CN217835329U - Four-wheel drive power device - Google Patents

Abstract

The utility model provides a four-wheel drive power device relates to the electric motor car field, and power device comprises two double entry clutches and two planet speed change mechanism and three motors, realizes that three motors directly drive, one-level variable speed, second grade variable speed, two grades of variable speeds, forerunner, rear-guard and four-wheel drive's multiple power performance combination, structural integration, compact, the function pluralism makes the electric motor car move under the operating mode condition of full condition in wide range high efficiency operating region.

Description

Four-wheel drive power device

Technical Field

The utility model relates to a new forms of energy electric motor car field especially relates to a four-wheel drive power device.

Background

The structure and the operation mode of the new energy electric vehicle power device directly influence the operation performance and the driving mileage of the electric vehicle and directly influence the efficiency and the cost of the full-working-condition operation of the electric vehicle. The conventional four-wheel drive power device of the electric vehicle usually adopts two groups of power assemblies which are arranged in a front-back separated mode, the assembly size and the function have single limitation, and the power assembly device needs to be improved to increase the endurance mileage and reduce the running cost and the space occupancy rate thereof.

Disclosure of Invention

The utility model provides a four-wheel drive power device relates to electric motor car and power assembly field. The utility model discloses power device integrates two compound clutch and two planetary gear and three motor drive mechanism as an organic whole, realizes directly driving, one-level variable speed, second grade variable speed and two grades of speed reduction increase square, and the acceleration rate subtracts the multiple power transmission mode of square, provides forerunner's, rear-guard and four-wheel drive operation function for the electric motor car. The speed-increasing transmission function of the power device is suitable for high-speed running of the electric vehicle on an expressway, and the defect that the electric energy loss is increased by a controller flux weakening control mode when the driving motor of the electric vehicle runs at a high speed at present is avoided. The three motors adopt a power split mode, and the rated power and the rotating speed of each power are reasonably set according to the running rule of the running condition of the vehicle, so that the vehicle can more run in a wide high-efficiency working range under the full-working condition. The utility model discloses the arrangement mode is nimble, both can indulge the front and back axostylus axostyle that sets up this device and stretch and connect electric motor car front axle differential mechanism respectively, also can transversely connect left and right sides semi-axis in electric motor car front axle or rear axle, compact structure, and occupation space is few, increases the continuation of the journey mileage, reduces whole car configuration and running cost.

The four-wheel drive power device is characterized by comprising the first transmission power device, the second transmission power device and the third transmission power device;

the first transmission comprises the first planetary gear set, the first motor and the first double clutch;

the first motor comprises the first stator, the first rotor and the first rotating shaft, the first stator is connected with the inner wall of the shell, the first rotating shaft is sleeved in the first rotor in a hollow mode, and the first rotor is rotatably arranged in the first stator inner bore;

the first double clutch comprises the second output shaft, the first clutch and the second clutch which are arranged on the second output shaft in a repeated way, and the first flywheel and the second flywheel which are correspondingly and separately coupled with the first clutch and the second clutch;

the first planetary set comprises the first central wheel, the first planet carrier, the first gear ring, the first output shaft, the first synchronizer and the second synchronizer, the first central wheel is concentrically sleeved on the needle roller bearing at the left end of the first rotating shaft, the first gear ring is connected with the inner wall of the shell, the first planet wheel is meshed with the outer teeth of the first central wheel and the inner teeth of the first gear ring, the first planet carrier is connected with the first planet wheel and concentrically sleeved at the right end of the first output shaft, the first flywheel is sleeved at the left end of the first output shaft, the first synchronizer is a bidirectional synchronizer and is positioned between the first central wheel and the first planet carrier and respectively connected or separated with the left-side joint gear ring of the first central wheel and the right-side joint gear ring of the first planet carrier, and the second synchronizer is positioned at the right side of the first central wheel and connected or separated from the right-side joint gear ring of the first central wheel;

the second transmission power device consists of the second planetary set, the second motor and the second multiple clutch;

the second motor comprises a second stator and a second rotor, the second rotating shaft is hollow and internally sleeved in a central hole of the second rotor, the second stator is fixedly arranged on the inner wall of the shell, the second rotor is rotatably arranged in the inner bore of the first stator, and the power, the rotating speed and the torque of the first motor and the second motor are different;

the second compound clutch comprises the fourth output shaft, the third flywheel and the third clutch, the fourth flywheel and the fourth clutch, the third clutch and the fourth clutch are sleeved on the fourth output shaft in an overlapping manner, and the third flywheel and the fourth flywheel are correspondingly and separately coupled with the third clutch and the fourth clutch;

the second planet group comprises the second central gear and the second planet gear, the second gear ring, the second planet carrier and the third planet carrier, the third output shaft, the third synchronizer and the fourth synchronizer, the second gear ring is fixedly arranged on the inner wall of the shell, the second central gear is sleeved on a needle roller bearing at the right end of the second rotating shaft, the second planet gear is engaged with the outer teeth of the second central gear and the inner teeth of the second gear ring, the second planet carrier is sleeved on the left end of the third output shaft, the third flywheel is sleeved on the right end of the third output shaft, the third planet carrier is positioned at the left side of the second central gear and is connected with the second rotating shaft through the needle roller bearing, the fourth synchronizer is a bidirectional synchronizer and is arranged between the third planet carrier and the second central gear and is connected with the second rotating shaft and is respectively connected with the left side joint gear ring of the second central gear or the right side joint gear ring of the third planet carrier or is connected with the right side joint ring gear ring of the second central gear, the third synchronizer is a bidirectional synchronizer and is positioned between the right side of the second central gear and is connected with the second planet carrier and the left side joint ring gear and the second planet carrier, and the transmission ratio of the second planet carrier is different from that the second planet carrier and the second planet carrier;

