CN111016643A

CN111016643A - Double-helix double-transcend integrated intelligent adaptive electric drive front-wheel drive system

Info

Publication number: CN111016643A
Application number: CN201911226464.3A
Authority: CN
Inventors: 薛荣生; 张引航; 陈俊杰; 王靖; 陈同浩; 谭志康; 邓天仪; 邓云帆; 梁品权; 颜昌权
Original assignee: Southwest University
Current assignee: Southwest University
Priority date: 2019-12-04
Filing date: 2019-12-04
Publication date: 2020-04-17
Anticipated expiration: 2039-12-04
Also published as: CN111016643B

Abstract

The invention discloses a double-helix double-transcend integrated intelligent self-adaptive electric drive front drive system, which includes a motor, an adaptive transmission assembly and a front drive force output mechanism. The motor includes a stator, a rotor and a motor shaft assembly. The motor shaft assembly Including the motor hollow shaft, power transmission flange and outer end mounting flange, the motor hollow shaft is fixed on the inner side of the rotor through the power transmission flange and the outer end mounting flange, and the power transmission flange passes through the power output reduction assembly and the adaptive transmission in turn. The assembly transmits power to the front drive power take-off. With the above technical solutions, the structure is extremely compact and the degree of integration is high, not only the transmission line is short, the transmission efficiency is high, but also the layout of the power mechanism is beneficial to reduce the impact on the dynamic balance of the wheels; through the design of the differential and related components, it is possible to achieve The power output of the front-wheel drive arrangement has high transmission efficiency of the entire transmission axle; through the installation of the power transmission flange and the outer end mounting flange, the overall balance is better.

Description

Double-helix double-surpassing integrated intelligent self-adaptive electric drive precursor system

Technical Field

The invention relates to the technical field of electric drive systems, in particular to a double-helix double-surpassing integrated intelligent self-adaptive electric drive precursor system.

Background

With the increasing strictness of environmental regulations, new energy vehicles represented by automobiles, motorcycles and tricycles which take pure electricity as power have been trending to replace traditional fuel vehicles.

At present, electric drive systems of automobiles, motorcycles and tricycles which take pure electricity as power are composed of two independent parts, namely a motor and a reduction gearbox (a gearbox or a transmission box), so that the transmission efficiency is not high enough, and the arrangement of mechanisms is influenced.

Moreover, due to the limitation of a transmission structure of the existing electric vehicle, in the driving process, a driver can control the electric vehicle according to experience under the condition that the driving resistance cannot be accurately known, so that the situation that the working state of a motor is not matched with the actual driving condition of the vehicle often inevitably occurs, and the motor is locked. Especially, when the vehicle is in low-speed heavy-load conditions such as starting, climbing, headwind and the like, the motor usually needs to work under the conditions of low efficiency, low rotating speed and high torque, the motor is easy to be damaged accidentally, the maintenance and replacement cost is increased, and meanwhile, the endurance mileage of the battery can be directly influenced. For vehicle types with high economic requirements, such as electric logistics vehicles, the traditional variable speed transmission structure obviously cannot well meet the use requirements.

Disclosure of Invention

In order to solve the technical problems, the invention provides a double-helix double-surpassing integrated intelligent self-adaptive electric driving precursor system.

The technical scheme is as follows:

the utility model provides a two surpassing integrated form wisdom self-adaptation electric drive precursor systems of double helix, includes motor, self-adaptation transmission assembly and precursor power take off mechanism, its characterized in that: the motor includes stator, rotor and receives the motor shaft assembly that the rotor drove, the motor shaft assembly includes the motor hollow shaft and sets up power transmission flange and the outer end mounting flange at the motor hollow shaft both ends respectively, the motor hollow shaft passes through the power transmission flange and the inboard at the rotor is fixed to outer end mounting flange, self-adaptation transmission assembly is partial at least to be set up in the motor hollow shaft, forerunner power take off mechanism includes differential mechanism and is used for transmitting power for differential mechanism's power take off gear sleeve, the power transmission flange transmits power for power take off gear sleeve through power take off speed reduction unit and self-adaptation transmission assembly in proper order to through the outside output power of differential mechanism.

By adopting the structure, the structure is extremely compact, the integration degree is high, the space in the motor is fully utilized, all or part of components of the self-adaptive transmission assembly can be arranged in the motor, the transmission route is short, the transmission efficiency is high, the arrangement of a power mechanism is facilitated, and the influence on the dynamic balance of the wheel is reduced; through the design of the differential and related components, the power output of the front-drive arrangement can be realized, and the transmission efficiency of the whole transmission axle is high; by installing the power transmission flange and the outer end mounting flange, the integral balance is better; by utilizing the self-adaptive transmission assembly, the self-adaptive automatic gear shifting and speed changing along with the change of the driving resistance are carried out under the condition of not cutting off the driving force, the motor is always positioned on a high-efficiency platform as far as possible, the high-efficiency operation interval of the motor is greatly increased, the use under the conditions of mountainous areas, hills and heavy loads can be met, the load change of the motor or an engine is gentle, and the pure electric vehicle runs stably and is high in safety.

