1 and the motor MG2 are powered by using the electric power from the battery 35 in a state where the engine 22 is stopped, thereby causing the motor 20 to run the hybrid vehicle 20. An outline of the travel mode will be described. In the hybrid vehicle 20 of the embodiment, the motor travel mode is the clutch engagement 1 in which the clutch C0 is connected and the motor MG1 is connected to the sun gear 41 of the power distribution and integration mechanism 40 and power is output to one of the motors MG1 and MG2. A motor travel mode, a clutch release 1 motor travel mode in which power is output to one of the motors MG1 and MG2 in a state where the connection between the motor MG1 by the clutch C0 and the sun gear 41 of the power distribution and integration mechanism 40 is released; The motor MG1 and the sun gear 41 of the power distribution and integration mechanism 40 are roughly divided into two-motor travel modes that allow the power from both the motors MG1 and MG2 to be used. When the motor travel mode is selected, the brake B0 is inactivated (see FIG. 6).

  When the clutch engagement 1 motor traveling mode is executed, the transmission C60 is set to the first shift state by setting the clutch C1 to the R position as shown in FIG. The power is output only to MG2 or the clutch C1 is set to the L position as shown in FIG. 6 with the clutch C0 engaged, so that the transmission 60 is set to the second shift state and the power is supplied only to the motor MG1. Output. Under the clutch engagement 1 motor traveling mode, the sun gear 41 of the power distribution and integration mechanism 40 and the first motor shaft 46 are connected by the clutch C0, so that the motor MG1 or MG2 not outputting power is Then, the motor MG2 or MG1 that outputs power is idled to rotate idly (see the broken line in FIG. 9). Further, when the clutch release 1 motor running mode is executed, the clutch C1 is set to the R position as shown in FIG. 6 with the clutch C0 disconnected from the motor MG1 and the sun gear 41 of the power distribution and integration mechanism 40. Thus, the transmission 60 is set to the first shift state and power is output only to the motor MG2, or the clutch C1 is set to the L position as shown in FIG. 6 to set the transmission 60 to the second shift state. Set and output power only to motor MG1. Under such a clutch disengagement 1 motor traveling mode, as shown by a one-dot chain line and a two-dot chain line in FIG. 9, the connection between the sun gear 41 and the motor MG1 by the clutch C0 is released. The rotation of the crankshaft 26 of the engine 22 stopped due to the function and the rotation of the stopped motor MG1 or MG2 are avoided, thereby suppressing a reduction in power transmission efficiency. Further, when the two-motor travel mode is executed, the clutch C1 is set to the M position as shown in FIG. 6 in a state where the connection between the motor MG1 and the sun gear 41 of the power distribution and integration mechanism 40 by the clutch C0 is released. As a result, the transmission 60 is set to the above-described 1-2 speed simultaneous engagement state, and at least one of the motors MG1 and MG2 is driven and controlled. As a result, it is possible to output power from both the motors MG1 and MG2 while avoiding the rotation of the engine 22, and to transmit a large amount of power to the drive shaft 66 under the motor traveling mode, so that the so-called slope start is good. It is possible to carry out the operation and to ensure good towing performance and the like when the motor is running.

  In the hybrid vehicle 20 of the embodiment, when the clutch disengagement 1 motor traveling mode is selected, the shift state of the transmission 60 can be easily changed to efficiently transmit power to the drive shaft 66. For example, the first motor shaft 46 is rotationally synchronized with the carrier shaft 45a when the transmission 60 is set to the first shift state and power is output only to the motor MG2 under the clutch release 1 motor travel mode. If the rotational speed Nm1 of the motor MG1 is adjusted so that the clutch position of the clutch C1 of the transmission 60 is switched from the R position to the M position, the shift to the above-described 1-2 speed simultaneous engagement state, that is, the 2-motor traveling mode is made. can do. In this state, if the clutch position of the clutch C1 is switched from the M position to the L position and power is output only to the motor MG1, the power output by the motor MG1 under the above-described second shift state is used as the drive shaft. 66 can be transmitted. In the case of changing the shift state of the transmission 60 in the shift-down direction under the clutch disengagement 1 motor travel mode, the procedure reverse to the above description may be basically executed. As a result, in the hybrid vehicle 20 of the embodiment, the torque can be amplified by shifting the rotation speed of the carrier 45 and the sun gear 41 using the transmission 60 even in the motor travel mode. Therefore, the maximum torque required for the motor MG1 and MG2 can be reduced. Further, even when the transmission state of the transmission 60 is changed during such motor traveling, since the simultaneous engagement state of the transmission 60, that is, the two-motor traveling mode is executed once, so-called torque loss at the time of changing the transmission state is performed. Therefore, the shift state can be changed very smoothly and without shock. Note that when the required driving force is increased or the remaining capacity SOC of the battery 35 is decreased under these motor travel modes, the speed change state of the transmission 60 (the clutch position of the clutch C1) is determined. Then, cranking of the engine 22 by the motor MG1 or MG2 that does not output power is executed, thereby starting the engine 22.

