CN111806218B

CN111806218B - Hybrid power drive system and method

Info

Publication number: CN111806218B
Application number: CN201910290865.9A
Authority: CN
Inventors: 周文太; 朱永明; 祁宏钟; 罗宇亮; 涂序聪; 魏丹
Original assignee: Guangzhou Automobile Group Co Ltd
Current assignee: Guangzhou Automobile Group Co Ltd
Priority date: 2019-04-11
Filing date: 2019-04-11
Publication date: 2022-01-18
Anticipated expiration: 2039-04-11
Also published as: CN111806218A

Abstract

A hybrid power driving system comprises an engine, a first clutch, an input shaft, a first motor, a planetary gear device, a second clutch, a braking device, an intermediate shaft, a second motor and a differential mechanism, wherein the planetary gear device comprises a sun gear, a planet carrier and a gear ring; the planet carrier is connected with the intermediate shaft; the second motor is connected with the intermediate shaft; the intermediate shaft is connected with the differential; the first clutch is used for combining or separating the engine and the input shaft, the second clutch is used for combining or separating the sun gear and the gear ring, and the braking device is used for braking or unlocking the sun gear; when the first clutch couples the engine and the input shaft and the brake device unlocks the sun gear, the second clutch or the brake device applies a slip friction torque to the sun gear. The hybrid power driving system can avoid the problem of gear knocking. The invention also relates to a hybrid power driving method.

Description

Hybrid power drive system and method

Technical Field

The invention relates to the technical field of new energy, in particular to a hybrid power driving system and a method.

Background

Due to the fact that the combustion torque of the engine is uneven, the cylinder pressure of the engine pulsates along with the stroke, the torque of the engine pulsates and the rotation speed of the engine fluctuates, the rotation speed fluctuation is difficult to completely eliminate by a torsional damper or a dual-mass flywheel, and the rotation speed fluctuation is transmitted to the hybrid electromechanical coupling device after passing through the torsional damper or the dual-mass flywheel.

The gear is a common power transmission device in the hybrid electromechanical coupling device, because the gear transmission generates heat, the gear is heated and expanded to cause tooth surface abrasion, and in order to ensure the service life of the gear, a certain gear gap is required to be kept between the gears which are meshed with each other.

Because of the gear clearance, the fluctuation of the rotating speed of the engine is transmitted to the hybrid electromechanical coupling device and the rotating speed of the gear in the device also fluctuates, so that the idle driven gear in the device is contacted with the driving gear sometimes and separated sometimes, the gear knocking problem is further generated, and the adverse effect is caused on the experience of a driver and passengers.

Disclosure of Invention

In view of the above, the present invention provides a hybrid driving system, which can avoid the problem of gear rattle.

A hybrid drive system comprising an engine, a first clutch, an input shaft, a first motor, a planetary gear arrangement, a second clutch, a brake arrangement, an intermediate shaft, a second motor, and a differential, the planetary gear arrangement comprising a sun gear, a planet carrier, and a ring gear, wherein: the engine is connected with the input shaft through the first clutch, and the first motor is connected with the input shaft; the planet carrier is connected with the intermediate shaft; the second motor is connected with the intermediate shaft; the intermediate shaft is connected with the differential; the first clutch is used for combining or separating the engine and the input shaft, the second clutch is used for combining or separating the sun gear and the gear ring, and the braking device is used for braking or unlocking the sun gear; when the first clutch couples the engine and the input shaft and the brake unlocks the sun gear, the second clutch or the brake applies a slip friction torque to the sun gear.

In an embodiment of the present invention, a first gear and a second gear are fixedly disposed on the intermediate shaft, a differential gear is disposed on the differential, the first gear is engaged with the planet carrier, and the second gear is engaged with the differential gear.

In an embodiment of the present invention, the second motor has a second motor output shaft, and a third gear is fixedly disposed on the second motor output shaft, and the third gear is meshed with the first gear.

In an embodiment of the present invention, the first motor has a first motor output shaft, a fourth gear is fixedly disposed on the first motor output shaft, a fifth gear is fixedly disposed on the input shaft, and the fourth gear and the fifth gear are engaged with each other.

In an embodiment of the present invention, the hybrid drive system has a dual-motor electric-only first-gear mode, in which the first clutch is disengaged and the second clutch is disengaged, and the brake device brakes the sun gear and is driven by the first motor and the second motor.

