阅读说明：本技术 电驱动桥及车辆 (Electric drive axle and vehicle ) 是由 邓乐 胡楷 于 2018-07-20 设计创作，主要内容包括：本发明涉及一种电驱动桥及车辆。包括桥壳总成及两个电驱动桥单元,两个所述电驱动桥单元装设于所述桥壳总成的相对两侧；所述电驱动桥单元包括：驱动电机,包括电机轴；半轴,与所述电机轴同轴设置；及减速器总成,包括减速器,所述电机轴与所述减速器的输入端连接,所述半轴位于所述减速器靠近车轮轮毂的一侧,所述半轴的一端与所述减速器的输出端连接,所述半轴的另一端与所述车轮轮毂连接。本发明提供的电驱动桥机车辆,将电机轴与半轴同轴设置,使驱动电机与制动器不相互影响,且电驱动桥结构简单,增加了离地间隙,使电驱动桥适用于半挂车。(The invention relates to electric drive axles and vehicles, which comprise an axle housing assembly and two electric drive axle units, wherein the two electric drive axle units are arranged on two opposite sides of the axle housing assembly, each electric drive axle unit comprises a drive motor, a half shaft and a speed reducer assembly, the drive motor comprises a motor shaft, the half shaft is coaxially arranged with the motor shaft, the speed reducer assembly comprises a speed reducer, the motor shaft is connected with the input end of the speed reducer, the half shaft is positioned on the side of the speed reducer, which is close to a wheel hub, the end of the half shaft is connected with the output end of the speed reducer, and the other end of the half shaft is connected with the wheel hub.)

The electric drive axle is characterized by comprising an axle housing assembly, a drive motor unit and two electric drive axle units, wherein the drive motor unit comprises two motor shafts, the two electric drive axle units are arranged on two opposite sides of the axle housing assembly, and the two motor shafts are respectively connected with the two electric drive axle units;

the electric drive axle unit includes:

the half shaft is coaxially arranged with the motor shaft; and

the speed reducer assembly comprises a speed reducer, wherein the motor shaft is connected with the input end of the speed reducer, the half shaft is located on the side of the speed reducer, which is far away from the driving motor unit, the end of the half shaft is connected with the output end of the speed reducer, and the other end of the half shaft is connected with a wheel hub.

2. The electric drive axle of claim 1, wherein the speed reducer assembly further comprises a hub reduction gear, the axle shaft is located between the speed reducer and the hub reduction gear, and both ends of the axle shaft are respectively connected with the output end of the speed reducer and the input end of the hub reduction gear, and the output end of the hub reduction gear is connected with the wheel hub.

3. The electric transaxle of claim 1 or 2 wherein the drive motor unit comprises a dual rotor drive motor comprising an inner rotor, an outer rotor surrounding the inner rotor, and two of the motor shafts;

the inner rotor is fixedly connected with the motor shaft and coaxially arranged, and the outer rotor is fixedly connected with the motor shaft and coaxially arranged.

4. The electric drive axle according to claim 1 or 2, further comprising a brake provided inside the wheel hub, and a suspension structure mounted on the axle housing assembly and provided between the brake and the speed reducer.

5. The electric drive axle of claim 4 wherein the suspension structure is a leaf spring suspension or a leading arm air suspension.

6. The electric drive axle of claim 1 or 2, wherein the speed reducer is a planetary gear speed reducer comprising th speed reducer housing, th ring gear, 0 th planet gear, 1 th planet carrier and 2 th sun gear, the th speed reducer housing is fixed to the axle housing assembly, the th ring gear is fixed to the th speed reducer housing, the th sun gear is engaged with the planet gears, the th planet gear is engaged with the th ring gear, the th sun gear is the input end of the speed reducer, and the th planet carrier is the output end of the speed reducer.

7. The electric drive axle of claim 2, wherein the wheel reduction gear is a planetary gear reduction gear comprising a second gear housing, a second ring gear, a second planet wheel, a second planet carrier, and a second sun gear, the electric drive axle also comprises a semi-shaft sleeve which is fixedly connected with the axle housing assembly, the second inner gear ring is fixed on the half shaft sleeve, the half shaft penetrates through the half shaft sleeve to be connected with the second sun gear, the second sun gear is meshed with the second planet gear, the second planet gear is meshed with the second inner gear ring, the second planet carrier is connected with the second reducer casing, the second reducer casing is fixed on the wheel hub, the second sun gear is the input end of the hub reduction gear, and the second planet carrier is the output end of the hub reduction gear.