As described above, the hybrid vehicle 20 of the embodiment has the sun gear 62 as the input element, the ring gear 63 as the fixed element, and the carrier 65 as the output element connected to the drive shaft 66, and the sun gear 62 and the carrier 65 are mutually connected. Either one or both of the transmission differential rotation mechanism 61 configured to be capable of differential rotation, the carrier 45 as the first element of the power distribution and integration mechanism 40, and the sun gear 41 as the second element are differentially rotated for transmission. A transmission 60 including a clutch C1 that can be selectively coupled to the sun gear 62 of the mechanism 61 is provided. The transmission 60 can be configured with relatively few parts, has a simple and compact configuration, and is excellent in mountability. In the hybrid vehicle 20, if either the carrier 45 or the sun gear 41 of the power distribution and integration mechanism 40 is connected to the sun gear 62 of the transmission differential rotation mechanism 61 by the clutch C <b> 1 of the transmission 60, the power distribution and integration mechanism The power from the 40 carriers 45 or the sun gear 41 can be output to the drive shaft 66 after being shifted by the transmission differential rotation mechanism 61. Furthermore, in the hybrid vehicle 20, if both the carrier 45 and the sun gear 41 of the power distribution and integration mechanism 40 are connected to the sun gear 62 of the transmission differential rotation mechanism 61 by the clutch C <b> 1 of the transmission 60, the power from the engine 22 is fixed. The transmission ratio can be mechanically (directly) transmitted to the drive shaft 66. When the carrier 45 of the power distribution and integration mechanism 40 is coupled to the sun gear 62 of the transmission differential rotation mechanism 61 by the clutch C1 of the transmission 60, a motor as a first electric motor connected to the carrier 45 serving as an output element. It is possible to make MG2 function as an electric motor and to make motor MG1 as a second electric motor connected to sun gear 41 serving as a reaction force element function as a generator. When the sun gear 41 of the power distribution and integration mechanism 40 is coupled to the sun gear 62 of the transmission differential rotation mechanism 61 by the clutch C1 of the transmission 60, the motor MG1 connected to the sun gear 41 serving as an output element functions as an electric motor. In addition, the motor MG2 connected to the carrier 45 serving as a reaction force element can function as a generator. Thereby, in the hybrid vehicle 20, the motor MG1 functioning as a generator when the rotational speed Nm2 or Nm1 of the motor MG2 or MG1 functioning as an electric motor is increased by appropriately switching the connection state by the clutch C1 or Generation of so-called power circulation can be suppressed by preventing the rotation speed Nm1 or Nm2 of MG2 from becoming a negative value. As a result, in the hybrid vehicle 20, it is possible to improve the power transmission efficiency in a wider driving range, and it is possible to improve the fuel consumption and the driving performance.

  In addition, if the transmission differential rotation mechanism 61 of the transmission 60 is a single pinion planetary gear mechanism as in the embodiment, the transmission 60 can be configured more compactly. However, the transmission differential rotation mechanism 61 of the transmission 60 includes a first sun gear and a second sun gear having different numbers of teeth, a first pinion gear that meshes with the first sun gear, and a second pinion gear that meshes with the second sun gear. And a planetary gear mechanism that includes a carrier that holds at least one stepped gear. If a planetary gear mechanism including such a stepped gear is used as the transmission differential rotation mechanism 61, a transmission having a single pinion planetary gear mechanism that tends to increase the rotation speed of the pinion gear when setting a larger reduction ratio. As compared with the above, a larger reduction ratio can be easily set. Further, if the motors MG1 and MG2 are arranged substantially coaxially with the engine 22 and the power distribution and integration mechanism 40 is arranged substantially coaxially between the motors MG1 and MG2 as in the embodiment, the power constituted by these motors The entire output device can be configured more compactly. The hybrid vehicle 20 in which the engine 22, the motors MG <b> 1, MG <b> 2, and the power distribution and integration mechanism 40 are arranged substantially coaxially as described above is connected to the sun gear 41 of the power distribution and integration mechanism 40 and is directed toward the transmission 60. A sun gear shaft 41a and a first motor shaft 46 as hollow shafts that extend, and a connecting shaft that is connected to the carrier 45 and extends toward the transmission 60 through the sun gear shaft 41a and first motor shaft 46 as a hollow shaft. The clutch C1 of the transmission 60 selectively connects one or both of the first motor shaft 46 and the carrier shaft 45a to the sun gear 62 of the transmission differential rotation mechanism 61. It is configured to be possible. As a result, the power from the carrier 45 of the power distribution and integration mechanism 40 and the power from the sun gear 41 can be output substantially coaxially and in the same direction, so that the transmission 60 is integrated with the engine 22, the motors MG1 and MG2, and the power distribution and integration. It becomes possible to arrange it substantially coaxially with the mechanism 40. Therefore, this configuration is extremely suitable for the hybrid vehicle 20 that travels mainly by driving the rear wheels.