the third transmission power device is composed of a third motor, a third rotating shaft, a third stator and a third rotor, wherein the third stator is fixedly arranged on the inner wall of the shell, the third rotor is fixedly arranged on the third rotating shaft and is internally provided with a gap with the third stator, the third rotating shaft penetrates through the first rotating shaft and the second rotating shaft, the left end face of the first rotating shaft and the right end face of the second rotating shaft are penetrated out from the left end and the right end of the third rotating shaft, the second flywheel and the fourth flywheel are respectively sleeved on the left end and the right end of the third rotating shaft, the first synchronizer is fixedly arranged on the left side of the third rotating shaft, and the third synchronizer is fixedly arranged on the right side of the third rotating shaft.

The four-wheel drive power device is characterized by further comprising the shell, the supporting plate and the bearing, wherein the shell radially covers the first power transmission device, the second power transmission device and the third power transmission device and bears components of the first power transmission device, the second power transmission device and the third power transmission device, and the supporting plate supports the shell and the bearing to rotate.

The four-wheel drive power device is characterized in that an inner rotor structure motor or an outer rotor structure motor is used.

The four-wheel-drive power plant is characterized in that the synchronizer and the clutch are arranged at different positions of the first rotating shaft, the second rotating shaft, the third rotating shaft, the first output shaft, the second output shaft and the third output shaft, and different types of synchronizers or clutches are adopted and are replaced, increased and decreased mutually.

The four-wheel drive power device is characterized in that the left and right transmission power devices are the same first transmission power device or two same second transmission power devices.

The four-wheel drive power plant according to the above, characterized in that a plurality of planetary sets are added in parallel to the first planetary set and the second planetary set.

The four-wheel-drive power device is characterized in that the four-wheel-drive power device is arranged on an electric vehicle in a longitudinal mode, the second output shaft and the fourth output shaft are respectively connected with a front axle differential and a rear axle differential of the vehicle, or arranged in a transverse mode, the second output shaft and the fourth output shaft are respectively connected with a left half shaft and a right half shaft of the vehicle.

The utility model provides a four wheel drive power device, a serial communication port, first motor the second motor the third motor's basic transmission mode does:

the first motor is directly driven, and the second output shaft and the fourth output shaft output power; when the first motor operates, the first rotating shaft power is transmitted to the second output shaft or/and the fourth output shaft through the second synchronizer, the first central wheel, the first synchronizer, the third rotating shaft, the second flywheel and the second clutch or/and the fourth flywheel and the fourth clutch.

The second motor is directly driven, and the second output shaft and the fourth output shaft output power; when the second motor operates, the power of the second rotating shaft is transmitted to the second output shaft and the fourth output shaft through the fourth synchronizer, the second central wheel, the third synchronizer, the third rotating shaft, the second flywheel and the second clutch or/and the fourth flywheel and the fourth clutch.

The third motor is directly driven, and the second output shaft and the fourth output shaft output power; when the third motor operates, the third rotor power is transmitted to the second output shaft and the fourth output shaft through the third rotating shaft, the second flywheel and the second clutch or/and the fourth flywheel and the fourth clutch.

The first motor operates in a primary speed reduction mode, and the second output shaft outputs power; when the first motor operates, the first rotating shaft power is transmitted to the second output shaft through the second synchronizer, the first central wheel, the first planet carrier, the first output shaft, the first flywheel and the first clutch.

The second motor operates in a first-stage speed reduction mode, and the fourth output shaft outputs power; when the second motor operates, the power of the second rotating shaft is transmitted to the fourth output shaft through the fourth synchronizer, the second central wheel, the second planet carrier, the third output shaft, the third flywheel and the third clutch.

The third motor operates in a first-stage speed reduction mode, and the second output shaft and the fourth output shaft respectively output power; when the third motor operates, third rotating shaft power is transmitted to the second output shaft or the fourth output shaft through the first synchronizer or the third synchronizer, the first central wheel or the second central wheel, the first planet wheel or the second planet wheel, the first planet carrier or the second planet carrier, the first output shaft or the third output shaft, the first flywheel or the third flywheel, the first clutch or the third clutch.

The first motor performs two-stage speed reduction operation, and the fourth output shaft outputs power; when the first motor operates, power is transmitted to the fourth output shaft through the second synchronizer, the first central wheel, the first planet carrier, the first synchronizer, the third rotating shaft, the third synchronizer, the second central wheel, the second planet carrier, the third output shaft, the third flywheel and the third clutch.

The second motor operates in a two-stage speed reduction mode, and the second output shaft outputs power; when the second motor operates, power is transmitted to the second output shaft through the fourth synchronizer, the second center wheel, the second planet carrier, the third synchronizer, the third rotating shaft, the first synchronizer, the first center wheel, the first planet carrier, the first output shaft, the first flywheel and the first clutch.