8, electric drive axle, which is characterized in that it includes an axle housing assembly, a drive motor unit and two electric drive axle units, the drive motor unit includes two motor shafts, the two electric drive axle units are installed on two opposite sides of the axle housing assembly, the two motor shafts are respectively connected with the two electric drive axle units;

the electric drive axle unit includes:

a half shaft, an end of the half shaft being connected with the motor shaft, the half shaft being disposed coaxially with the motor shaft, and

the semi-shaft is positioned between the driving motor and the hub reduction gear, the other end of the semi-shaft is connected with the input end of the hub reduction gear, and the output end of the hub reduction gear is connected with a wheel hub.

9. The electric drive axle of claim 8, wherein the drive motor unit includes a dual rotor drive motor including an inner rotor, an outer rotor surrounding the inner rotor, and two of the motor shafts;

the inner rotor is fixedly connected with the motor shaft and coaxially arranged, and the outer rotor is fixedly connected with the motor shaft and coaxially arranged.

10. The electric drive axle of claim 8 further comprising a brake disposed inboard of said wheel hub and a suspension structure mounted on said axle housing assembly and disposed between said brake and said drive motor.

11. The electric drive axle of claim 10 wherein the suspension structure is a leaf spring suspension or a leading arm air suspension.

12, vehicle, characterized in that, it comprises a vehicle body and an electric drive axle according to any of claims 1-11 or connected to the vehicle body.

Technical Field

The invention relates to the technical field of vehicles, in particular to electric drive axles and a vehicle.

Background

At present, a semitrailer does not usually use a power system, and can normally run only by being powered by a tractor after being connected with the tractor through a coupling device.

There are kinds of centralized electric drive axles on the existing market, and motors are adopted to drive two wheels, so that distributed driving of the wheels cannot be realized, and the problems of low vehicle transmission efficiency, large turning radius and the like exist.

There are kinds of wheel limit electric transaxles in the market, adopt two motors to drive wheels respectively alone, wheel limit electric transaxle's motor is close to the wheel setting, and its reduction gear structure is complicated, bulky and weight is heavy to lead to ground clearance ratio less, can't be applicable to the semitrailer.

Disclosure of Invention

Based on this, it is necessary to provide electric drive axles and vehicles suitable for semitrailers aiming at the problems that the existing semitrailer does not have a power system, and the existing centralized drive axle and wheel-side drive axle have defects and are further not suitable for semitrailers.

electric drive axle comprises an axle housing assembly, a drive motor unit and two electric drive axle units, wherein the drive motor unit comprises two motor shafts, the two electric drive axle units are arranged on two opposite sides of the axle housing assembly, the two motor shafts are respectively connected with the two electric drive axle units, the electric drive axle units comprise half shafts and speed reducer assemblies, each half shaft is coaxially arranged with the corresponding motor shaft, each speed reducer assembly comprises a speed reducer, the motor shafts are connected with the input ends of the speed reducers, the half shafts are located on the sides of the speed reducers, which are far away from the drive motor units, the ends of the half shafts are connected with the output ends of the speed reducers, and the other ends of the half shafts are connected.

The motor shaft is directly and coaxially arranged with the half shaft, and only the speed reducer is adopted to complete speed reduction, so that the electric drive axle is simple in structure, ground clearance is increased, and the electric drive axle can drive wheels independently by the drive motor and is suitable for a semi-trailer.

In embodiments, the speed reducer assembly further includes a hub reduction gear, the half shaft is located between the speed reducer and the hub reduction gear, and two ends of the half shaft are respectively connected to the output end of the speed reducer and the input end of the hub reduction gear, and the output end of the hub reduction gear is connected to the wheel hub.

In embodiments, the drive motor unit comprises a dual rotor drive motor comprising an inner rotor, an outer rotor surrounding the inner rotor, and two motor shafts, the inner rotor being fixedly connected and coaxially disposed with the motor shaft , and the outer rotor being fixedly connected and coaxially disposed with the motor shaft .

In embodiments, the electric drive axle further includes a brake disposed inboard of the wheel hub and a suspension structure mounted on the axle housing assembly and disposed between the brake and the speed reducer.

In of these embodiments, the suspension structure is a leaf spring suspension or a leading arm air suspension.

In embodiments, the speed reducer is a planetary gear speed reducer and comprises a speed reducer housing, a 0 th annular gear, a 1 th planetary gear, a 2 th planetary gear and a 3 th sun gear, wherein the th speed reducer housing is fixed to the axle housing assembly, the th annular gear is fixed to the th speed reducer housing, the th sun gear is engaged with the planetary gear, the th planetary gear is engaged with the th annular gear, the th sun gear is an input end of the speed reducer, and the th planetary gear is an output end of the speed reducer.