  Furthermore, the brake B0 provided in the hybrid vehicle 20 can fix the second motor shaft 55, which is the rotation shaft of the motor MG2, so as not to rotate. Therefore, as described above, when the sun gear 41 of the power distribution and integration mechanism 40 connected to the motor MG1 is coupled to the drive shaft 66 via the clutch C1 of the transmission 60 and the transmission differential rotation mechanism 61, the second gear. Even if the motor shaft 55 is fixed to be non-rotatable by the brake B0, the power from the engine 22 can be mechanically (directly) transmitted to the drive shaft 66 at a fixed gear ratio. As a result, in the hybrid vehicle 20, the power transmission efficiency can be improved satisfactorily in a wider driving range. The fixing means as described above may be any means that fixes the rotation of the element (the sun gear 41 in the embodiment) that becomes the reaction force element of the power distribution and integration mechanism when the minimum speed ratio by the transmission is set. Depending on the configuration of the transmission, the first motor shaft 46 or the sun gear 41 of the motor MG1 may be fixed. Further, instead of using the dedicated brake B0 as the fixing means, the function of the fixing means may be given to the clutch C0.

  The hybrid vehicle 20 of the embodiment includes the sun gear shaft 41a and the first motor shaft 46, that is, the clutch C0 that executes the connection between the sun gear 41 and the motor MG1 and the release of the connection. Thus, in the hybrid vehicle 20, if the connection between the sun gear shaft 41a and the first motor shaft 46 by the clutch C0 is released, the engine 22 is substantially driven by the functions of the power distribution and integration mechanism 40 by the motors MG1 and MG2 and the transmission 60. It becomes possible to separate from. Therefore, in the hybrid vehicle 20, if the clutch C0 is released and the engine 22 is stopped, the power from at least one of the motors MG1 and MG2 is applied to the drive shaft 66 with a change in the shift state of the transmission 60. It can be transmitted efficiently. As a result, in hybrid vehicle 20, the maximum torque required for motors MG1 and MG2 can be reduced, and further miniaturization of motors MG1 and MG2 can be achieved. However, the clutch C0 is not limited to the one that executes the connection between the sun gear 41 and the motor MG1 and the release of the connection. That is, the clutch C0 may execute connection between the carrier 45 (first element) and the second motor shaft 55 (motor MG2) and release of the connection, and the crankshaft 26 and the ring gear 42 of the engine 22 may be executed. Connection with (third element) and cancellation of the connection may be executed.

  Further, when the power distribution and integration mechanism 40 which is a double pinion planetary gear mechanism having a gear ratio ρ of less than 0.5 is employed as in the hybrid vehicle 20 of the embodiment, the carrier 45 is compared with the sun gear 41. The torque distribution ratio from the engine 22 is increased. Therefore, by arranging the reduction gear mechanism 50 between the carrier 45 and the motor MG2 as in the example of FIG. 1, it is possible to reduce the size of the motor MG2 and reduce its power loss. In this case, if the gear ratio of the power distribution and integration mechanism 40 is ρ, and the reduction ratio ρr of the reduction gear mechanism 50 is a value in the vicinity of ρ / (1-ρ), the motors MG1 and MG2 Since the specifications can be made substantially the same, the productivity of the hybrid vehicle 20 and the power output device can be improved and the cost can be reduced. However, the power distribution and integration mechanism 40 that is a double pinion planetary gear mechanism may be configured such that the gear ratio satisfies ρ> 0.5. In this case, the reduction gear mechanism 50 has a reduction ratio of ( 1−ρ) / ρ, and may be arranged between the sun gear 11 and the motor MG1 or MG2.