Preferably, the method comprises the following steps: the motor hollow shaft comprises a hollow shaft sleeve and a plurality of silicon steel sheets arranged between the hollow shaft sleeve and the rotor, and the hollow shaft sleeve is made of an aluminum alloy material. Structure more than adopting, hollow axle sleeve is the aluminum alloy material, realizes lightweight design.

Preferably, the method comprises the following steps: the self-adaptive transmission assembly comprises a main shaft, a high-speed gear transmission mechanism and a low-speed gear transmission mechanism;

the high-speed gear transmission mechanism comprises a multi-plate friction clutch and an elastic element group for applying pretightening force to the multi-plate friction clutch, at least parts of the multi-plate friction clutch and the elastic element group are positioned in a motor, a motor shaft assembly transmits power to the multi-plate friction clutch sequentially through a power output speed reduction component and a first overrunning clutch, the multi-plate friction clutch is sleeved on a main shaft through an inner-plate spiral roller sleeve, and a first spiral transmission pair is formed between the inner-plate spiral roller sleeve and the main shaft so that the inner-plate spiral roller sleeve can slide axially along the main shaft;

the low-speed gear transmission mechanism comprises a second overrunning clutch and a countershaft transmission assembly for speed reduction transmission between a motor shaft assembly and the second overrunning clutch, the second overrunning clutch can transmit power to the main shaft through an inner core wheel sleeve, a double-cam transmission sleeve is sleeved on the main shaft, and the end faces of the two ends of the double-cam transmission sleeve are respectively matched with the corresponding end faces of a power output gear sleeve and an inner sheet spiral roller sleeve in an end face cam pair transmission mode and form a second spiral transmission pair with the main shaft.

When the resisting torque transmitted to the multi-plate friction clutch by the main shaft is smaller than the preset load limit of the multi-plate friction clutch, the rotor transmits power to the differential through the power output speed reducing component, the first overrunning clutch, the multi-plate friction clutch, the inner plate spiral roller sleeve, the double-cam transmission sleeve and the power output gear sleeve in sequence through the motor shaft assembly. When the resisting torque transmitted to the multi-plate friction clutch by the main shaft is larger than or equal to the preset load limit of the multi-plate friction clutch, the multi-plate friction clutch is separated, and the rotor transmits power to the differential mechanism through the power output speed reducing component, the auxiliary shaft transmission component, the second overrunning clutch, the inner core wheel sleeve, the main shaft and the power output gear sleeve in sequence through the motor shaft assembly.

By adopting the structure, the defects of the traditional disc type friction clutch are overcome by utilizing the multi-disc type friction clutch, the wear resistance is greatly improved, the stability and the reliability are high, the service life is prolonged, and the large-torque power transmission can be carried out; the increased double-cam transmission sleeve delays the return of the gears, so that the gear shifting effect is better; therefore, the self-adaptive automatic gear shifting and speed changing along with the change of the driving resistance are carried out under the condition of not cutting off the driving force, the motor is always positioned on the efficient platform as much as possible, the efficient operation interval of the motor is greatly increased, the use under the conditions of mountainous areas, hills and heavy loads can be met, the load change of the motor or an engine is smooth, and the pure electric vehicle runs stably and safely; the double-screw transmission of the first screw transmission pair and the second screw transmission pair is strong in load resistance, so that the main shaft is not easy to break, and the transmission is more suitable for large-torque power transmission.

Preferably, the method comprises the following steps: the multi-plate friction clutch comprises a friction plate supporting piece arranged on the inner plate spiral raceway sleeve, and a plurality of outer friction plates and inner friction plates which are alternately arranged between the friction plate supporting piece and the inner plate spiral raceway sleeve, wherein each outer friction plate can axially slide along the friction plate supporting piece, and each inner friction plate can axially slide along the inner plate spiral raceway sleeve;

the first overrunning clutch transmits power to the friction plate supporting piece, the elastic element group can apply pretightening force to the inner spiral roller way sleeve to compress the outer friction plates and the inner friction plates, a spiral transmission pair is formed between the inner spiral roller way sleeve and the main shaft, the inner spiral roller way sleeve can slide along the axial direction of the main shaft, and the elastic element group is compressed to release the outer friction plates and the inner friction plates.

By adopting the structure, the friction structure in the multi-plate friction clutch is set into the outer friction plates and the inner friction plates which are alternately arranged, so that the borne torque is dispersed on the outer friction plates and the inner friction plates, the abrasion is shared by the outer friction plates and the inner friction plates, the friction loss is greatly reduced, and the defect of the traditional plate friction clutch is overcome, thereby greatly improving the abrasion resistance, stability and reliability of the friction clutch, prolonging the service life and being capable of being used as a large-torque power transmission device.