In an embodiment of the invention, the hybrid drive system has a dual-motor electric-only second-gear mode, in which the first clutch is disengaged and the second clutch is engaged, and the brake device unlocks the sun gear and is driven by the first motor and the second motor.

In an embodiment of the present invention, the hybrid drive system has a parallel hybrid first-gear mode in which the first clutch is engaged, the second clutch is disengaged, the sun gear is braked by the brake device, and the engine, the first motor, and the second motor drive the sun gear; the hybrid power driving system has a parallel hybrid two-gear mode, in which the first clutch is engaged, the second clutch is engaged, and the brake device unlocks the sun gear and is driven by the engine, the first motor, and the second motor.

In an embodiment of the present invention, the hybrid drive system has a series hybrid mode in which the first clutch is engaged, the second clutch is disengaged, the sun gear is unlocked by the brake device, the engine drives the first motor to generate electric power, and the second motor drives the first motor to generate electric power.

The present invention also provides a hybrid driving method using the above hybrid driving system, the hybrid driving method including:

when the first clutch couples the engine and the input shaft and the brake device unlocks the sun gear, the second clutch or the brake device applies a slip friction torque to the sun gear.

In an embodiment of the present invention, the hybrid driving method further includes:

selecting a working mode of the hybrid power driving system, wherein when the hybrid power driving system is in a series hybrid mode, the first clutch is combined, the second clutch is separated, the sun gear is unlocked by the braking device, and the engine drives the first motor to generate power and is driven by the second motor;

detecting whether the brake device is in fault, and controlling the brake device to apply sliding friction torque to the sun gear when the brake device is in a normal state;

and when the second clutch is in a normal state, controlling the second clutch to apply a sliding friction torque to the sun gear.

The hybrid power driving system can avoid the problem of gear knocking when the engine inputs power and the sun gear is in an idle state. The hybrid power driving system does not need to adjust the torque of the second motor coupled with the wheel end, has small influence on the drivability and ensures the stable running of the vehicle.

Drawings

Fig. 1 is a schematic configuration diagram of a hybrid drive system of the present invention.

FIG. 2 is a lever diagram schematic of the hybrid drive system of the present invention in a series hybrid mode.

FIG. 3 is a schematic flow chart of the hybrid drive method of the present invention for optimizing gear rattle.

Detailed Description

Fig. 1 is a schematic configuration diagram of a hybrid drive system of the present invention. As shown in fig. 1, the hybrid drive system includes an engine 11, a first clutch 12, an input shaft 13, a first electric machine 14, a planetary gear device 15, a second clutch 16, a brake device 17, an intermediate shaft 18, a second electric machine 19, a differential 20, and a power battery (not shown). The planetary gear device 15 includes a sun gear 151, a carrier 152, and a ring gear 153.

The engine 11 is connected to the input shaft 13 through the first clutch 12, and the first electric machine 14 is connected to the input shaft 13. The first clutch 12 is used to couple or decouple the engine 11 and the input shaft 13. When the first clutch 12 is engaged, the power of the engine 11 can be transmitted to the input shaft 13; when the first clutch 12 is disengaged, the engine 11 is disconnected from the input shaft 13. In the present embodiment, the engine 11 is a gasoline engine or a diesel engine, and the first electric machine 14 is a drive and power generation integrated machine.

The first motor 14 has a first motor output shaft 141, a fourth gear 142 is fixedly disposed on the first motor output shaft 141, a fifth gear 131 is fixedly disposed on the input shaft 13, and the fourth gear 142 and the fifth gear 131 are engaged with each other.

The ring gear 153 is fixed to the input shaft 13 so that the input shaft 13 and the ring gear 153 can rotate synchronously. The planet carrier 152 is provided with planet wheels 154, the planet wheels 154 are connected to the planet carrier 152 through rolling bearings or sliding bearings, and the planet wheels 154 are meshed with the sun gear 151 and the ring gear 153 respectively.

The second clutch 16 is used to couple or decouple the sun gear 151 and the ring gear 153. When the second clutch 16 is engaged, the sun gear 151 and the ring gear 153 are locked together; when the second clutch 16 is disengaged, the sun gear 151 and the ring gear 153 are disengaged from each other.

The brake device 17 is used to brake or unlock the sun gear 151. The braking device 17 is, for example, a brake or a one-way clutch. When the brake device 17 brakes the sun gear 151, the sun gear 151 is fixed against rotation with respect to the input shaft 13; when the brake 17 unlocks the sun gear 151, the sun gear 151 can rotate relative to the input shaft 13.