  FIG. 10 is a schematic configuration diagram of a hybrid vehicle 20A according to a modification. In the hybrid vehicle 20A shown in the figure, the functions of the clutch C0 and the brake B0 of the hybrid vehicle 20 described above are shared by the clutch C0 'and the brake B0' driven by the hydraulic actuator 88, respectively. The hybrid vehicle 20A also includes a transmission 60A in which the functions of the clutch C1 described above are shared by the clutches C1a and C1b driven by the hydraulic actuator 88, respectively. That is, in the hybrid vehicle 20A of the modified example, it is possible to execute connection between the sun gear 41 of the power distribution and integration mechanism 40 and the first motor shaft 46 (motor MG1) and release of the connection by driving the clutch C0 ′. Thus, by driving the brake B0, it is possible to fix the second motor shaft 55, which is the rotation shaft of the motor MG2, so that it cannot rotate. Further, the first element in which the carrier 45 as the first element of the power distribution and integration mechanism 40 and the drive shaft 66 are connected via the carrier shaft 45a and the transmission differential rotation mechanism 61 by connecting the clutch C1a of the transmission 60A. A connected state can be realized. Further, by connecting the clutch C1b, the sun gear 41 as the second element of the power distribution and integration mechanism 40 and the drive shaft 66 are connected via the sun gear shaft 41a, the first motor shaft 46, and the transmission differential rotation mechanism 61. A two-element connected state can be realized. Further, by connecting both of the clutches C1a and C1b, a dual element connection state is realized in which both the carrier 45 and the sun gear 41 of the power distribution and integration mechanism 40 are connected to the drive shaft 66 via the transmission differential rotation mechanism 61. It becomes possible. FIG. 11 shows the setting states of the clutch positions of the clutch C0 ′, the brake B0 ′, the clutches C1a and C1b of the transmission 60A, and the like during travel of the hybrid vehicle 20A. Thus, also in the hybrid vehicle 20A including the hydraulic clutch C0 ′ and the brake B0 ′ and the transmission 60A including the hydraulic clutches C1a and C1b, the same operational effects as the above-described hybrid vehicle 20 are obtained. be able to.

  FIG. 12 is a schematic configuration diagram of a hybrid vehicle 20B according to another modification. The hybrid vehicles 20 and 20A described above are configured as rear wheel drive vehicles, whereas the hybrid vehicle 20B according to the modified example is configured as a front wheel drive vehicle. As shown in FIG. 12, the hybrid vehicle 20 </ b> B has a sun gear 11 that is an external gear, an inner tooth formed on the inner periphery thereof, and an outer tooth formed on the outer periphery thereof, and is disposed concentrically with the sun gear 11. It includes a ring gear 12 and a carrier 14 that holds a plurality of pinion gears 13 that mesh with both the sun gear 11 and the internal teeth of the ring gear 12, and includes the sun gear 11 (second element), the ring gear 12 (first element), and the carrier 14 (third And a power distribution and integration mechanism 10 which is a single pinion type planetary gear mechanism configured to be capable of differentially rotating with respect to each other. In the embodiment, the power distribution and integration mechanism 10 is configured such that the gear ratio ρ (the value obtained by dividing the number of teeth of the sun gear 11 by the number of teeth of the ring gear 12) is ρ <0.5. The sun gear 11 as the second element of the power distribution and integration mechanism 10 includes a motor MG1 (second motor) via a sun gear shaft 11a extending from the sun gear 11 to the opposite side of the engine 22, a clutch C0, and a first motor shaft 46. Rotor) is connected. The ring gear 12 as the first element includes a reduction gear mechanism 50 disposed on the engine 22 side of the power distribution and integration mechanism 10 and a hollow second motor extending from the reduction gear mechanism 50 (sun gear 51) toward the engine 22. A motor MG2 (hollow rotor) as a first electric motor is connected via a shaft 55. Further, the crankshaft 26 of the engine 22 is connected to the carrier 14 as the third element via a carrier shaft 14a and a damper 28 extending through the second motor shaft 55 and the motor MG2.