In embodiments, the wheel-side speed reducer is a planetary gear speed reducer and includes a second speed reducer housing, a second inner gear ring, a second planet wheel, a second planet carrier, and a second sun gear, the electric drive axle further includes a half-shaft sleeve, the half-shaft sleeve is fixedly connected to the axle housing assembly, the second inner gear ring is fixed to the half-shaft sleeve, the half shaft passes through the half-shaft sleeve and is connected to the second sun gear, the second sun gear is engaged with the second planet wheel, the second planet wheel is engaged with the second inner gear ring, the second planet carrier is connected to the second speed reducer housing, the second speed reducer housing is fixed to the wheel hub, the second sun gear is an input end of the wheel-side speed reducer, and the second planet carrier is an output end of the wheel-side speed reducer.

electric drive axle comprises an axle housing assembly, a drive motor unit and two electric drive axle units, wherein the drive motor unit comprises two motor shafts, the two electric drive axle units are arranged on two opposite sides of the axle housing assembly, the two motor shafts are respectively connected with the two electric drive axle units, the electric drive axle unit comprises a half shaft, the end of the half shaft is connected with the motor shafts, the half shaft and the motor shafts are coaxially arranged, a wheel-side speed reducer is arranged between the drive motor and the wheel-side speed reducer, the other end of the half shaft is connected with the input end of the wheel-side speed reducer, and the output end of the wheel-side speed reducer is connected with a wheel hub.

The speed reduction is completed by adopting the wheel-side speed reducer, so that the electric drive axle has a simple structure, and the ground clearance is increased, so that the electric drive axle not only can realize that the driving motor unit can drive wheels independently, but also is suitable for a semitrailer.

In embodiments, the driving motor unit is a dual rotor driving motor, the dual rotor driving motor includes an inner rotor, an outer rotor surrounding the inner rotor, and two motor shafts, the inner rotor is fixedly connected and coaxially arranged with the motor shaft , and the outer rotor is fixedly connected and coaxially arranged with the motor shaft .

In embodiments, the electric drive axle further includes a brake disposed inboard of the wheel hub and a suspension structure mounted on the axle housing assembly and disposed between the brake and the drive motor.

In of these embodiments, the suspension structure is a leaf spring suspension or a leading arm air suspension.

vehicle comprises a vehicle body and the electric drive axle connected with the vehicle body.

Drawings

FIG. 1 is a schematic structural diagram of an electric transaxle in embodiment of the present invention;

FIG. 2 is a schematic view of a drive motor in an embodiment of the present invention;

FIG. 3 is a schematic view of a drive motor unit in an embodiment of the present invention;

FIG. 4 is a schematic illustration of an axle housing assembly in an embodiment of the present invention;

FIG. 5 is a schematic structural view from another perspective of the axle housing assembly shown in FIG. 4;

FIG. 6 is a schematic illustration of an axle housing assembly in another embodiment of the present invention;

FIG. 7 is a schematic illustration of a retarder of the electric transaxle of FIG. 1;

fig. 8 is a schematic structural view of an electric drive axle in a second embodiment of the present invention;

FIG. 9 is a schematic illustration of the wheel reduction of the electric drive axle of FIG. 8;

fig. 10 is a schematic structural view of an electric drive axle in a third embodiment of the present invention;

FIG. 11 is a schematic diagram of a portion of the electric drive axle shown in FIG. 10;

fig. 12 is a schematic structural view of the suspension structure in the electric transaxle shown in fig. 10, which is a leading arm type air suspension structure.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully with reference to the accompanying drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It is noted that when elements are referred to as being "secured to" another elements, they may be directly on the other elements or intervening elements may also be present, that when elements are referred to as being "connected" to another elements, they may be directly connected to another elements or intervening elements may be present.

In order to facilitate understanding of the technical solution of the present invention, prior to the detailed description, a description will be given of an existing wheel-rim electric drive axle structure.

The existing wheel-side electric drive axle is usually suitable for passenger car models with low floor requirements, a motor is arranged by wheels on two sides and adopts a two-stage speed ratio reducer assembly, an -stage usually adopts a cylindrical gear reducer, an input shaft of the cylindrical gear reducer is a motor shaft, an output shaft of the cylindrical gear reducer is a half shaft, a second stage adopts a planetary gear reducer, the input shaft of the cylindrical gear reducer is a half shaft, the output shaft of the cylindrical gear reducer is a planet carrier, and the planet carrier is connected with a wheel hub.