The second motor runs in a speed increasing mode, and the second output shaft and the fourth output shaft output power; when the second motor operates, the power of the second rotating shaft is transmitted to the second output shaft or/and the fourth output shaft through the fourth synchronizer, the third planet carrier, the second planet wheel, the second central wheel, the third synchronizer, the third rotating shaft, the second flywheel and the second clutch or/and the fourth flywheel and the fourth clutch.

The four-wheel drive power device is characterized in that any two or more motors in the first motor, the second motor and the third motor are in a combined transmission mode of basically transmitting motion.

The four-wheel drive power device is characterized by further comprising the electric vehicle power assembly.

Drawings

In order to more clearly illustrate the technical solutions of the present invention or the prior art, the following briefly introduces the drawings required for the embodiments or the prior art descriptions, and obviously, the drawings in the following description are some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic diagram of a four-wheel drive power plant;

FIG. 2 is a schematic diagram of a first motor direct drive implementation of front drive, rear drive and four drive;

FIG. 3 is a schematic diagram of a second motor direct drive implementation of front drive, rear drive and four drive;

FIG. 4 is a schematic diagram of a third motor direct drive implementation of front drive, rear drive and four drive;

FIG. 5 is a schematic diagram of a first motor one-stage speed reduction mode for implementing forerunner;

FIG. 6 is a schematic diagram of a second motor implementing a back drive with a first reduction;

FIG. 7 is a schematic diagram of a first-order speed reduction mode of the third motor for implementing forward driving and backward driving;

FIG. 8 is a schematic diagram of a two-stage deceleration implementation of the first motor for rear drive;

FIG. 9 is a schematic diagram of a second motor two-stage speed reduction implementation of the forerunner system;

FIG. 10 is a schematic diagram of a second motor speed increasing mode for implementing forward driving, backward driving and four-wheel driving;

FIG. 11 is a schematic diagram of the first motor, the second motor, and the third motor together implementing forward drive, backward drive, and four-wheel drive;

FIG. 12 is a schematic diagram of a four-wheel drive implementation of the first motor primary reduction and the second motor primary reduction;

FIG. 13 is a schematic view of the second motor increasing speed and the third motor direct-drive co-operation;

reference numerals:

1: a first motor; 2: a first stator; 3: a first rotor; 4: a first rotating shaft;

5: a first center wheel; 6: a first planet gear; 7: a first ring gear; 8: a first carrier;

9: a second motor; 10: a second stator; 11: a second rotor; 12: a second rotating shaft;

13: a second center wheel; 14: a second planet wheel; 15: a second ring gear; 16: a second planet carrier; 17: a third carrier; 18: a third motor; 19: a third stator; 20: a third rotor;

21: a third rotating shaft; 22: a first output shaft; 23: a second output shaft; 24: a third output shaft; 25: a fourth output shaft; 26: a first flywheel; 27: a first clutch; 28: a second flywheel; 29: a second clutch; 30: a third flywheel; 31: a third clutch; 32: a fourth flywheel; 33: a fourth clutch; 34, a first synchronizer; 35: a second synchronizer;

36: a third synchronizer; 37: a fourth synchronizer; 38: a housing; 39: and a support plate.

Detailed Description

The following describes embodiments of the present invention in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.

In the description of the embodiments of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of describing the embodiments of the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the embodiments of the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the embodiments of the present invention, it should be noted that, unless explicitly stated or limited otherwise, the terms "connected" and "connected" should be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the embodiments of the present invention can be understood in specific cases by those skilled in the art.

In embodiments of the invention, unless expressly stated or limited otherwise, the first feature may be directly on or directly under the second feature or indirectly via intermediate members. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of an embodiment of the invention. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Moreover, various embodiments or examples and features of various embodiments or examples described in this specification can be combined and combined by one skilled in the art without being mutually inconsistent.

In the first embodiment, as shown in fig. 1, the utility model provides a four-wheel drive power device, which is characterized in that the four-wheel drive power device comprises a first transmission power device, a second transmission power device and a third transmission power device;

the first power transmission device comprises a first planetary set, a first motor 1 and a first double clutch;

the first motor 1 comprises a first stator 2, a first rotor 3 and a first rotating shaft 4, the first stator 2 is connected with the inner wall of the shell 38, the first rotating shaft 4 is sleeved in the first rotor 3 in a hollow mode, and the first rotor 3 is rotatably arranged in the inner bore of the first stator 2;

the first double clutch comprises a second output shaft 23, a first clutch 27 and a second clutch 29 which are arranged on the second output shaft 23 in a repeated way, and a first flywheel 26 and a second flywheel 28 which are correspondingly and separately coupled with the first clutch 27 and the second clutch 29;

the first planetary set comprises a first central wheel 5, a first planet wheel 6, a first planet carrier 8, a first gear ring 7, a first output shaft 22, a first synchronizer 34 and a second synchronizer 35, wherein the first central wheel 5 is concentrically sleeved on a needle roller bearing at the left end of the first rotating shaft 4, the first gear ring 7 is connected with the inner wall of the shell 38, the first planet wheel 6 is meshed with the outer teeth of the first central wheel 5 and the inner teeth of the first gear ring 7, the first planet carrier 8 is connected with the first planet wheel 6 and concentrically sleeved at the right end of the first output shaft 22, the first flywheel 26 is sleeved at the left end of the first output shaft 22, the first synchronizer 34 is a bidirectional synchronizer and is positioned between the first central wheel 5 and the first planet carrier 8 and respectively jointed or separated with the left side jointing gear ring of the first central wheel 5 and the right side jointing gear ring of the first planet carrier 8, and the second synchronizer 35 is positioned at the right side of the first central wheel 5 and connected with the first rotating shaft 4 and separated or jointed with the right side jointing gear ring of the first central wheel 5;