  The hybrid vehicle 20B includes a transmission 90 different from the transmissions 60 and 60A. The transmission 90 is attached to the first motor shaft 46 and the first connecting gear train that is constituted by the ring gear 12 of the power distribution and integration mechanism 10 and the first driven gear 91 that always meshes with the external teeth of the ring gear 12. The second connecting gear train composed of the drive gear 47 and the second driven gear 92 that is always meshed with the drive gear 47, and the crankshaft 26, the first motor shaft 46, and the second motor shaft 55 of the engine 22 extend in parallel. An existing transmission shaft 93, a transmission differential rotation mechanism 94 that is a single pinion planetary gear mechanism, and a clutch C1 are included. The first driven gear 91 of the first connecting gear train is attached to a hollow first gear shaft 91a that is rotatably supported by a bearing (not shown) and extends in parallel with the first motor shaft 46 and the second motor shaft 55. ing. The second driven gear 92 is rotatably supported by a bearing (not shown) at a predetermined distance from the first gear shaft 91a and extends in parallel with the first motor shaft 46 and the second motor shaft 55. It is attached to a hollow second gear shaft 92a. In the embodiment, the number of teeth of the outer teeth of the ring gear 12 constituting the first connecting gear train and the drive gear 47 constituting the second connecting gear train is the same, and the first tooth constituting the first connecting gear train. The number of teeth of the driven gear 91 and the second driven gear 92 constituting the second connecting gear train are the same, but the number of teeth of these gears can be arbitrarily determined.

The transmission shaft 93 extends in parallel with the first motor shaft 46 and the second motor shaft 55 through the inside of the first and second gear shafts 91a and 92a described above, and at its tip (right end in the figure), A transmission differential rotation mechanism 94 is connected. The transmission differential rotation mechanism 94 holds a sun gear 95 connected to the transmission shaft 93, a ring gear 96 arranged concentrically with the sun gear 95, and a plurality of pinion gears 97 that mesh with both the sun gear 95 and the ring gear 96. The sun gear 95 (input element) and the carrier 98 (output element) are configured to be capable of differential rotation with each other. As shown in FIG. 12, the ring gear 96 of the transmission differential rotation mechanism 94 is fixed to the transmission case so as not to rotate. Further, here, a hollow carrier shaft 98a is connected to the carrier 98 of the transmission differential rotation mechanism 94, and the transmission shaft 93 is fixed to the sun gear 95 through the carrier shaft 98a. Thereby, in the transmission 90, the hollow second gear shaft 92a to which the second driven gear 92 is attached and the hollow to which the first driven gear 91 is attached are sequentially arranged around the transmission shaft 93 from the left side in the drawing. The first gear shaft 91a and the hollow carrier shaft 98a are arranged. The carrier 98 is connected to front wheels 69c and 69d as drive wheels via an output gear 99 attached to the end of the carrier shaft 98a, a gear mechanism 67 including a drive shaft 66, and a differential gear 68.

  The clutch C1 included in the transmission 90 is disposed in the vicinity of between the first gear shaft 91a and the second gear shaft 92a, and either one or both of the first gear shaft 91a and the second gear shaft 92a are connected. It can be connected to the transmission shaft 93. In the embodiment, the clutch C1 is, for example, a transmission shaft so as to be positioned between a dog fixed to one end (the left end in the drawing) of the first gear shaft 91a and the first gear shaft 91a and the second gear shaft 92a. 93, a dog fixed to one end (right end in the figure) of the second gear shaft 92a, and a dog that can be engaged with these dogs and driven by an electric, electromagnetic, or hydraulic actuator 101. As shown in FIG. 12, the clutch position that is the position of the engaging member can be selectively switched between “R position”, “M position”, and “L position”. is there. That is, when the clutch position of the clutch C1 of the transmission 90 is set to the R position, the first dog of the first gear shaft 91a and the dog of the transmission shaft 93 are connected with less loss through the engagement member. As a result, the ring gear 12 as the first element of the power distribution and integration mechanism 10 is connected to the drive shaft 66 via the first connection gear train, the first gear shaft 91a, the transmission shaft 93, the transmission differential rotation mechanism 94, and the like. First element connection state). Further, when the clutch position of the clutch C1 is set to the M position, the first dog of the first gear shaft 91a, the dog of the transmission shaft 93, and the dog of the second gear shaft 92a are less lost through the engaging member. Accordingly, both the first gear shaft 91a and the second gear shaft 92a, that is, both the ring gear 12 and the sun gear 11 of the power distribution and integration mechanism 10 are connected to the first and second connection gear trains, the transmission shaft 93, It is connected to the drive shaft 66 through the transmission differential rotation mechanism 94 and the like (both elements are connected). Further, when the clutch position of the clutch C1 is set to the L position, the dog of the second gear shaft 92a and the dog of the transmission shaft 93 are connected with less loss via the engaging member, whereby the clutch C0 is connected. If the M position is set, the sun gear 11 as the second element of the power distribution and integration mechanism 10 is driven by the second connecting gear train, the second gear shaft 92a, the transmission shaft 93, the transmission differential rotation mechanism 94, and the like. 66 (second element connected state).