Preferably, the method comprises the following steps: the inner-sheet spiral raceway sleeve comprises a friction sheet pressing disc in a disc-shaped structure and an output spiral raceway barrel in a cylindrical structure, the output spiral raceway barrel is sleeved on the main shaft, a first spiral transmission pair is formed between the output spiral raceway barrel and the main shaft, and the friction sheet pressing disc is fixedly sleeved at one end of the output spiral raceway barrel;

the friction plate support piece comprises a friction plate supporting disc in a disc-shaped structure and an outer plate spline sleeve in a cylindrical structure, the power input mechanism can transmit power to the friction plate supporting disc, the friction plate supporting disc is parallel to the friction plate pressing disc, the outer plate spline sleeve is coaxially sleeved outside the output spiral roller path cylinder, one end of the outer plate spline sleeve is in spline fit with the outer edge of the friction plate supporting disc, and the other end of the outer plate spline sleeve is rotatably supported on the outer edge of the friction plate pressing disc;

the outer edge of each outer friction plate is matched with the inner wall spline of the outer plate spline sleeve, the inner edge of each inner friction plate is matched with the outer wall spline of the output spiral raceway barrel, a plurality of inner plate starting check rings are sleeved on the outer wall of the output spiral raceway barrel, and each inner plate starting check ring is respectively positioned on one side, close to the friction plate supporting plate, of each inner friction plate;

when the output spiral roller path cylinder axially moves towards the direction far away from the friction plate supporting disc, each inner plate starting retainer ring can drive the adjacent inner friction plate to axially move towards the direction far away from the friction plate supporting disc, so that each outer friction plate and each inner friction plate are separated from each other; when the output spiral roller path cylinder moves axially towards the direction close to the friction plate supporting disc, the friction plate pressing disc can press each outer friction plate and each inner friction plate.

By adopting the structure, the end face cam pair is stable and reliable in transmission fit and easy to process and manufacture; through set up the inner disc on the inner friction piece installation section of thick bamboo and start the retaining ring, can drive each inner friction piece and adjacent outer friction piece separation initiatively, for current multi-disc friction clutch, response speed has not only been improved by a wide margin, corresponding time has been shortened, thereby can increase the quantity of friction piece by a wide margin, the quantity of infinitely increased friction piece even, make this friction clutch can be applied to big moment of torsion scene, and can guarantee the thorough separation of inner friction piece and outer friction piece, the condition of adhesion can not take place, long-term use, each inner friction piece is unanimous basically with the wearing and tearing condition of outer friction piece, greatly reduced the smooth loss that rubs, overcome the defect of traditional multi-disc friction clutch, friction clutch's life has been prolonged, thereby whole friction clutch's wearability has been improved by a wide margin, stability and reliability.

Preferably, the method comprises the following steps: the distance between the adjacent inner plate starting check rings is equal, the distance between the adjacent inner plate starting check rings is larger than that between the adjacent inner friction plates, and when the friction plate pressing plate presses each outer friction plate and each inner friction plate, the distance between each inner plate starting check ring and each adjacent inner friction plate is gradually reduced in an equal-difference array relation towards the direction close to the friction plate pressing plate. By adopting the structure, each inner friction plate and the corresponding outer friction plate can be dispersed more orderly and uniformly, and the response time is shortened.

Preferably, the method comprises the following steps: the friction plate pressing disc is provided with an annular raceway on the surface of one side close to the elastic element group, an end face bearing is arranged between the elastic element group and the friction plate pressing disc and comprises a bearing supporting disc and a plurality of bearing balls supported between the bearing supporting disc and the friction plate pressing disc, and each bearing ball can roll along the annular raceway. By adopting the structure, the friction plate pressing disc is used as a supporting disc of the end face bearing, so that the manufacturing cost is saved, and the assembly space is saved.

Preferably, the method comprises the following steps: the auxiliary shaft transmission assembly comprises a combination pattern sleeve, an auxiliary shaft first-stage driving gear, an auxiliary shaft first-stage driven gear and an auxiliary shaft second-stage driving gear, wherein the auxiliary shaft first-stage driven gear and the auxiliary shaft second-stage driving gear are fixedly sleeved on the auxiliary shaft, the auxiliary shaft first-stage driving gear is rotatably sleeved on the double-cam transmission sleeve and meshed with the auxiliary shaft first-stage driven gear, the auxiliary shaft second-stage driving gear is meshed with a second-stage driven gear on the second overrunning clutch, and the combination pattern sleeve is respectively in spline fit with the auxiliary shaft first-stage driving gear and a first outer ring of. By adopting the structure, the structure is simple, stable and reliable.

Preferably, the method comprises the following steps: the reverse gear mechanism is characterized in that a reverse gear driven gear is fixedly sleeved on the inner core wheel sleeve, a reverse gear driving gear meshed with the reverse gear driven gear is rotatably sleeved on the auxiliary shaft, a reverse gear combination sleeve capable of sliding along the axial direction of the auxiliary shaft is sleeved on the auxiliary shaft, and the reverse gear combination sleeve can be meshed with the reverse gear driving gear. With the above configuration, the power can be switched between the front and rear gears stably and reliably.