The planet carrier 152 is connected with the intermediate shaft 18, specifically, a first gear 181 and a second gear 182 are fixedly arranged on the intermediate shaft 18, the first gear 181 and the second gear 182 are arranged at intervals, and the first gear 181 is meshed with the planet carrier 152.

The second motor 19 is connected with the intermediate shaft 18, specifically, the second motor 19 is arranged in parallel with the first motor 14, the second motor 19 has a second motor output shaft 191, a third gear 192 is fixedly arranged on the second motor output shaft 191, and the third gear 192 is meshed with the first gear 181. In the present embodiment, the second motor 19 is a driving and power generating integrated machine.

The intermediate shaft 18 is connected with a differential 20, specifically, a differential gear 201 is arranged on the differential 20, and the differential gear 201 is meshed with the second gear 182. The differential 20 is used for adjusting the difference between the rotating speeds of the left wheel and the right wheel, so that the left wheel and the right wheel roll at different rotating speeds when the automobile turns or runs on an uneven road surface, and the pure rolling motion of the wheels driven by the two sides is ensured.

The power battery is electrically connected with the first motor 14 and the second motor 19 respectively. The power battery supplies electric energy for driving the first electric motor 14 and the second electric motor 19, and the electric energy generated when the first electric motor 14 and the second electric motor 19 are driven to rotate can be stored in the power battery.

In the present embodiment, when the first clutch 12 couples the engine 11 and the input shaft 13 and the brake device 17 unlocks the sun gear 151, the fluctuation of the rotation speed of the engine 11 is transmitted to the planetary gear device 15, so that the NVH problem such as gear rattling occurs between the sun gear 151 and the planetary gears 154 in the idle state, and the sun gear 151 is not in the idle state by applying the slip friction torque to the sun gear 151 by the second clutch 16 or the brake device 17, thereby avoiding the NVH problem such as gear rattling.

The hybrid power driving system has a dual-motor pure electric first gear mode, a dual-motor pure electric second gear mode, a parallel hybrid first gear mode, a parallel hybrid second gear mode and a series hybrid mode.

Specifically, in the two-motor electric-only first-gear mode, the first clutch 12 is disengaged, the second clutch 16 is disengaged, the sun gear 151 is braked by the brake device 17, the engine 11 is not started, and the first motor 14 and the second motor 19 are driven. The power transmission has two paths, wherein the first path is transmitted to the first gear 181, the intermediate shaft 18, the second gear 182, the differential gear 201, the differential 20 and finally the wheels 30 by the first motor 14 through the gear ring 153 and the planet carrier 152; path two is transmitted by the second motor 19 through the third gear 192 to the first gear 181, the intermediate shaft 18, the second gear 182, the differential gear 201, the differential 20, and finally to the wheels 30.

In the two-motor electric-only second-gear mode, the first clutch 12 is disengaged, the second clutch 16 is engaged, the sun gear 151 is unlocked by the brake device 17, the engine 11 is not started, and the first motor 14 and the second motor 19 drive the engine. At this time, since the second clutch 16 is engaged, the carrier 152 and the ring gear 153 are locked together, so that the entire planetary gear device is fixedly connected as a unit and integrally rotated at a speed ratio of 1. The power transmission has two paths, wherein the first path is transmitted to the first gear 181, the intermediate shaft 18, the second gear 182, the differential gear 201, the differential 20 and finally the wheels 30 by the first motor 14 through the whole planetary gear device 15; path two is transmitted by the second motor 19 through the third gear 192 to the first gear 181, the intermediate shaft 18, the second gear 182, the differential gear 201, the differential 20, and finally to the wheels 30.

In the parallel hybrid first-speed mode, the first clutch 12 is engaged, the second clutch 16 is disengaged, and the sun gear 151 is braked by the brake device 17 and driven by the engine 11, the first electric machine 14, and the second electric machine 19. The power transmission has three paths, wherein the path one is transmitted from the engine 11 to the intermediate shaft 18, the second gear 182, the differential gear 201, the differential 20 and finally to the wheels 30 through the input shaft 13, the gear ring 153, the planet carrier 152 and the first gear 181; path two, the first motor 14 transmits the power to the first gear 181, the intermediate shaft 18, the second gear 182, the differential gear 201, the differential 20, and finally the wheels 30 through the ring gear 153 and the planet carrier 152; path three is transmitted by the second motor 19 through the third gear 192 to the first gear 181, the intermediate shaft 18, the second gear 182, the differential gear 201, the differential 20, and finally to the wheels 30.