  Thus, the hybrid vehicle according to the present invention may be configured as a front-wheel drive vehicle, and the hybrid vehicle 20B of FIG. 12 can obtain the same operational effects as the above-described hybrid vehicles 20, 20A. The hybrid vehicle 20B of FIG. 12 includes a transmission shaft 93 extending in parallel with the first and second motor shafts 46, 55, a parallel shaft type first and second connecting gear train, and a clutch C1 as a switching means. According to such a transmission 90, the power output device is a two-shaft type by disposing the clutch C <b> 1 and the transmission differential rotation mechanism 94 around the transmission shaft 93 coaxially therewith. Even if the engine 22, the motors MG1 and MG2, and the power distribution and integration mechanism 10 are arranged substantially coaxially, an increase in the axial direction (vehicle width direction) size of the power output device can be suppressed. . Therefore, the power output apparatus of FIG. 12 is compact and excellent in mountability, and is extremely suitable for the hybrid vehicle 20B that travels mainly by driving the front wheels. Further, like the transmission 90, if the sun gear 11 and the ring gear 12 of the power distribution and integration mechanism 10 are connected to the transmission shaft 93 via the parallel shaft type first connection gear train and the second connection gear train, It is also possible to freely set the speed ratio between the sun gear 11 or the ring gear 12 and the transmission shaft 93. As a result, the degree of freedom in setting the gear ratio of the transmission 90 can be increased, and the power transmission efficiency can be further improved. In the example of FIG. 12, external gears are formed on the ring gear 12 of the power distribution and integration mechanism 10 and the ring gear 12 itself constitutes the second connecting gear train. However, the present invention is not limited to this. That is, instead of forming external teeth on the ring gear 12, a gear similar to the drive gear 47 may be connected to the ring gear 12 and meshed with the first driven gear 91 to constitute the first connection gear train. . Furthermore, as described above, the hybrid vehicle 20B includes the power distribution and integration mechanism 10 that is a single pinion type planetary gear mechanism in which the gear ratio ρ is less than 0.5. In the distribution integration mechanism 10, the torque distribution ratio from the engine 22 to the ring gear 12 is larger than that of the sun gear 41. Accordingly, as shown in FIG. 12, by arranging the reduction gear mechanism 50 between the ring gear 12 and the motor MG2, it is possible to reduce the size of the motor MG2 and reduce its power loss. In this case, if the reduction ratio ρr of the reduction gear mechanism 50 is a value in the vicinity of the gear ratio ρ of the power distribution and integration mechanism 40, the specifications of the motors MG1 and MG2 can be made substantially the same. Therefore, the productivity of the engine 22 and the power output device can be improved and the cost can be reduced.

  FIG. 13 is a schematic configuration diagram of a hybrid vehicle 20C according to still another modification. In the hybrid vehicle 20C shown in the figure, the functions of the clutch C0 and the brake B0 of the hybrid vehicle 20B described above are shared by the clutch C0 'and the brake B0' driven by a hydraulic actuator 88C, respectively. The hybrid vehicle 20C includes a transmission 90C in which the function of the clutch C1 of the hybrid vehicle 20B described above is shared by the clutches C1a and C1b driven by the hydraulic actuator 88C, respectively. In the hybrid vehicle 20C shown in FIG. 13 as well, if the clutch C0 ′, the brake B0 ′, and the clutches C1a and C1b of the transmission 90C are controlled as shown in FIG. 11, the above-described hybrid vehicles 20, 20A, 20B and Similar effects can be obtained.

  In the hybrid vehicles 20, 20A, 20B, and 20C described above, a mechanism for connecting and releasing the sun gear 41 (11) and the motor MG1, and the second motor shaft 55 (carrier 45 or ring gear 12) are provided. Any or all of the fixing mechanism and the reduction gear mechanism 50 may be omitted. The hybrid vehicles 20 and 20A may be configured as rear-wheel drive-based four-wheel drive vehicles, and the hybrid vehicles 20B and 20C may be configured as front-wheel drive-based four-wheel drive vehicles. May be. Furthermore, in the hybrid vehicles 20 and 20A described above, the power distribution and integration mechanism 40 meshes with the first sun gear and the second sun gear having different numbers of teeth, and the first pinion gear and the second sun gear that mesh with the first sun gear. It may be a planetary gear mechanism including a carrier that holds at least one stepped gear that is connected to the second pinion gear. In the hybrid vehicles 20B and 20C described above, the power distribution and integration mechanism 40 may be configured as a double pinion planetary gear mechanism. Further, in the above embodiment, the power output device is described as being mounted on the hybrid vehicles 20, 20A, 20B, 20C. However, the power output device according to the present invention can be used for moving vehicles other than automobiles, ships, airplanes, and the like. It may be mounted on the body or may be incorporated in a fixed facility such as a construction facility.