the second transmission power device comprises a second planetary set, a second motor 9 and a second double clutch;

the second motor 9 comprises a second stator 10, a second rotor 11 and a second rotating shaft 12, the second rotating shaft 12 is hollow and is sleeved in a central hole of the second rotor 11, the second stator 10 is fixedly arranged on the inner wall of the shell 38, the second rotor 11 is rotatably arranged in an inner bore of the first stator 2, and the power, the rotating speed and the torque of the first motor 1 are different from those of the second motor 9;

the second double clutch comprises a fourth output shaft 25, a third flywheel 30, a third clutch 31, a fourth flywheel 32 and a fourth clutch 33, the third clutch 31 and the fourth clutch 33 are sleeved on the fourth output shaft 25 in an overlapping manner, and the third flywheel 30 and the fourth flywheel 32 are correspondingly and separately coupled with the third clutch 31 and the fourth clutch 33;

the second planetary set comprises a second central gear 13, a second planet gear 14, a second ring gear 15, a second planet carrier 16, a third planet carrier 17, a third output shaft 24, a third synchronizer 36 and a fourth synchronizer 37, the second ring gear 15 is fixedly arranged on the inner wall of the shell 38, the second central gear 13 is sleeved on a needle bearing at the right end of the second rotating shaft 12, the second planet gear 14 is meshed with the outer teeth of the second central gear 13 and the inner teeth of the second ring gear 15, the second planet carrier 16 is sleeved on the left end of the third output shaft 24, a third flywheel 30 is sleeved on the right end of the third output shaft 24, the third planet carrier 17 is positioned at the left side of the second central gear 13 and is connected with the second rotating shaft 12 through the needle bearing, the fourth synchronizer 37 is a bidirectional synchronizer which is arranged between the third planet carrier 17 and the second central gear 13 and is connected with the second rotating shaft 12 and is respectively connected with the left side joint gear of the second central gear 13 or the right side joint gear of the third planet carrier 17 and is separated from or connected with the right side joint gear of the second central gear 13, the third synchronizer 36 is a bidirectional synchronizer which is positioned between the right side of the second central gear 13 and the second ring 16, the second central gear and the second planet carrier 13, the second planet carrier is separated from or connected with the left side of the second planet carrier 16, and the second planet carrier is connected with the second planet carrier 16, and the second planet carrier 16, and the second planet carrier is in different transmission ratio of the second planet carrier, and the second planet carrier is different transmission ratio of the second planetary carrier, and the second planetary carrier is different transmission ratio of the second planetary carrier 16, and the second planetary carrier is different transmission ratio of the second planetary carrier, and the second planetary carrier transmission ratio of the second planetary carrier 16;

the third transmission device comprises a third motor 18, a third rotating shaft 21, a third stator 19 and a third rotor 20, the third stator 19 is fixedly arranged on the inner wall of the shell 38, the third rotor 20 is fixedly arranged on the third rotating shaft 21 and has a gap with the inner periphery of the third stator 19, the third rotating shaft 21 penetrates through the first rotating shaft 4 and the second rotating shaft 12, the left end and the right end of the third rotating shaft 21 penetrate through the left end surface of the first rotating shaft 4 and the right end surface of the second rotating shaft 12, the second flywheel 28 and the fourth flywheel 32 are respectively sleeved at the left end and the right end of the third rotating shaft 21, the first synchronizer 34 is fixedly arranged at the left side of the third rotating shaft 21, and the third synchronizer 36 is fixedly arranged at the right side of the third rotating shaft 21.

According to a four-wheel drive power device, the four-wheel drive power device is characterized by further comprising a shell 38, a supporting plate 39 and a bearing, wherein the shell 38 radially covers the first transmission power device, the second transmission power device and the third transmission power device and bears the components of the first transmission power device, the second transmission power device and the third transmission power device, and the supporting plate 39 supports the shell and the bearing to rotate.

According to a four-wheel drive power device, an inner rotor structure motor or an outer rotor structure motor is used.

According to a four-wheel drive power device, synchronizers and clutches are arranged at different positions of a first rotating shaft 4, a second rotating shaft 12, a third rotating shaft 21, a first output shaft 22, a second output shaft 23, a third output shaft 24 and a fourth output shaft 25, and synchronizers or clutches of different types are adopted and are replaced, increased and decreased mutually.

According to a four-wheel drive power plant, the left and right two transmission power plants are identical first transmission power plants or two identical second transmission power plants.

The four-wheel drive power plant is characterized in that a plurality of planetary groups are added in parallel to a first planetary group and a second planetary group.

A four-wheel drive power plant according to the invention is characterized in that it is installed in a longitudinally placed manner in an electric vehicle with the second output shaft 23 and the fourth output shaft 25 connected to the front axle differential and the rear axle differential, respectively, of the vehicle, or in a laterally placed manner with the second output shaft 23 and the fourth output shaft 25 connected to the left half-axle and the right half-axle, respectively, of the vehicle.