Preferably, the method comprises the following steps: the periphery of the auxiliary shaft is provided with a plurality of roller inner side arc-shaped grooves distributed along the circumferential direction, the roller inner side arc-shaped grooves are internally provided with rollers parallel to the axis of the auxiliary shaft, the hole wall of the reverse gear combination sleeve is provided with a plurality of roller outer side arc-shaped grooves which are in one-to-one correspondence with the roller inner side arc-shaped grooves and axially penetrate through the roller inner side arc-shaped grooves, so that the reverse gear combination sleeve can axially slide through the rollers, and the inner radius of the roller inner side arc-shaped grooves and the inner radius of the roller outer side arc-shaped grooves are both larger. The structure more than adopting, be connected through the roller between combination cover and the countershaft of reversing gear, make the combination cover of reversing gear can rotate certain angle relative the countershaft, possess certain degree of freedom to make the combination cover of reversing gear change in with the driving gear that reverses gear and combine, greatly improved the smooth and easy degree of shifting, overcome easy the appearance jamming when advancing to reverse gear, be difficult to advance the fender, easily damaged scheduling problem, can bear super large moment of torsion simultaneously.

Compared with the prior art, the invention has the beneficial effects that:

the double-helix double-surpass integrated intelligent self-adaptive electric driving precursor system adopting the technical scheme has the advantages of ingenious design, extremely compact structure and high integration degree, fully utilizes the space inside the motor, can install all or part of components of the self-adaptive transmission assembly into the motor, has short transmission route and high transmission efficiency, is beneficial to the arrangement of a power mechanism, and reduces the influence on the dynamic balance of the wheels; through the design of the differential and related components, the power output of the front-drive arrangement can be realized, and the transmission efficiency of the whole transmission axle is high; by installing the power transmission flange and the outer end mounting flange, the integral balance is better; by utilizing the self-adaptive transmission assembly, the self-adaptive automatic gear shifting and speed changing along with the change of the driving resistance are carried out under the condition of not cutting off the driving force, the motor is always positioned on a high-efficiency platform as far as possible, the high-efficiency operation interval of the motor is greatly increased, the use under the conditions of mountainous areas, hills and heavy loads can be met, the load change of the motor or an engine is gentle, and the pure electric vehicle runs stably and is high in safety.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic illustration of a high speed drive;

FIG. 3 is a schematic diagram of the engagement relationship between the multi-plate friction clutch and the inner plate helical raceway sleeve;

FIG. 4 is a schematic structural view of an inner spiral raceway sleeve;

FIG. 5 is a schematic structural view of an outer friction plate;

FIG. 6 is a schematic structural view of an inner friction plate;

FIG. 7 is a schematic structural view of a first overrunning clutch;

FIG. 8 is a schematic illustration of a low range transmission;

FIG. 9 is a cross-sectional view of the second overrunning clutch;

fig. 10 is a schematic structural view of the cage.

Detailed Description

The present invention will be further described with reference to the following examples and the accompanying drawings.

As shown in fig. 1, fig. 2 and fig. 8, a double-helix double-overrunning integrated intelligent adaptive electric drive precursor system mainly comprises a motor, an adaptive transmission assembly and a precursor power output mechanism.

The motor comprises a stator 15, a rotor 16 and a motor shaft assembly driven by the rotor 16, the motor shaft assembly comprises a motor hollow shaft 17, and a power transmission flange 18 and an outer end mounting flange 19 which are respectively arranged at two ends of the motor hollow shaft 17, the motor hollow shaft 17 is fixed at the inner side of the rotor 16 through the power transmission flange 18 and the outer end mounting flange 19, namely, the rotor 16 drives the motor hollow shaft 17 to synchronously rotate through the power transmission flange 18 and the outer end mounting flange 19. Wherein, power transmission flange 18 keeps off drive mechanism and low-speed gear drive mechanism with power transmission through power take off speed reduction assembly, and motor hollow shaft 17 includes hollow shaft sleeve 17a and a plurality of setting silicon steel sheet 17b between hollow shaft sleeve 17a and rotor 16, and hollow shaft sleeve 17a adopts the aluminum alloy material to make, not only satisfies lightweight design requirement, can shield well moreover.

Referring to fig. 1, 2 and 8, the adaptive transmission assembly includes a main shaft 1, a high-speed transmission mechanism and a low-speed transmission mechanism.

Referring to fig. 1 and 2, the high-speed gear transmission mechanism includes a multi-plate friction clutch 2 and an elastic element group 3 for applying a pre-tightening force to the multi-plate friction clutch 2, the multi-plate friction clutch 2 and the elastic element group 3 are at least partially located inside a hollow shaft 17 of the motor, a motor shaft assembly sequentially passes through a power output speed reduction assembly and a first overrunning clutch 4 to transmit power to the multi-plate friction clutch 2, the multi-plate friction clutch 2 is sleeved on the main shaft 1 through an inner plate helical raceway sleeve 5, and a first helical transmission pair is formed between the inner plate helical raceway sleeve 5 and the main shaft 1 so that the inner plate helical raceway sleeve 5 can slide axially along the main shaft 1.