  The embodiments of the present invention have been described above using the embodiments. However, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the scope of the present invention. Needless to say.

1 is a schematic configuration diagram of a hybrid vehicle 20 according to an embodiment of the present invention. When the hybrid vehicle 20 of the embodiment is driven with the operation of the engine 22, the power distribution and integration mechanism 40 and the transmission 60 when the transmission ratio of the transmission 60 is changed in the upshift direction according to the change in the vehicle speed. It is explanatory drawing which illustrates the relationship between the rotation speed and torque of a main element. It is explanatory drawing similar to FIG. It is explanatory drawing similar to FIG. It is explanatory drawing similar to FIG. It is a chart which shows the setting state of clutch position of clutch C0, brake B0, and clutch C1 of transmission 60 at the time of running of hybrid car 20 of an example. An example of a collinear diagram showing the relationship between the rotational speed and torque in each element of the power distribution and integration mechanism 40 and each element of the reduction gear mechanism 50 when the motor MG1 functions as a generator and the motor MG2 functions as an electric motor. It is explanatory drawing shown. An example of a collinear diagram showing the relationship between the rotational speed and torque in each element of the power distribution and integration mechanism 40 and each element of the reduction gear mechanism 50 when the motor MG2 functions as a generator and the motor MG1 functions as an electric motor. It is explanatory drawing shown. It is explanatory drawing for demonstrating the motor driving mode in the hybrid vehicle 20 of an Example. It is a schematic block diagram of the hybrid vehicle 20A of a modification. 10 is a chart showing the setting states of the clutch C0 ′, the brake B0 ′, the clutch positions of the clutches C1a and C1b of the transmission 60A, and the like during travel of the hybrid vehicle 20A of a modified example. It is a schematic block diagram of the hybrid vehicle 20B of the modification. It is a schematic block diagram of the hybrid vehicle 20C of the modification.

Explanation of symbols

  20, 20A, 20B, 20C Hybrid vehicle, 22 engine, 24 engine electronic control unit (engine ECU), 26 crankshaft, 28 damper, 30 motor electronic control unit (motor ECU), 31, 32 inverter, 33, 34 Rotation position detection sensor, 35 battery, 36 battery electronic control unit (battery ECU), 37 temperature sensor, 39 power line, 40, 10 power distribution integration mechanism, 41, 11, 51, 62, 95 sun gear, 41a, 62a, 11a Sun gear shaft, 42, 12, 52, 63, 96 Ring gear, 42a Ring gear shaft, 43, 44, 13, 53, 64, 97 Pinion gear, 45, 14, 54, 65, 98 Carrier, 45a, 14a, 98a Carrier shaft 46 first motor shaft, 7 drive gear, 50 reduction gear mechanism, 55 second motor shaft, 60, 60A, 90, 90C transmission, 61 differential rotation mechanism for transmission, 66 drive shaft, 67 gear mechanism, 68 differential gear, 69a, 69b rear wheel , 69c, 69d Front wheel, 70 Hybrid electronic control unit (hybrid ECU), 72 CPU, 74 ROM, 76 RAM, 80 ignition switch, 81 shift lever, 82 shift position sensor, 83 accelerator pedal, 84 accelerator pedal position sensor, 85 Brake pedal, 86 Brake pedal position sensor, 87 Vehicle speed sensor, 88, 88C, 100, 101, 102 Actuator, 91 First driven gear, 91a First gear shaft, 92 Second driven gear, 92a Second gear shaft, 93 Transmission axis , 94 gear shift differential rotation mechanism, 99 output gear, B0, B0 'brake, C0, C0', C1, C1a, C1b clutch, MG1, MG2 motor.

Claims (11)