According to a four wheel drive power device, a serial communication port, the utility model discloses first motor 1, second motor 9, third motor 18's basic transmission mode does:

the first motor 1 directly drives, and the second output shaft 23 and the fourth output shaft 25 output power; when the first electric machine 1 is operated, the first rotating shaft 4 transmits power to the second output shaft 23 or/and the fourth output shaft 25 through the second synchronizer 35, the first central wheel 5, the first synchronizer 34, the third rotating shaft 21, the second flywheel 28 and the second clutch 29 or/and the fourth flywheel 32 and the fourth clutch 33.

The second motor 9 is directly driven, and the second output shaft 23 and the fourth output shaft 25 output power; when the second electric machine 9 is operated, the power of the second rotating shaft 12 is transmitted to the second output shaft 23 and the fourth output shaft 25 through the fourth synchronizer 37, the second central gear 13, the third synchronizer 36, the third rotating shaft 21, the second flywheel 28 and the second clutch 29 or/and the fourth flywheel 32 and the fourth clutch 33.

The third motor 18 directly drives, and the second output shaft 23 and the fourth output shaft 25 output power; when the third motor 18 is operated, the third rotor 20 is driven to transmit power to the second output shaft 23 and the fourth output shaft 25 via the third rotating shaft 21, the second flywheel 28 and the second clutch 29 or/and the fourth flywheel 32 and the fourth clutch 33.

The first motor 1 operates in a first-stage speed reduction mode, and the second output shaft 23 outputs power; when the first electric machine 1 is operated, the first rotating shaft 4 transmits power to the second output shaft 23 through the second synchronizer 35, the first center wheel 5, the first planetary gear 6, the first carrier 8, the first output shaft 22, the first flywheel 26 and the first clutch 27.

The second motor 9 operates at a first-stage speed reduction, and the fourth output shaft 25 outputs power; when the second electric machine 9 is running, the power of the second rotating shaft 12 is transmitted to the fourth output shaft 25 through the fourth synchronizer 37, the second central gear 13, the second planetary gear 14, the second planetary carrier 16, the third output shaft 24, the third flywheel 30 and the third clutch 31.

The third motor 18 operates at a first-stage speed reduction, and the second output shaft 23 and the fourth output shaft 25 respectively output power; when the third electric machine 18 is running, the third rotating shaft 21 transmits power to the second output shaft 23 or the fourth output shaft 25 through the first synchronizer 34 or the third synchronizer 36, the first central gear 5 or the second central gear 13, the first planetary gear 6 or the second planetary gear 14, the first planet carrier 8 or the second planet carrier 16, the first output shaft 22 or the third output shaft 24, the first flywheel 26 or the third flywheel 30, the first clutch 27 or the third clutch 31.

The first motor 1 performs two-stage speed reduction operation, and the fourth output shaft 25 outputs power; when the first electric machine 1 is running, power is transmitted to the fourth output shaft 25 through the second synchronizer 35, the first central wheel 5, the first planet wheel 6, the first planet carrier 8, the first synchronizer 34, the third rotating shaft 21, the third synchronizer 36, the second central wheel 13, the second planet wheel 14, the second planet carrier 16, the third output shaft 24, the third flywheel 30 and the third clutch 31.

The second motor 9 performs two-stage speed reduction operation, and the second output shaft 23 outputs power; when the second electric machine 9 is operated, power is transmitted to the second output shaft 23 through the fourth synchronizer 37, the second center gear 13, the second planetary gear 14, the second planetary carrier 16, the third synchronizer 36, the third rotating shaft 21, the first synchronizer 34, the first center gear 5, the first planetary gear 6, the first planetary carrier 8, the first output shaft 22, the first flywheel 26, and the first clutch 27.

The second motor 9 runs in an acceleration mode, and the second output shaft 23 and the fourth output shaft 25 output power; when the second electric machine 9 is running, the second rotating shaft 12 is made to transmit power to the second output shaft 23 or/and the fourth output shaft 25 through the fourth synchronizer 37, the third planet carrier 17, the second planet wheel 14, the second central wheel 13, the third synchronizer 36, the third rotating shaft 21, the second flywheel 28 and the second clutch 29 or/and the fourth flywheel 32 and the fourth clutch 33.

The four-wheel drive power device is characterized in that any two or more than two motors in a first motor, a second motor and a third motor basically transmit a combined transmission mode of motion.

A four-wheel drive power device is characterized by further comprising an electric vehicle power assembly device.

Following embodiment uses the utility model discloses power device sets up in the electric motor car as indulging the mode of putting to second output shaft connection vehicle front axle differential mechanism, with fourth output shaft connection vehicle rear axle differential mechanism, the transmission mode is implemented forerunner's, rear-guard and four-wheel drive respectively and is taken as the example. The electric machine, the synchronizer and the clutch, which are not described in the embodiments, are in their inactive state.

The first motor 1, the second motor 9 and the third motor 18 basically transmit the motion mode:

in the second embodiment, as shown in fig. 2, the first motor 1 directly drives the electric vehicle to perform the front-wheel drive, rear-wheel drive and four-wheel drive operation; when the first motor 1 operates, the power of the first rotating shaft 4 is transmitted to the second output shaft 23 or/and the fourth output shaft 25 through the second synchronizer 35, the first central gear 5, the first synchronizer 34, the third rotating shaft 21, the second flywheel 28, the second clutch 29, the fourth flywheel 32 and the fourth clutch 33, when the electric vehicle is driven forwards, the second clutch 29 is coupled, the fourth clutch 33 is separated, when the electric vehicle is driven backwards, the fourth clutch 33 is coupled, the second clutch 29 is separated, and when the electric vehicle is driven forwards, the second clutch 29 and the fourth clutch 33 are coupled.