The main shaft 1 is installed inside the box body through a main shaft bearing 30, similarly, the power transmission flange 18 and the outer end mounting flange 19 are respectively installed inside the box body through a flange mounting bearing 31, and through the design, a gap is reserved between the main shaft 1 and the power transmission flange 18 and the outer end mounting flange 19, so that respective dynamic balance is kept.

A first encoder 32 is arranged on the outer end mounting flange 19, a second encoder 33 is arranged on the main shaft 1, the first encoder 32 is used for detecting the rotating speed of the power transmission flange 18 (namely the motor hollow shaft 17), and the second encoder 33 is used for detecting the rotating speed of the main shaft 1.

Referring to fig. 2, the multiple-plate friction clutch 2 includes a friction plate support member disposed on the inner plate spiral raceway sleeve 5, and a plurality of outer friction plates 2c and inner friction plates 2d alternately arranged between the friction plate support member and the inner plate spiral raceway sleeve 5, each outer friction plate 2c being capable of axially sliding along the friction plate support member, and each inner friction plate 2d being capable of axially sliding along the inner plate spiral raceway sleeve 5.

Referring to fig. 2 and 3, the inner spiral raceway sleeve 5 includes an output spiral raceway barrel 5a and a friction plate pressing plate 5b fixedly connected by a welding process, wherein the output spiral raceway barrel 5a is a cylindrical structure, the friction plate pressing plate 5b is a disc-shaped structure, the friction plate pressing plate 5b is vertically and fixedly sleeved outside one end of the output spiral raceway barrel 5a, and a cam profile structure is processed on an end face of the output spiral raceway barrel 5a far away from the friction plate pressing plate 5 b.

The output spiral raceway cylinder 5a is sleeved on the main shaft 1, and forms the first spiral transmission pair with the main shaft 1, so that the inner sheet spiral raceway sleeve 5 can slide along the axial direction of the main shaft 1, and the elastic element group 3 is compressed to release each outer friction sheet 2c and each inner friction sheet 2 d. Specifically, the first helical transmission pair includes inner helical raceways 5a3 circumferentially distributed on the inner wall of the output helical raceway cylinder 5a and outer helical raceways 1a circumferentially distributed on the outer wall of the main shaft 1, a plurality of outwardly projecting balls 27 being embedded in each of the outer helical raceways 1a, and the respective balls 27 being capable of rolling in the corresponding inner helical raceway 5a3 and outer helical raceway 1a, respectively. When the inner-plate spiral raceway sleeve 5 rotates relative to the main shaft 1, the inner-plate spiral raceway sleeve can axially move relative to the main shaft 1, so that the multi-plate friction clutch 2 can be pressed or released, and the multi-plate friction clutch 2 is in a combined or separated state.

The friction plate pressing plate 5b extends radially outward from an end of the output spiral raceway barrel 5a remote from the friction plate support member. A plurality of concentric annular raceways 5b1 are distributed on the surface of the friction plate pressing disc 5b on the side close to the elastic element group 3, an end face bearing 21 is arranged between the elastic element group 3 and the friction plate pressing disc 5b, the end face bearing 21 comprises a bearing supporting disc 21b and a plurality of bearing balls 21a supported between the bearing supporting disc 21b and the friction plate pressing disc 5b, and each bearing ball 21a can roll along the corresponding annular raceway 5b 1. Through the structure, the friction plate pressing plate 5b can be used as a bearing supporting plate on one side, so that the manufacturing cost is saved, and the assembly space is saved.

Referring to fig. 2-3 and 4-5, the multiple-plate friction clutch 2 includes a friction plate supporter, and a plurality of outer friction plates 2c and inner friction plates 2d alternately arranged between the friction plate supporter and an inner plate spiral raceway sleeve 5, wherein the friction plate supporter includes a friction plate supporting plate 2a having a disc-shaped structure and an outer plate spline sleeve 2b having a cylindrical structure, a power input mechanism is capable of transmitting power to the friction plate supporting plate 2a, the friction plate supporting plate 2a is parallel to the friction plate pressing plate 5b, the outer plate spline sleeve 2b is coaxially sleeved outside the output spiral raceway sleeve 5a, one end thereof is spline-fitted with an outer edge of the friction plate supporting plate 2a, and the other end thereof is rotatably supported on an outer edge of the friction plate pressing plate 5 b. Each outer friction plate 2c is axially slidable along the inner wall of the outer plate spline housing 2b, and each inner friction plate 2d is axially slidable along the outer wall of the output spiral raceway cylinder 5 a. Compared with the traditional disc type friction clutch, the multi-plate type friction clutch 2 in the present embodiment is used for a long time, the abrasion conditions of each inner friction plate 2d and each outer friction plate 2c are basically consistent, the sliding friction loss is reduced, the abrasion resistance, the stability and the reliability of the multi-plate type friction clutch 2 are improved, and the service life of the multi-plate type friction clutch 2 is prolonged.