However, since the wheel rim is also provided with a brake, in order to prevent the motor arranged on the wheel side from interfering with the brake, the motor shaft and the half shaft are required to be eccentrically arranged to provide a position-mounted brake, and therefore, the -stage speed reducer is complicated in structure, large in size and heavy, which results in a small ground clearance of the vehicle, and therefore, the wheel rim electric drive axle is not suitable for the electric drive axle required for the semitrailer requiring a large ground clearance.

Therefore, it is necessary to provide types of electric drive axles and vehicles suitable for semitrailers.

As shown in fig. 1, an electric drive axle 100 according to embodiment of the present invention includes an axle housing assembly 10, a driving motor unit and two electric drive axle units, wherein the driving motor unit includes two motor shafts 21, the two electric drive axle units are mounted on two opposite sides of the axle housing assembly, the two motor shafts 21 are respectively connected to the two electric drive axle units, and the electric drive axle unit includes a driving motor unit 20, a half shaft 30 and a reducer assembly.

The half shaft 30 is arranged coaxially with the motor shaft 21, the speed reducer assembly comprises a speed reducer 40, the motor shaft 21 is connected with the input end of the speed reducer 40, the half shaft 30 is located at side of the speed reducer 40 far away from the driving motor unit, the end of the half shaft 30 is connected with the output end of the speed reducer 40, the other end of the half shaft 30 is connected with the wheel hub 200, and the motor shaft 21 of the driving motor unit 20 transmits the driving force to the wheel hub 200 through the speed reducer 40 and the half shaft 30 in sequence.

It should be understood that the half shaft 30 in the driving motor unit is disposed coaxially with the motor shaft 21, and the motor shaft 21 means the motor shaft 21 correspondingly connected to the driving motor unit.

In this way, since the semitrailer does not need to consider the low floor requirement of a passenger car model, the motor shaft 21 of the driving motor unit 20 and the half shaft 30 are coaxially arranged, and the positions of the driving motor unit 20 and the brake at the wheel rim do not influence each other.

In addition, the motor shaft 21 is directly and coaxially arranged with the half shaft 30, and only the speed reducer 40 is adopted to complete speed reduction, so the electric drive axle 400 has a simple structure, and further the ground clearance is increased, so that the electric drive axle 100 of the invention not only can realize that the drive motor unit 20 can independently drive wheels, but also can be applied to a semitrailer, and it should be understood that the electric drive axle 100 of the invention is applied to a semitrailer, which means that the electric drive axle 100 of the invention is mainly applied to a semitrailer, but is not limited to the semitrailer.

In the embodiments, the drive motor unit 20 is mounted in the middle of the axle housing assembly 10, which results in an elongated layout space for the entire electric drive axle 100, and step leaves sufficient mounting space for the wheel-side brake.

In embodiments, the drive motor unit 20 includes two drive motors 22, and the two drive motors 22 include two motor shafts 21.

In the embodiment, the two electric drive axle units are symmetrically disposed about the axle housing assembly 10 such that the two electric drive axle units transfer uniform torque to the corresponding wheel hubs 200 and are mounted to the vehicle body to equalize the forces on the vehicle body.

As shown in FIG. 2, in , the driving motor 22 may be a disc motor comprising a rotor 221, a stator 222 and a terminal 223. compared with a conventional motor, the disc motor has the advantages of higher power density, large peak torque, wide efficient area, and less noise, vibration, size and weight, and thus the electric drive axle 100 may be more compact, lighter and more efficient.

Referring again to FIG. 1, in particular embodiment , two drive motors 22 are axially spaced apart in a manner that facilitates easy installation of the drive motors 22 and subsequent removal for servicing in the event of a failure.

As shown in FIG. 3, in some other specific embodiments , the driving motor unit 20 comprises a dual rotor driving motor, which includes an inner rotor 231, an outer rotor 232 surrounding the inner rotor 231, and two motor shafts 21, the inner rotor 231 is fixedly connected and coaxially disposed with the motor shaft 21 , and the outer rotor 232 is fixedly connected and coaxially disposed with the motor shaft 21 .

Referring to fig. 1 again, in , in some embodiments, the axle housing assembly 10 includes an intermediate axle housing 11, the intermediate axle housing 11 has a receiving cavity, and the driving motor unit 20 is installed in the receiving cavity.

In embodiments, the axle housing assembly 10 further includes side axle housings 12, the side axle housings 12 being respectively located on opposite sides of the intermediate axle housing 11 adjacent the wheel hub 200, and the end of the side axle housing 12 being connected to the intermediate axle housing 11.