In the parallel hybrid second-speed mode, the first clutch 12 is engaged, the second clutch 16 is engaged, the sun gear 151 is unlocked by the brake device 17, and the engine 11, the first electric machine 14, and the second electric machine 19 are driven. At this time, since the second clutch 16 is engaged, the carrier 152 and the ring gear 153 are locked together, so that the entire planetary gear device is fixedly connected as a unit and integrally rotated at a speed ratio of 1. The power transmission has three paths, wherein the path one is transmitted from the engine 11 to the first gear 181, the intermediate shaft 18, the second gear 182, the differential gear 201, the differential 20 and finally to the wheels 30 through the whole planetary gear device; path two, from the first electric machine 14 through the whole planetary gear to the first gear 181, the intermediate shaft 18, the second gear 182, the differential gear 201, the differential 20, and finally to the wheels 30; path three is transmitted by the second motor 19 through the third gear 192 to the first gear 181, the intermediate shaft 18, the second gear 182, the differential gear 201, the differential 20, and finally to the wheels 30.

FIG. 2 is a lever diagram schematic of the hybrid drive system of the present invention in a series hybrid mode. As shown in fig. 1 and 2, in the series hybrid mode, the first clutch 12 is engaged, the second clutch 16 is disengaged, the sun gear 151 is unlocked by the brake device 17, the engine 11 is started to drive the first electric machine 14 to generate electric power, and the second electric machine 19 is driven by the first electric machine 14 to supply electric power to the second electric machine 19. The electric energy generated by the engine 11 driving the first electric machine 14 to rotate can also be stored in a power battery, and the power battery provides the electric energy required by the second electric machine 19. The power transmission has a path from the second electric machine 19 through the third gear 192 to the first gear 181, the intermediate shaft 18, the second gear 182, the differential gear 201, the differential 20, and finally to the wheels 30. Because the fluctuation of the rotation speed of the engine 11 is transmitted to the planetary gear device 15, the problem of NVH such as gear knocking will occur between the sun gear 151 and the planet gears 154 in the idle state, and the second clutch 16 or the brake device 17 is controlled to apply a sliding friction torque to the sun gear 151, so that the sun gear 151 is not in the idle state, and the problem of NVH such as gear knocking is avoided.

The hybrid power driving system provided by the embodiment of the invention has a double-motor pure electric first-gear mode, a double-motor pure electric second-gear mode, a parallel hybrid first-gear mode, a parallel hybrid second-gear mode and a series hybrid mode, and can automatically realize the switching of different modes according to the SOC (residual electric quantity) value of a power battery and the vehicle speed requirement. For example, judging the magnitude relation between the SOC value of the power battery and a first threshold value, or simultaneously judging the magnitude relation between the SOC value of the power battery and the first threshold value and the magnitude relation between the vehicle speed and a second threshold value; and switching the working mode of the hybrid power driving system according to the judgment result. It should be noted that the first threshold is used to determine the SOC value of the power battery, and the second threshold is used to determine the vehicle speed, and the embodiment does not limit the value ranges of the first threshold and the second threshold, and may be freely set according to a specific control strategy, and the values of the first threshold and the second threshold are different under different control strategies. After the first threshold value and the second threshold value are set, automatic judgment is carried out, and automatic switching is carried out among various modes according to the judgment result.

The present invention also relates to a hybrid driving method using the above hybrid driving system, the hybrid driving method including:

when the first clutch 12 couples the engine 11 and the input shaft 13, and the brake 17 unlocks the sun gear 151, the second clutch 16 or the brake 17 applies a slip friction torque to the sun gear 151.