The inner edge of each inner friction plate 2d is provided with an inner plate inner spline 2d1, the outer wall of the output spiral raceway barrel 5a is provided with an inner plate outer spline 5a1 matched with each inner plate inner spline 2d1, namely, the output spiral raceway barrel 5a and each inner friction plate 2d realize spline fit with the inner plate outer spline 5a1 through the inner plate inner spline 2d1, so that each inner friction plate 2d can synchronously rotate with the output spiral raceway barrel 5a and can axially move along the output spiral raceway barrel 5a, and separation is realized.

The outer edge of each outer friction plate 2c is provided with an outer plate external spline 2c1, and the inner wall of the outer plate spline housing 2b is provided with an outer plate internal spline 2b1 matched with each outer plate external spline 2c 1. That is, the outer plate spline housing 2b and each outer friction plate 2c realize spline fit with the outer plate inner spline 2b1 through the outer plate outer spline 2c1, so that each outer friction plate 2c can synchronously rotate with the outer plate spline housing 2b, and can axially move along the outer plate spline housing 2b to realize separation.

The inner rim of the friction plate supporting disc 2a has a power input sleeve 2a1 extending away from the friction plate pressing disc 5 b. The power input sleeve 2a1 is coaxially arranged with the output spiral raceway barrel 5a, that is, the central axes of the power input sleeve 2a1, the output spiral raceway barrel 5a and the main shaft 1 coincide with each other. The friction plate supporting plate 2a is extended radially outwardly from the end of the power input sleeve 2a1 adjacent to the friction plate presser plate 5b and faces the friction plate presser plate 5b so that the outer friction plates 2c and the inner friction plates 2d are alternately arranged on the friction plate supporting plate 2a and the friction plate presser plate 5 b. Further, a power output spline 2a3 spline-fitted to the outer plate inner spline 2b1 is provided on the outer edge of the friction plate backup plate 2 a. Each outer friction plate 2c and friction plate supporting disc 2a can share the outer plate inner spline 2b1 on the inner wall of the outer plate spline housing 2b, and the design and processing difficulty and the production cost are reduced.

One end of the outer plate spline housing 2b, which is far away from the friction plate support piece, is supported on the outer edge of the friction plate pressing disc 5b and can freely rotate relative to the friction plate pressing disc 5b so as to keep the structure stable and reliable.

The elastic element group 3 can apply pretightening force to the inner plate spiral roller way sleeve 5 to press each outer friction plate 2c and each inner friction plate 2d tightly, so that the friction clutch 2 keeps a combined state. In this embodiment, the elastic element group 3 is preferably a disc spring, which is stable, reliable, and low in cost, and can continuously apply an axial thrust to the end bearing 21.

A plurality of inner plate starting check rings 2e are arranged on the inner wall of the output spiral raceway barrel 5a, and each inner plate starting check ring 2e is respectively positioned on one side of the adjacent inner friction plate 2d close to the friction plate supporting plate 2 a. By arranging the inner plate starting retainer ring 2e on the output spiral raceway barrel 5a, each inner friction plate 2d can be separated, so that all the inner friction plates 2d can be quickly and uniformly dispersed in a separated state, and the outer friction plates 2c are driven to move simultaneously, so that the inner friction plates 2d and the outer friction plates 2c are completely separated.

The distance between the adjacent inner plate starting check rings 2e is equal, and the distance between the adjacent inner plate starting check rings 2e is larger than the distance between the adjacent inner friction plates 2d, specifically, the distance between the adjacent inner plate starting check rings 2e is only slightly larger than the distance between the adjacent inner friction plates 2d, and when the friction clutch is in a disconnected state, the adjacent inner plate starting check rings 2e can ensure that each inner friction plate 2d and the adjacent outer friction plate 2c are uniformly distributed after being separated. When the friction plate pressing disc 5b presses each outer friction plate 2c and each inner friction plate 2d, the distance between each inner plate starting check ring 2e and the adjacent inner friction plate 2d is gradually reduced in an arithmetic progression towards the direction close to the friction plate pressing disc 5 b. The outer wall of the output spiral raceway cylinder 5a is provided with an inner plate male spline 5a1, the inner plate male spline 5a1 is provided with a plurality of inner retainer mounting ring grooves 5a2 corresponding to the corresponding inner plate actuating retainers 2e, and each inner plate actuating retainer 2e is fitted into the corresponding inner retainer mounting ring groove 5a 2.

Referring to fig. 2 and 7, the first overrunning clutch 4 includes a first outer ring 4c, a first inner core wheel 4a, and a plurality of first rolling elements 4b disposed between the first outer ring 4c and the first inner core wheel 4a, the first rolling elements 4b include thick rollers and thin rollers alternately disposed around the first inner core wheel 4a along a circumferential direction, two opposite first holders 4d are disposed on an outer circumferential surface of the first inner core wheel 4a, a circle of thin roller chutes are disposed on an inner wall of each first holder 4d, two ends of each thin roller are slidably inserted into the corresponding thin roller chutes, respectively, the power output reduction assembly can transmit power to the first outer ring 4c, and the inner wall of the first inner core wheel 4a is in spline fit with the friction plate support plate 2 a. By adopting the structure, each thin roller can follow up, the stability and the reliability of the first overrunning clutch 4 are improved, and the service life is prolonged.