Specifically, in the embodiments, the side wall of the intermediate axle housing 11 is provided with a axial hole along the axial direction of the motor shaft 21, and the motor shaft 21 passes through the axial hole and is connected with the electric drive axle unit.

In embodiments, as shown in fig. 4, the intermediate axle housing 11 includes a motor mounting plate 111, the side of the motor mounting plate 111 is fixedly connected to the side axle housing 12, and the side is fixedly connected to the end of the driving motor 22.

Specifically , the drive motor 22 is bolted to the motor mounting plate 111.

In , the shaft hole is opened on the motor mounting plate 111.

In the embodiment, the axle housing assembly 11 further includes ribs 13, the ribs 13 being connected to the intermediate axle housing 11 and the side axle housing 12, respectively, so that the fixed connection between the intermediate axle housing 11 and the side axle housing 12 is more secure, and in the embodiment, the ribs 13 are right triangular in shape.

As shown in fig. 5, in the embodiments, the reinforcing beads 13 include a plurality of reinforcing beads 13, and the plurality of reinforcing beads 13 are circumferentially spaced along the axle housing 12.

In , the reinforcing ribs 13 are disposed between the side axle housing 12 and the motor mounting plate 111.

Referring again to FIG. 4, in the embodiment, the intermediate axle housing 11 includes two opposing motor mounting plates 111 and two opposing intermediate support plates 112 connected between the two motor mounting plates 111. it should be understood that the two motor mounting plates 111 respectively mount the two drive motors of the two electric drive axle units, hi the embodiment, the intermediate support plates 112 are connected to the motor mounting plates 111 by welds.

In , the intermediate axle housing 11 further includes a auxiliary mounting plate 113 extending axially along the driving motor 22, the 0 auxiliary mounting plate 113 is disposed on the side of the 1 driving motor 22, and the auxiliary mounting plate 113 is connected at its outer periphery to the corresponding motor mounting plate 111 and the two intermediate support plates 112, respectively, and the auxiliary mounting plate 113 is fixedly connected to the end of the driving motor 22 far from the motor mounting plate 111, the auxiliary mounting plate 113 is disposed, in , to form an axial fixation of the driving motor 22, so that the driving motor 22 is more reliably fixed, in , to strengthen the connection between the motor mounting plate 111 and the intermediate support plates 112, and to reduce the stress at the connection between the motor mounting plate 111 and the intermediate support plates 112.

, the intermediate axle housing 11 further includes a second auxiliary mounting plate 114 extending axially along the driving motor 22, the second auxiliary mounting plate 114 is disposed on the other side of the driving motor 22 opposite to the -th auxiliary mounting plate 113, and the outer periphery of the second auxiliary mounting plate 114 is connected to the corresponding motor mounting plate 111 and the two intermediate support plates 112, respectively, the second auxiliary mounting plate 114 is disposed to enhance the connection between the motor mounting plate 111 and the intermediate support plates 112, and the second auxiliary mounting plate 114 is engaged with the -th auxiliary mounting plate 113, so that the driving motor 22 is more reliably fixed in the direction perpendicular to the axial direction.

In , the auxiliary mounting plate 113 on the 22 side of the driving motor 22 and the second auxiliary mounting plate 114 on the 22 side of the driving motor 22 are disposed on the same side, and the auxiliary mounting plate 113 and the second auxiliary mounting plate 114 are disposed at an axial interval along the driving motor 22, which allows a space for routing the wires of the driving motor unit 20 and the wires of the cooling water pipes.

As shown in FIG. 6, in the embodiments, the two motor mounting plates 111, the two intermediate support plates 112 and the bottom plate 113 are integrally formed, thus simplifying the structure of the intermediate axle housing 11 and increasing the strength of the intermediate axle housing 11. in the embodiment, the intermediate axle housing 11 is integrally stamped and welded or cast.

Referring to fig. 1 again, in the present embodiment, the electric drive axle 100 further includes a brake 50 and a suspension structure 60, the brake 50 is disposed inside the wheel hub 200, and the suspension structure 60 is mounted on the axle housing assembly 10 and disposed between the brake 50 and the reducer 40. Since the half shaft 30 of the motor shaft 21 is coaxially disposed, a space for accommodating the suspension structure 60 is also provided without affecting the positions of the drive motor unit 20 and the wheel-side brake 50. The traditional wheel-side electric drive axle has limited arrangement position, and the vehicle only can adopt an air spring suspension with complex structure, high cost and inapplicability to a C-shaped beam of a semitrailer. The sufficient space for the electric drive axle 100 of the present invention enables the electric drive axle 100 to use various types of suspension structures commonly used in the market, without increasing the cost by redesigning the suspension structure adaptively.