In the third embodiment, as shown in fig. 3, the second motor 9 directly drives the electric vehicle to perform the front-wheel drive, rear-wheel drive and four-wheel drive operation; when the second motor 9 is operated, the power of the second rotating shaft 12 is transmitted to the second output shaft 23 or/and the fourth output shaft 25 through the fourth synchronizer 37, the second central gear 13, the third synchronizer 36, the third rotating shaft 21, the second flywheel 28, the second clutch 29, the fourth flywheel 32 and the fourth clutch 33, when the electric vehicle is driven forwards, the second clutch 29 is coupled, the fourth clutch 33 is disengaged, when the electric vehicle is driven backwards, the fourth clutch 33 is coupled, the second clutch 29 is disengaged, and when the electric vehicle is driven forwards, the second clutch 29 and the fourth clutch 33 are coupled.

In the fourth embodiment, as shown in fig. 4, the third motor 18 is directly driven to implement the front-wheel drive, rear-wheel drive and four-wheel drive operation of the electric vehicle; when the third motor 18 is operated, the power of the third rotating shaft 21 is transmitted to the second output shaft 23 or/and the fourth output shaft 25 through the second flywheel 28, the second clutch 29, the fourth flywheel 32 and the fourth clutch 33, when the electric vehicle is driven forwards, the second clutch 29 is coupled, the fourth clutch 33 is disengaged, when the electric vehicle is driven backwards, the fourth clutch 33 is coupled, the second clutch 29 is disengaged, and when the electric vehicle is driven backwards, the second clutch 29 and the fourth clutch 33 are coupled.

In the fifth embodiment, as shown in fig. 5, the first motor 1 performs the forerunner operation of the electric vehicle in a one-stage speed reduction mode; when the first electric machine 1 is operated, the first rotating shaft 4 transmits power to the second output shaft 23 through the second synchronizer 35, the first center wheel 5, the first planetary gear 6, the first carrier 8, the first output shaft 22, the first flywheel 26 and the first clutch 27.

In the sixth embodiment, as shown in fig. 6, the second motor 9 performs rear-drive operation of the electric vehicle in a one-stage speed reduction mode; when the second electric machine 9 is running, the second rotating shaft 12 is made to transmit power to the fourth output shaft 25 through the fourth synchronizer 37, the second central gear 13, the second planetary gear 14, the second planetary carrier 16, the third output shaft 24, the third flywheel 30 and the third clutch 31.

Seventh, as shown in fig. 7, the third motor 18 performs the forward driving operation or the backward driving operation of the electric vehicle in a one-step speed reduction mode; when the third electric machine 18 is operated, the third rotating shaft 21 transmits power to the second output shaft 23 to implement the forward drive operation or the fourth output shaft 25 to implement the backward drive operation through the first synchronizer 34 or the third synchronizer 36, the first center wheel 5 or the second center wheel 13, the first planetary gear 6 or the second planetary gear 14, the first carrier 8 or the second carrier 16, the first output shaft 22 or the third output shaft 24, the first flywheel 26 or the third flywheel 30, and the first clutch 27 or the third clutch 31.

In an eighth embodiment, as shown in fig. 8, the first motor 1 performs rear-drive operation of the electric vehicle in a two-stage speed reduction mode; when the first electric machine 1 is operated, power is transmitted to the fourth output shaft 25 through the second synchronizer 35, the first center wheel 5, the first planet wheel 6, the first planet carrier 8, the first synchronizer 34, the third rotating shaft 21, the third synchronizer 36, the second center wheel 13, the second planet wheel 14, the second planet carrier 16, the third output shaft 21, the third flywheel 30 and the third clutch 31, and the second clutch is disengaged 29.

In the ninth embodiment, as shown in fig. 9, the electric vehicle is operated in a forward driving mode by a two-stage speed reduction mode of the second motor 9; when the second electric machine 9 is operated, power is transmitted to the second output shaft 23 through the fourth synchronizer 37, the second central gear 13, the second planetary gear 14, the second planetary carrier 16, the third synchronizer 36, the third rotating shaft 21, the first synchronizer 34, the first central gear 5, the first planetary gear 6, the first planetary carrier 8, the first output shaft 22, the first flywheel 26 and the first clutch 27, and the fourth clutch 33 is disengaged.

In the tenth embodiment, as shown in fig. 10, the speed increasing mode of the second motor 9 implements the forward driving operation, the backward driving operation and the four-driving operation of the electric vehicle; when the second electric machine 9 is operated, the second rotating shaft 12 transmits power to the second output shaft 23 or/and the fourth output shaft 25 through the fourth synchronizer 37, the third planet carrier 17, the second planet wheel 14, the second central wheel 13, the third synchronizer 36, the third rotating shaft 21, the second flywheel 28 and the second clutch 29 or the fourth flywheel 32 and the fourth clutch 33; when the electric vehicle drives forwards, the second clutch 29 is coupled, the fourth clutch 33 is separated, when the electric vehicle drives backwards, the fourth clutch 33 is coupled, the second clutch 29 is separated, and when the electric vehicle drives backwards, the second clutch 29 and the fourth clutch 33 are coupled.