Specifically, FIG. 3 is a schematic flow chart of the hybrid drive method of the present invention for optimizing gear rattle. As shown in fig. 1 and 3, the hybrid driving method further includes:

selecting a working mode of a hybrid power driving system, wherein the hybrid power driving system has a double-motor pure electric first-gear mode, a double-motor pure electric second-gear mode, a parallel hybrid first-gear mode, a parallel hybrid second-gear mode and a series hybrid mode; when the power battery is sufficient in electric quantity, low in speed, medium and small in torque working conditions or medium speed and small torque working conditions, a pure electric mode is selected, and switching is performed between a double-motor pure electric first-gear mode and a double-motor pure electric second-gear mode according to the accelerator opening of a driver; when the power battery is in low electric quantity, low vehicle speed, medium and small torque working conditions or medium vehicle speed and small torque working conditions, a series hybrid mode is selected; and when the working condition of large torque or high vehicle speed is adopted, the parallel hybrid mode is selected, and the parallel hybrid first-gear mode and the parallel hybrid second-gear mode are switched according to the opening degree of the accelerator of the driver.

Step one, judging whether a hybrid power driving system works in a series hybrid mode, and setting the sliding friction torque of a braking device 17 as 0 and the sliding friction torque of a second clutch 16 as 0 when the hybrid power driving system does not work in the series hybrid mode; when the hybrid drive system is in the series hybrid mode, the first clutch 12 is engaged, the second clutch 16 is disengaged, the sun gear 151 is unlocked by the brake device 17, and the engine 11 drives the first electric machine 14 to generate electric power and the second electric machine 19 to drive it.

And step two, detecting the current vehicle speed. The higher the vehicle speed is, the larger the wind noise, the tire noise and the road noise of the whole vehicle are, and when the vehicle speed is higher than a certain threshold value, the wind noise, the tire noise and the road noise of the whole vehicle can completely cover the gear knocking sound, the gear knocking optimization control is not required to be implemented, the sliding friction torque of the brake device 17 is set to be 0, the sliding friction torque of the second clutch 16 is set to be 0, and the gear knocking optimization control process is quitted.

Step three, detecting whether the brake device 17 is in fault, controlling the brake device 17 to apply a sliding friction torque to the sun gear 151 when the brake device 17 is in a normal state, and setting the sliding friction torque of the second clutch 16 to be 0; because one end of the braking device 17 is connected to the housing, and the other end is connected to the sun gear 151, the braking device 17 loads the sliding friction torque on the sun gear 151, so that the sun gear 151 is not in an idle state, the sun gear 151 is tightly attached to the planet gears 154, and the problem of gear knocking between the sun gear 151 and the planet gears 154 is avoided.

When the brake device 17 is in a failure state, detecting whether the second clutch 16 is failed, and when the second clutch 16 is in a normal state, controlling the second clutch 16 to apply a slip friction torque to the sun gear 151, and setting the slip friction torque of the brake device 17 to 0; since one end of the second clutch 16 is connected to the ring gear 153 and the other end is connected to the sun gear 151, the second clutch 16 applies a sliding friction torque to the sun gear 151, so that the sun gear 151 is not in an idle state, and the sun gear 151 is tightly attached to the planet gears 154, thereby avoiding the problem of gear knocking between the sun gear 151 and the planet gears 154.

When the second clutch 16 is detected to be in a fault state, setting the sliding friction torque of the brake device 17 to be 0, setting the sliding friction torque of the second clutch 16 to be 0, and exiting the gear knocking optimization control process.

It is worth mentioning that the purpose of implementing the gear rattle optimization control by preferentially using the braking device 17 is: the rotating speed difference between the two ends of the friction plate of the working condition braking device 17 is smaller, and the sliding friction power of the friction plate is controlled to be lower by using the braking device 17 to carry out gear knocking optimization.

In summary, the hybrid power driving system provided by the embodiment of the invention has a simpler overall structure, can realize a dual-motor pure electric first gear mode, a dual-motor pure electric second gear mode, a parallel hybrid first gear mode, a parallel hybrid second gear mode and a series hybrid mode, and has stronger flexibility. When the operation mode is switched, the second motor 19 is driven, and there is no interruption in power. Further, the hybrid drive system of the present invention can avoid the problem of gear rattle when the engine 11 inputs power and the sun gear 151 is in an idle state. The hybrid power driving system of the invention does not need to adjust the torque of the second motor 19 coupled with the wheel end, has little influence on the drivability and ensures the stable running of the vehicle. The hybrid power driving system can be applied to two-wheel drive vehicles or four-wheel drive vehicles, and is good in platformization.

Further, the invention also provides a vehicle comprising the hybrid power driving system.

The above embodiments are only examples of the present invention and are not intended to limit the scope of the present invention, and all equivalent changes and modifications made according to the contents described in the claims of the present invention should be included in the claims of the present invention.