In the present embodiment, the suspension structure 60 may be a leaf spring suspension, as shown in fig. 1. The steel plate spring suspension has the advantages of simple structure, high reliability, low cost, simple control and the like. In other embodiments, the suspension structure 60 may also be a leading arm air suspension, which has the same advantages as a leaf spring suspension.

In the specific embodiment , leaf spring suspensions or leading arm air suspensions are mounted to the axle housing assembly 10 in a direction perpendicular to the longitudinal direction of the axle housing assembly 10.

In specific embodiments, the brake 50 is a disc brake, and in other embodiments, the brake 50 may be other brake structures, and is not limited herein.

As shown in fig. 7, in the present embodiment, the reducer 40 is a planetary gear reducer, and includes a th reducer housing 41, a th ring gear 42, th planet gears 43, a 1 st planet carrier 44, and a th sun gear 45, the rd reducer housing 41 is fixed to the axle housing assembly 10, the th ring gear 42 is fixed to the th reducer housing 41, the th sun gear 45 is engaged with the th planet gears 43, the th planet gears 43 are engaged with the th ring gear 42, the th sun gear 45 is an input end of the reducer 40, and the th planet carrier 44 is an output end of the reducer 40, the structure of the reducer 6340 can realize that the motor shaft 21 of the driving motor unit 20 is coaxially arranged with the half shaft 30, the arrangement mode is simple, and the effects of reducing the rotation speed and increasing the torque are realized, the structure is simple and compact, so that the structure of the assembly reducer is simple, the mass is small, and the volume.

Specifically to , in the embodiments, the sun gear 45 is connected with the motor shaft 21 of the driving motor unit 20, the 0 th planet gear 43 is arranged between the 1 sun gear 45 and the 2 ring gear 42, the external teeth of the 3 rd planet gear 43 are engaged with the external teeth of the 4 th sun gear 45 and the internal teeth of the 5 th ring gear 42, respectively, the reducer 40 further includes a th planet gear shaft 46 and a bearing, the th planet gear 43 is fixed on the th planet gear shaft 46 through the bearing, the th planet gear carrier 44 is connected with the th planet gear shaft 46, and the th planet gear carrier 44 is connected with the end of the half shaft 30, in the embodiments, the bearing is a needle bearing.

In this embodiment, the end of the speed reducer housing 41 is fixedly connected to the intermediate axle housing 11.

In , the reducer housing 41 is hollow and has a opening facing of the driving motor unit 20, and the motor shaft 21 of the driving motor unit 20 passes through the shaft hole of the intermediate axle housing 11 and the opening to connect with the th sun gear 45.

Specifically, in the embodiments, the end of the reducer housing 41 is secured to the motor mounting plate 111.

In the present embodiment, the -th planet carrier 44 is a double-sided plate-split planet carrier, and includes a -th side plate 441 and a second side plate 442 located on opposite sides of the -th planet wheel 43, respectively, the -th side plate 441 and the second side plate 442 are abutted to both end surfaces of the -th planet wheel 43, respectively, the -th planet wheel shaft 46 is connected to the -th side plate 441 and the second side plate 442, respectively, so as to limit the -th planet wheel 43 in the axial direction, specifically, the position between the -th side plate 441 and the second side plate 442 is fixed by using a cylindrical pin and a screw.

In , the side plate 441 has an axial through hole through which the motor shaft 21 of the driving motor unit 20 passes to connect with the sun gear 45.

In the present embodiment, the center of the second side plate 442 is provided with a reducer output shaft 47, and the reducer output shaft 47 is connected to the end of the half shaft 30. specifically, the reducer output shaft 47 is splined to the end of the half shaft 30. specifically, in the embodiments of , the center of the second side plate 442 is provided with an internal spline, the end of the half shaft 30 is provided with an external spline that mates with the internal spline, it should be understood that the reducer output shaft 47 refers to the internal spline of the center of the second side plate 442, in other embodiments , the reducer output shaft 47 may be provided with an external spline, the end of the half shaft 30 may be provided with an internal spline, or other connection means, without limitation.

In , the reducer case 41 has a second opening opposite to the opening, and the reducer output shaft 47 passes through the second opening and protrudes from the second opening.

Referring again to fig. 1, in the present embodiment, the -th reducer case 41 is fixedly connected to the side axle housing 12 at the end away from the intermediate axle housing 11.