A power output device that outputs power to a drive shaft,
An internal combustion engine;
A first electric motor capable of inputting and outputting power;
A second electric motor capable of inputting and outputting power;
A first element connected to the rotating shaft of the first electric motor, a second element connected to the rotating shaft of the second electric motor, and a third element connected to the engine shaft of the internal combustion engine. A power distribution and integration mechanism configured to allow the elements to differentially rotate relative to each other;
A differential rotation mechanism for speed change having an input element, a fixed element, and an output element connected to the drive shaft, and configured so that the input element and the output element can differentially rotate with each other, and the power distribution integration Shift transmission means including connection means capable of selectively connecting either one or both of the first element and the second element of the mechanism to the input element of the transmission differential rotation mechanism;
Fixing means capable of fixing any one of the rotation shaft of the first motor and the rotation shaft of the second motor to be non-rotatable;
When the first or second element of the power distribution and integration mechanism connected to the first or second electric motor not corresponding to the fixing means is coupled to the input element of the differential rotation mechanism for shifting. Control means for controlling the fixing means so that the rotation shaft of the second or first motor corresponding to the fixing means is fixed in a non-rotatable manner;
Equipped with a,
The control means includes one of the first and second elements of the power distribution and integration mechanism connected to the second or first electric motor corresponding to the fixing means, and the input element of the differential rotation mechanism for shifting. , A state where both the first and second elements of the power distribution and integration mechanism and the input element of the differential transmission rotating mechanism are connected, and the fixing means does not correspond. A state in which the other of the first and second elements of the power distribution and integration mechanism connected to the first or second electric motor and the input element of the transmission differential rotation mechanism are coupled; and the power distribution and integration The second or first electric motor in which the other of the first and second elements of the mechanism is connected to the input element of the differential rotation mechanism for shifting and is connected to one of the first and second elements. The rotation axis of the motor is fixed so that it cannot rotate. Power output device state and is that control said coupling means so as to switch selectively the said fixing means are. The power output apparatus according to claim 1 , wherein the shift differential rotation mechanism of the shift transmission unit is a three-element planetary gear mechanism. It said first and second electric motor is disposed substantially coaxially with said internal combustion engine, the power distribution and integration mechanism according to claim 1 is positioned generally coaxially with both the electric motor between the second motor and the first motor or the power output apparatus according to 2. In the power output device according to claim 3 ,
A hollow shaft connected to any one of the first and second elements of the power distribution and integration mechanism and extending toward the transmission unit;
A connecting shaft connected to the other of the first and second elements and extending through the hollow shaft toward the speed change transmission means;
The connecting means of the speed change transmission means is a power output device capable of selectively connecting either one or both of the hollow shaft and the connecting shaft to the input element of the differential rotation mechanism for shifting. Connection between the first motor and the first element and release of the connection; connection between the second motor and the second element; release of the connection; connection between the internal combustion engine and the third element; The power output apparatus according to any one of claims 1 to 4 , further comprising connection / disconnection means capable of executing either of the cancellation of the connection. One of the first and second elements of the power distribution and integration mechanism to which a larger torque is input from the third element connected to the engine shaft is the rotation shaft of the first motor or the second motor. The power output device according to any one of claims 1 to 5 , wherein the power output device is connected to the first electric motor or the second electric motor via a speed reduction unit that decelerates the rotation of the motor. The power output apparatus according to claim 6, wherein
The power distribution and integration mechanism includes a sun gear, a ring gear, and a double pinion planetary gear mechanism that includes a carrier that holds at least one set of two pinion gears that mesh with each other and one meshes with the sun gear and the other meshes with the ring gear. The first element is one of the sun gear and the carrier, the second element is the other of the sun gear and the carrier, and the third element is the ring gear. The power output apparatus according to claim 7 ,
The power distribution and integration mechanism is configured such that ρ <0.5, where ρ is a gear ratio of the power distribution and integration mechanism, which is a value obtained by dividing the number of teeth of the sun gear by the number of teeth of the ring gear. The speed reduction means is configured to have a speed reduction ratio in the vicinity of ρ / (1−ρ) and is arranged between the first motor or the second motor and the carrier. The power output apparatus according to claim 7 ,
The power distribution and integration mechanism is configured such that ρ> 0.5 when a gear ratio of the power distribution and integration mechanism, which is a value obtained by dividing the number of teeth of the sun gear by the number of teeth of the ring gear, is ρ. The power reduction device is configured such that the speed reduction ratio is a value in the vicinity of (1-ρ) / ρ, and is disposed between the first motor or the second motor and the sun gear. The power output apparatus according to claim 6 , wherein
The power distribution and integration mechanism is a single pinion type planetary gear mechanism including a sun gear, a ring gear, and a carrier that holds at least one pinion gear that meshes with both the sun gear and the ring gear, and the first element is the sun gear. And the second element is the other of the sun gear and the ring gear, and the third element is the carrier.
When the gear ratio of the power distribution and integration mechanism, which is a value obtained by dividing the number of teeth of the sun gear by the number of teeth of the ring gear, is ρ, the reduction means is configured such that the reduction ratio becomes a value in the vicinity of ρ. And a power output device disposed between the first or second electric motor and the ring gear. A hybrid vehicle comprising the power output device according to any one of claims 1 to 10 and including drive wheels driven by power from the drive shaft.

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