Referring to fig. 1 and 2, the power output reduction assembly includes a high-speed gear shaft 9 and a high-speed gear primary driven gear 10, the high-speed gear shaft 9 includes a high-speed gear intermediate shaft portion 9a parallel to the main shaft 1 and a high-speed gear secondary driving tooth portion 9b formed on the high-speed gear intermediate shaft portion 9a, the high-speed gear primary driven gear 10 is fixedly sleeved on the high-speed gear intermediate shaft portion 9a and engaged with a flange output tooth 18a on the outer periphery of the power transmission flange 18, and the first outer ring 4c has a high-speed gear secondary driven tooth portion 4c1 engaged with the high-speed gear secondary driving tooth portion 9 b.

Referring to fig. 1 and 8, the low-speed gear transmission mechanism includes a second overrunning clutch 6 and a countershaft transmission assembly for speed reduction transmission between the motor shaft assembly and the second overrunning clutch 6, the second overrunning clutch 6 can be transmitted to the main shaft 1 through the power of the inner core wheel sleeve 7 (the inner core wheel sleeve 7 is in spline fit with the main shaft 1), the main shaft 1 is sleeved with a double-cam transmission sleeve 42, end faces of two ends of the double-cam transmission sleeve 42 are respectively in transmission fit with corresponding end faces of the power output gear sleeve 34 and the inner plate helical raceway sleeve 5 through an end face cam pair, and a second helical transmission pair is formed between the double-cam transmission sleeve and the main shaft 1.

Referring to fig. 8 to 10, the second overrunning clutch 6 includes a second outer ring 6a and a second inner core wheel 6c disposed between the second outer ring 6a and the inner core wheel 7, and second rolling elements are respectively disposed between the second outer ring 6a and the second inner core wheel 6 c.

The second inner core wheel sleeve 7 is made of a high-strength anti-torsion material, the second inner core wheel 6c is made of a compression-resistant wear-resistant material, specifically, the second inner core wheel sleeve 7 is made of alloy steel, and the second inner core wheel 6c is made of bearing steel or alloy steel or hard alloy. In this embodiment, the material of the second inner core wheel sleeve 7 is preferably 20CrMnTi, and has high torsion resistance, low cost and high cost performance, and the material of the second inner core wheel 6c is preferably GCr15, and has good wear-resistant and pressure-resistant performance, low cost and high cost performance. The second inner core wheel sleeve 7 is high in torsion and pressure resistance, transmission reliability and stability can be guaranteed, and the second inner core wheel 6c is high in abrasion and pressure resistance, so that the second inner core wheel sleeve 7 and the second inner core wheel 6c are made of two different materials, production cost is effectively saved, and the service life of the multi-row floating combined type heavy-load overrunning clutch is greatly prolonged.

The rolling bodies distributed along the outer periphery of the second core wheel 6c are composed of thick rolling bodies 6d and thin rolling bodies 6e which are alternately arranged, two opposite second retainers 6f are arranged on the outer peripheral surface of the second core wheel 6c, a circle of annular groove 6f1 is formed in the inner wall of each second retainer 6f, and two ends of each thin rolling body 6e are respectively inserted into the corresponding annular grooves 6f1 in a sliding manner. By adopting the structure, each thin rolling body 6e can follow up, the overall stability and reliability are improved, and the service life is prolonged.

The second outer ring 6a has secondary driven teeth 6b on the outer wall thereof. The outer wall of the inner core cam sleeve 7 is spline-fitted to the inner wall of the second inner core 6 c. With the above configuration, power transmission can be reliably performed.

The external teeth 6c1 comprise a top arc section 6c12, a short side section 6c11 and a long side section 6c13 which are respectively positioned at two sides of the top arc section 6c12, the short side section 6c11 is of an inwards concave arc structure, the long side section 6c13 is of an outwards convex arc structure, and the curvature of the short side section 6c11 is smaller than that of the long side section 6c 13. By adopting the structure, the stability and the reliability of the one-way transmission function can be ensured.

The end faces of the two ends of the double-cam transmission sleeve 42 are respectively provided with cam profile structures which are matched with the cam profile structures on the end faces of the power output gear sleeve 34 and the inner sheet spiral raceway sleeve 5, so that the double-cam transmission sleeve 42 is respectively in transmission fit with the corresponding end faces of the power output gear sleeve 34 and the inner sheet spiral raceway sleeve 5 through end face cam pairs. The double cam transmission sleeve 42 is more beneficial to disengagement and gear shifting.