In the embodiment, the axle housing 12 is provided with a through hole and the axle shaft 30 is disposed within the axle housing 12. in the embodiment, the reducer output shaft 47 is connected to the end of the axle shaft 30 within the axle housing 12.

In embodiments, the suspension structure 60 is mounted on the axle housing 12.

In the present embodiment, the electric drive axle 100 further includes a connecting seat 70, the connecting seat 70 is fixed to the end of the half shaft 30 away from the speed reducer 40, and the connecting seat 420 is fixed to the outer side of the wheel hub 200 in the circumferential direction.

In , coupling sockets 70 are formed integrally with axle half shafts 30 , which arrangement may allow axle half shafts 30 to more reliably transmit forces through coupling sockets 70 to wheel hub 200.

As shown in fig. 8, fig. 8 shows an electric drive axle 300 in a second embodiment of the present invention.

The electric transaxle 300 in this embodiment has a similar structure to the electric transaxle 100 in embodiment , except that specific reference numerals will be used for the description.

In the embodiment, the speed reducer assembly includes a speed reducer 40 and a hub reduction gear 310, the half shaft 30 is located between the speed reducer 40 and the hub reduction gear 310, two ends of the half shaft 30 are respectively connected to an output end of the speed reducer 40 and an input end of the hub reduction gear 310, and an output end of the hub reduction gear 310 is connected to the wheel hub 200. The motor shaft 21 of the drive motor unit 20 transmits the driving force to the wheel hub 200 through the reduction gear 40, the half shaft 30, and the hub reduction gear 310 in this order.

Thus, by setting the reducer assembly as a two-stage speed ratio reducer, wherein stage is to use the motor shaft 21 of the driving motor unit 20 as the input end, the half shaft 30 as the output end, and the second stage is to use the half shaft 30 as the input end, and the output end is connected to the wheel hub 200, the effects of increasing the reduction ratio of the electric drive axle 100, increasing the rotation speed of the motor shaft 21, reducing the size and weight of the driving motor unit 20, and improving the operating efficiency of the driving motor unit 20 can be achieved.

As shown in fig. 9, in the present embodiment, the hub reduction gear 310 is a planetary gear reduction gear, and includes a second reduction gear housing 311, a second ring gear 312, a second planet gear 313, a second planet carrier 314, and a second sun gear 315, the electric drive axle 300 further includes a half shaft sleeve 320, the half shaft sleeve 320 is fixedly connected to the axle housing assembly 10, the second ring gear 312 is fixed to the half shaft sleeve 320, the half shaft 30 is connected to the second sun gear 315 through the half shaft sleeve 320, the second sun gear 315 is engaged with the second planet gear 313, the second planet gear 313 is engaged with the second ring gear 312, the second planet carrier 314 is connected to the second reduction gear housing 311, the second reduction gear housing 311 is fixed to the wheel hub 200, the second sun gear 315 is an input end of the hub reduction gear 310, and the second planet carrier 314 is an output end of the hub reduction gear 310.

Specifically to , in some embodiments, the end of the half shaft 30 is connected to the second sun gear 315, the second planet gears 313 are disposed between the second sun gear 315 and the second ring gear 312, and the external teeth of the second planet gears 313 are engaged with the external teeth of the second sun gear 315 and the internal teeth of the second ring gear 312, the hub reduction gear 310 further includes a second planet shaft 316 and a bearing, the second planet gears 313 are fixed to the second planet shaft 316 through the bearing, the second planet carrier 314 is connected to the second planet shaft 316, and the second planet carrier 314 is connected to the second reduction gear housing 311.

In embodiments, the second planet carrier 314 extends from side to side of the second planet gear 313, end face of the second planet gear 313 abuts against the second planet carrier 314, the other end face of the second planet gear 313 abuts against the inner wall of the second reducer housing 311, and the second planet gear shaft 316 is respectively connected with the second planet carrier 314 and the second reducer housing 311 to limit the second planet gear 313 in the axial direction.

In , the second planet carrier 314 has a through hole along the axial direction, and the end of the axle shaft 30 extends to the axle sleeve 320 and passes through the through hole to connect with the second sun gear 315.

In embodiments, the end of the axle housing 320 is fixedly attached to the end of the axle housing 12.

In , the hub reduction gear 310 further includes a ring gear support assembly 317, the ring gear support assembly 317 is fixedly connected to the outside of the axle sleeve 320, and the second ring gear 312 is fixed to the ring gear support assembly 317.

In , a tapered roller bearing 330 is disposed between the wheel hub 200 and the axle sleeve 320, and the tapered roller bearing 330 includes two tapered roller bearings disposed on the inner side of the wheel hub 200 and the outer side of the wheel hub 200.