Claims

1. Hybrid drive system, comprising an engine (11), a first clutch (12), an input shaft (13), a first electric machine (14), a planetary gear (15), a second clutch (16), a braking device (17), an intermediate shaft (18), a second electric machine (19) and a differential (20), the planetary gear (15) comprising a sun gear (151), a planet carrier (152) and a ring gear (153), wherein:

the engine (11) is connected with the input shaft (13) through the first clutch (12), and the first motor (14) is connected with the input shaft (13);

the planet carrier (152) is connected with the intermediate shaft (18);

the second motor (19) is connected with the intermediate shaft (18);

the intermediate shaft (18) is connected with the differential (20);

the first clutch (12) is used for combining or separating the engine (11) and the input shaft (13), the second clutch (16) is used for combining or separating the sun gear (151) and the gear ring (153), the braking device (17) is used for braking or unlocking the sun gear (151), and the gear ring (153) is fixed on the input shaft (13);

when the first clutch (12) couples the engine (11) and the input shaft (13) and the brake device (17) unlocks the sun gear (151), the second clutch (16) or the brake device (17) applies a slip friction torque to the sun gear (151).

2. Hybrid drive system according to claim 1, characterized in that a first gear (181) and a second gear (182) are fixedly arranged on the intermediate shaft (18), a differential gear (201) is arranged on the differential (20), the first gear (181) is in mesh with the planet carrier (152), and the second gear (182) is in mesh with the differential gear (201).

3. A hybrid drive system according to claim 2, wherein the second electric machine (19) has a second electric machine output shaft (191), a third gear (192) being fixedly arranged on the second electric machine output shaft (191), the third gear (192) being in mesh with the first gear (181).

4. A hybrid drive system according to claim 3, wherein the first electric machine (14) has a first electric machine output shaft (141), a fourth gear (142) is fixedly arranged on the first electric machine output shaft (141), a fifth gear (131) is fixedly arranged on the input shaft (13), and the fourth gear (142) and the fifth gear (131) are mutually meshed.

5. Hybrid drive system according to any one of claims 1 to 4, characterized in that it has a dual-motor electric-only first gear mode in which the first clutch (12) is disengaged, the second clutch (16) is disengaged, and the braking device (17) brakes the sun gear (151) to be driven by the first electric motor (14) and the second electric motor (19).

6. Hybrid drive system according to any one of claims 1 to 4, characterized in that it has a two-motor electric-only second gear mode, in which the first clutch (12) is disengaged and the second clutch (16) is engaged, the braking device (17) unlocking the sun gear (151) and being driven by the first electric motor (14) and the second electric motor (19).

7. Hybrid drive system according to any one of claims 1 to 4, characterized in that it has a parallel hybrid first gear mode in which said first clutch (12) is engaged, said second clutch (16) is disengaged, said braking means (17) brakes said sun gear (151), driven by said engine (11), said first electric machine (14) and said second electric machine (19); the hybrid drive system has a parallel hybrid second-speed mode in which the first clutch (12) is engaged, the second clutch (16) is engaged, and the brake device (17) unlocks the sun gear (151) and is driven by the engine (11), the first motor (14), and the second motor (19).

8. A hybrid drive system according to any one of claims 1 to 4, characterized in that it has a series hybrid mode in which said first clutch (12) is engaged, said second clutch (16) is disengaged, said braking device (17) unlocks said sun gear (151), said engine (11) drives said first electric machine (14) for generating electric power, driven by said second electric machine (19).

9. A hybrid driving method that utilizes the hybrid driving system according to any one of claims 1 to 8, the hybrid driving method comprising:

10. The hybrid driving method according to claim 9, characterized by further comprising:

selecting an operating mode of the hybrid drive system, wherein when the hybrid drive system is in a series hybrid mode, the first clutch (12) is engaged, the second clutch (16) is disengaged, the sun gear (151) is unlocked by the braking device (17), and the engine (11) drives the first motor (14) to generate electricity and the second motor (19) to drive the first motor;

detecting whether the brake device (17) is in failure, and controlling the brake device (17) to apply a sliding friction torque to the sun gear (151) when the brake device (17) is in a normal state;

when the brake device (17) is in a failure state, whether the second clutch (16) is in failure is detected, and when the second clutch (16) is in a normal state, the second clutch (16) is controlled to apply a slip friction torque to the sun gear (151).