The following embodiments are combined transmission modes of basic functions of partial motors:

in the eleventh embodiment, as shown in fig. 11, according to the driving condition and the power complementation requirement of the electric vehicle, the primary and secondary power outputs of the three motors are determined, and four direct-drive modes of the first motor 1, the second motor 9 and the third motor 18, which are combined arbitrarily, include: the first motor 1 and the second motor 9, the first motor 1 and the third motor 18, the second motor 9 and the third motor 18, the first motor 1, the second motor 9 and the third motor 18 implement the front-driving operation, the rear-driving operation and the four-driving operation;

in the embodiment, the first motor 1, the second motor 9 and the third motor 18 are combined to implement a front-drive operation, a rear-drive operation and a four-drive operation, the first motor 1 directly drives and operates, so that the power of the first rotating shaft 4 is transmitted to the third rotating shaft 21 through the second synchronizer 35, the first central wheel 5 and the first synchronizer 34; the second motor 9 runs directly, so that the power of the second rotating shaft 12 is transmitted to the third rotating shaft 21 through the fourth synchronizer 37, the second central wheel 13 and the third synchronizer 36; the third motor 18 runs directly, and the power of the third rotor 20 is transmitted to the third rotating shaft 21; the third rotating shaft 21 transmits power to the second output shaft 23 or/and the fourth output shaft 25 through the second flywheel 28 and the second clutch 29 or/and the fourth flywheel 32 and the fourth clutch 33 to implement front driving or/and rear driving and four driving of the electric vehicle; when the electric vehicle drives forwards, the second clutch 29 is coupled, the fourth clutch 33 is separated, when the electric vehicle drives backwards, the fourth clutch 33 is coupled, the second clutch 29 is separated, when the electric vehicle drives backwards, the second clutch 29 is coupled with the fourth clutch 33, and the angular speeds of the first motor 1, the second motor 9 and the third motor 18 which transmit motion to the third rotating shaft 21 are the same.

In the twelfth embodiment, as shown in fig. 12, the first motor 1 and the second motor 9 perform four-wheel drive operation by combining one-stage speed reduction;

the first motor 1 operates in a primary speed reduction mode in a forerunner mode; when the first motor 1 operates, the power of the first rotating shaft 4 is transmitted to the second output shaft 23 through the second synchronizer 35, the first central wheel 5, the first planet wheel 6, the first planet carrier 8, the first output shaft 22, the first flywheel 26 and the first clutch 27;

the second motor 9 operates in a back-drive mode in a primary speed reduction mode; when the second electric machine 9 is running, the second rotating shaft 12 is made to transmit power to the fourth output shaft 25 through the fourth synchronizer 37, the second central gear 13, the second planetary gear 14, the second planetary carrier 16, the third output shaft 24, the third flywheel 30 and the third clutch 31.

In the thirteenth embodiment, as shown in fig. 13, the second motor 9 is speeded up and the third motor 18 is directly driven to operate in combination; the second motor 9 is in a speed-increasing mode to implement the forward driving operation, the backward driving operation, the four-wheel driving operation and the combined operation of the third motor 18 of the electric vehicle; when the second electric machine 9 is operated, the power of the second rotating shaft 12 is transmitted to the second output shaft 23 or/and the fourth output shaft 25 through the fourth synchronizer 37, the third planet carrier 17, the second planet wheel 14, the second central wheel 13, the third synchronizer 36, the third rotating shaft 21, the second flywheel 28, the second clutch 29 or/and the fourth flywheel 32 and the fourth clutch 33; when the electric vehicle drives forwards, the second clutch 29 is coupled, the fourth clutch 33 is separated, when the electric vehicle drives backwards, the fourth clutch 33 is coupled, the second clutch 29 is separated, when the electric vehicle drives forwards, the second clutch 29 and the fourth clutch 33 are coupled, when the second motor 9 implements three operation modes of speed increasing, front driving, rear driving and four driving, the third motor 18 can be directly driven to implement combined operation with the second motor 9, and the angular speeds of the third motor 18 and the second motor 9 acting on the third rotating shaft 21 are the same.

The bold solid lines in fig. 2-13 below represent the individual path patterns of the conveying motion; the broken lines represent various ways of conveying the motion.

The utility model relates to a four-wheel drive power device, integrated two double entry clutch, two planetary mechanism and three motors are an indivisible transmission whole, and the conventional power assembly of electric motor car of comparing has creatively realized can realizing by single power assembly forerunner's, rear-guard and four-wheel drive power directly drive, the multiple functional combination of one-level variable speed, second grade variable speed and two grades of variable speeds, provide neotype solution for the operation of the electric motor car under the full operating mode condition of performance car. The utility model discloses a indulge the differential mechanism of putting the mode and connecting the front and back axle, also can adopt horizontal mode to set up in vehicle front end or rear end, have compact structure, power volume density is high, and transmission speed range is wide, characteristics such as planet wheel load bearing capacity is strong can reduce vehicle manufacturing cost and running cost, increases the vehicle continuation of the journey mileage, realizes incessant safe operation.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, those skilled in the art will understand that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; such modifications and substitutions do not depart from the spirit and scope of the present invention in its corresponding aspects. The present invention has various motion modes, which are described only by way of examples and are not intended to limit all the operation modes of the present invention.