In , the second reducer case 311 is a hollow structure, and a third opening is opened at a end facing the outer side of the wheel hub 200, the second reducer case 311 further includes a second connecting portion formed at the third opening along the circumferential direction of the second reducer case 311, the second connecting portion is fixedly connected to the wheel hub 200, and the specific structure of the second connecting portion is similar to that of the connecting portion, and is not described herein again.

In , the second reducer case 311 has a fourth opening opposite to the third opening.

in some embodiments, the wheel reduction gear 310 further includes an end cap 318, the end cap 318 covers the fourth opening and is fixedly connected to the outer end face of the second reduction gear housing 311. the end cap 318 is disposed to further step protect the inner structure of the wheel reduction gear 310 from external interference, and has functions of blocking dust and preventing water.

As shown in fig. 10, fig. 10 shows an electric drive axle 400 according to a third embodiment of the present invention.

The electric drive axle 400 of this embodiment has a similar structure to the electric drive axle 300 of the second embodiment, and the differences will be specifically described. For ease of description, the reference numerals of the same elements are not changed.

In this embodiment, the electric drive axle 400 includes an axle housing assembly 10, a driving motor unit 20 and two electric drive axle units, the driving motor unit includes two motor shafts 21, the two electric drive axle units are installed on two opposite sides of the axle housing assembly 10, the two motor shafts 21 are respectively connected with the two electric drive axle units, and the electric drive axle unit includes a half shaft 30 and a wheel reduction gear 410.

The motor shaft 21 is connected to the end of the half shaft 30, the motor shaft 21 is coaxially disposed with the half shaft 30, the half shaft 30 is located between the driving motor unit 20 and the hub reduction gear 410, the other end of the half shaft 30 is connected to the input end of the hub reduction gear 410, the output end of the hub reduction gear 410 is connected to the wheel hub 200, the motor shaft 21 of the driving motor unit 20 transmits the driving force to the wheel hub 200 through the half shaft 30 and the hub reduction gear 410 in sequence, the hub reduction gear 410 in the present embodiment has the same structure as the hub reduction gear 310 in the second embodiment, and the description thereof is omitted.

Since the semitrailer does not need to consider the low floor requirement of a passenger car model, the motor shaft 21 of the driving motor unit 20 and the half shaft 30 are coaxially arranged, and the positions of the driving motor unit 20 and the brake at the wheel rim do not influence each other.

In addition, only the wheel-side reducer 410 is adopted to complete speed reduction, so that the electric drive axle 400 is simple in structure, ground clearance is further increased, and the electric drive axle 400 can drive wheels independently by the driving motor unit 20 and is suitable for a semitrailer.

As shown in FIG. 10, in the specific embodiments, the axle shaft 30 is splined to the motor shaft 21, and in other embodiments, other splines or couplings may be used, without limitation.

Referring to fig. 10 again, in the present embodiment, the electric drive axle 400 further includes a brake 50 and a suspension structure 60, the brake 50 is disposed inside the wheel hub 200, and the suspension structure 60 is mounted on the axle housing assembly 10 and disposed between the brake 50 and the driving motor unit 20. Since the half shaft 30 of the motor shaft 21 is coaxially disposed, a space for accommodating the suspension structure 60 is also provided without affecting the positions of the drive motor unit 20 and the wheel-side brake 50. The traditional wheel-side electric drive axle has limited arrangement position, and the vehicle only can adopt an air spring suspension with complex structure, high cost and inapplicability to a C-shaped beam of a semitrailer. The sufficient space for the electric drive axle 400 of the present invention enables the electric drive axle 400 to use various types of suspension structures commonly used in the market, without increasing the cost by redesigning the suspension structure adaptively.

Specifically, in the embodiments, as shown in fig. 10, the suspension structure 50 may be a leaf spring suspension, or in the embodiments, as shown in fig. 12, the suspension structure 50 is a leading arm type air suspension, which has the same advantages as the leaf spring suspension , and thus, the description thereof is omitted.

Based on the electric drive axle (100, 300, 400), the invention also provides vehicles, which comprise a vehicle body and the electric drive axle (100, 300, 400) connected with the vehicle body.

In the vehicle, the positions of the driving motor unit 20 and the wheel-side brake are not affected by each other by arranging the electric drive axle (100, 300, 400) of the invention, the volume of the reducer assembly is reduced, the ground clearance is increased, and the electric drive axle (100, 300, 400) can drive wheels of the vehicle by the driving motor unit 20 alone.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.