Claims (7)

1. A four-wheel drive power plant, comprising: the first transmission power device, the second transmission power device and the third transmission power device;

the first power transmission device comprises a first planetary set, a first motor and a first compound clutch;

the first motor comprises a first stator, a first rotor and a first rotating shaft, the first stator is connected with the inner wall of the shell, the first rotating shaft is sleeved in the first rotor in a hollow mode, and the first rotor is rotatably arranged in the first stator inner cavity;

the first compound clutch comprises a second output shaft, a first clutch and a second clutch which are arranged on the second output shaft in a repeated way, and a first flywheel and a second flywheel which are in separation coupling and correspond to the first clutch and the second clutch;

the first planetary set comprises a first central wheel, a first planet carrier, a first gear ring, a first output shaft, a first synchronizer and a second synchronizer, the first central wheel is concentrically sleeved on the needle roller bearing at the left end of the first rotating shaft, the first gear ring is connected with the inner wall of the shell, the first planet wheel is meshed with the outer teeth of the first central wheel and the inner teeth of the first gear ring, the first planet carrier is connected with the first planet wheel and concentrically sleeved at the right end of the first output shaft, the first flywheel is sleeved at the left end of the first output shaft, the first synchronizer is a bidirectional synchronizer and is positioned between the first central wheel and the first planet carrier, and is respectively connected or separated with the left-side joint gear ring of the first central wheel and the right-side joint gear ring of the first planet carrier, and the second synchronizer is positioned at the right side of the first central wheel and is connected with the first rotating shaft and is separated or connected with the right-side joint gear ring of the first central wheel;

the second transmission power device consists of a second planetary set, a second motor and a second multiple clutch;

the second motor comprises a second stator, a second rotor and a second rotating shaft, the second rotating shaft is hollow and internally sleeved in a central hole of the second rotor, the second stator is fixedly arranged on the inner wall of the shell, the second rotor is rotatably arranged in the inner bore of the first stator, and the power, the rotating speed and the torque of the first motor and the second motor are different;

the second compound clutch comprises a fourth output shaft, a third flywheel, a third clutch, a fourth flywheel and a fourth clutch, the third clutch and the fourth clutch are sleeved on the fourth output shaft in an overlapping manner, and the third flywheel and the fourth flywheel are correspondingly and separately coupled with the third clutch and the fourth clutch;

the second planet group comprises a second central gear, a second planet wheel, a second gear ring, a second planet carrier, a third output shaft, a third synchronizer and a fourth synchronizer, the second gear ring is fixedly arranged on the inner wall of the shell, the second central gear is sleeved on a needle bearing at the right end of the second rotating shaft, the second planet wheel is meshed with external teeth of the second central gear and internal teeth of the second gear ring, the second planet carrier is sleeved on the left end of the third output shaft, the third flywheel is sleeved on the right end of the third output shaft, the third planet carrier is positioned at the left side of the second central gear and is connected with the second rotating shaft through the needle bearing, the fourth synchronizer is a bidirectional synchronizer and is arranged between the third planet carrier and the second central gear and is connected with the second rotating shaft, and is respectively connected with the left side joint gear ring of the second central gear or the right side joint gear ring of the third planet carrier or is connected with the right side joint gear ring of the second planet carrier, the third synchronizer is a bidirectional synchronizer and is positioned between the right side of the second central gear and the second central gear, is connected with the right side joint gear ring of the second central gear and the left side joint gear ring of the second planet carrier, and the transmission ratio of the second planet carrier is different from that the second planet carrier;

the third transmission power device is composed of a third motor, a third rotating shaft, a third stator and a third rotor, wherein the third stator is fixedly arranged on the inner wall of the shell, the third rotor is fixedly arranged on the third rotating shaft and is provided with a gap with the inner periphery of the third stator, the third rotating shaft runs through the first rotating shaft and the second rotating shaft, the left end face of the first rotating shaft and the right end face of the second rotating shaft are penetrated out from the left end and the right end of the third rotating shaft, the second flywheel and the fourth flywheel are respectively sleeved on the left end and the right end of the third rotating shaft, the first synchronizer is fixedly arranged on the left side of the third rotating shaft, and the third synchronizer is fixedly arranged on the right side of the third rotating shaft.

2. The four-wheel drive power unit according to claim 1, comprising a housing radially encasing said first and second power transmission means and said third power transmission means and carrying components thereof, and a support plate and a bearing, said support plate supporting said housing and said bearing for rotation.

3. The four-wheel drive power plant according to claim 1, characterized in that an inner rotor structure motor or an outer rotor structure motor is used.

4. The four-wheel drive power unit according to claim 1, wherein the synchronizer and the clutch are provided at different positions of the first rotating shaft, the second rotating shaft, the third rotating shaft, the first output shaft, the second output shaft, the third output shaft and the fourth output shaft, and different types of synchronizers or clutches are adopted and are replaced, added and reduced with each other.

5. A four-wheel drive power unit according to claim 1, wherein the two side transmission power units are the same first transmission power unit or the same second transmission power unit.

6. The four-wheel drive power plant according to claim 1, wherein the first planetary set and the second planetary set are juxtaposed in sets of planetary sets.

7. The four-wheel drive power unit according to claim 1, wherein the four-wheel drive power unit is installed in a longitudinal manner on the electric vehicle or in a transverse manner on the electric vehicle.

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