Referring to fig. 8, the double cam driving sleeve 42 includes a screw fitting sleeve 42a and a mounting support sleeve 42b, wherein a second screw driving pair is formed between the screw fitting sleeve 42a and the main shaft 1. Specifically, the second helical transmission pair includes second inner helical raceways circumferentially distributed on the inner wall of the helical fit sleeve 42a and second outer helical raceways circumferentially distributed on the outer wall of the main shaft 1, a plurality of second balls protruding outward are embedded in each second outer helical raceway, and each second ball can roll in the corresponding second inner helical raceway and second outer helical raceway. When the double-cam transmission sleeve 42 rotates relative to the main shaft 1, the double-cam transmission sleeve can axially move relative to the main shaft 1, and simultaneously drives the inner-plate spiral roller sleeve 5 to axially move relative to the main shaft 1, so that the multi-plate friction clutch 2 can be pressed or released, and the multi-plate friction clutch 2 is in a combined or separated state.

The mounting support sleeve 42b rotates synchronously with the spiral matching sleeve 42a through spline fit, and the friction plate support disc 2a is rotatably sleeved on the mounting support sleeve 42 b.

Referring to fig. 1 and 8, the countershaft transmission assembly includes a combination spline housing 41, a first-stage countershaft driving gear 11, a countershaft 12, and a first-stage countershaft driven gear 13 and a second-stage countershaft driving gear 14 both fixedly sleeved on the countershaft 12, the first-stage countershaft driving gear 11 is rotatably sleeved on the double-cam transmission housing 42 and engaged with the first-stage countershaft driven gear 13, the second-stage countershaft driving gear 14 is engaged with a second-stage driven gear 6b on the second overrunning clutch 6, and the combination spline housing 41 is spline-fitted with the first-stage countershaft driving gear 11 and the first outer ring 4c respectively so that the three can rotate synchronously.

The inner hub 7 is fixedly fitted with a reverse driven gear 38, the counter shaft 12 is rotatably fitted with a reverse drive gear 39 engaged with the reverse driven gear 38, the counter shaft 12 is fitted with a reverse coupling sleeve 40 slidable in the axial direction thereof, and the reverse coupling sleeve 40 is engageable with the reverse drive gear 39.

The periphery of the auxiliary shaft 12 is provided with a plurality of roller inner side arc-shaped grooves distributed along the circumferential direction, the roller inner side arc-shaped grooves are internally provided with rollers 12a parallel to the axis of the auxiliary shaft 12, the hole wall of the reverse gear combination sleeve 40 is provided with a plurality of roller outer side arc-shaped grooves 5a which are in one-to-one correspondence with the roller inner side arc-shaped grooves and axially penetrate through the roller inner side arc-shaped grooves, so that the reverse gear combination sleeve 40 can axially slide through the rollers 12a, and the inner radius of the roller inner side arc-shaped grooves and the inner radius of the roller outer side arc-shaped grooves are both. The reverse gear coupling sleeve 40 can be engaged with the reverse gear driving gear 39, and specifically, the reverse gear coupling sleeve 40 is disengaged from the reverse gear driving gear 39 in forward gear; in reverse gear, the reverse gear coupling sleeve 40 engages the reverse drive gear 39. By adopting the structure, the reverse gear combination sleeve 40 is connected with the auxiliary shaft 12 through the roller 12a, so that the reverse gear combination sleeve 40 can rotate by a certain angle relative to the auxiliary shaft 12 and has a certain degree of freedom, the reverse gear combination sleeve 40 is easier to be combined with the reverse gear driving gear 39, the gear shifting smoothness is greatly improved, the problems that the gear is blocked easily when the gear is shifted and the gear is difficult to shift and easy to damage are solved, and meanwhile, the super-large torque can be borne.

The front-drive power output mechanism comprises a power output gear sleeve 34 and a differential 35, wherein the power output gear sleeve 34 is rotatably sleeved on the main shaft 1 and can output power outwards through the differential 35, namely the differential 35 drives a left shaft 36 and a right shaft 37 to rotate simultaneously.

In the present embodiment, the elastic element group 3 applies pressure via the end face bearings 21 to press the outer friction plates 2c and the inner friction plates 2d of the friction clutch 2. When the multiple disc friction clutch 2 is in the engaged state, the power is in the high-speed gear power transmission route:

the rotor 16 → the motor hollow shaft 17 → the power transmission flange 18 → the high-speed stage one-stage driven gear 10 → the high-speed stage gear shaft 9 → the first overrunning clutch 4 → the friction plate supporting plate 2a → the outer plate spline housing 2b → the outer friction plate 2c and the inner friction plate 2d → the output spiral raceway sleeve 5a → the double cam gear housing 42 → the power output gear housing 34 → the differential 35 → the left shaft 36 and the right shaft 37 output power.

At this time, the first overrunning clutch 4 does not overrun, the second overrunning clutch 6 overruns, and the resistance transmission path: the left and

right shafts

36 and 37 → the differential 35 → the power output gear sleeve 34 → the double cam gear sleeve 42 → the output spiral race tube 5a → the friction plate pressing plate 5b → the end face bearing 21 → the elastic element group 3; when the resisting moment transmitted to the multi-plate friction clutch 2 by the main shaft 1 is greater than or equal to the preset load limit of the multi-plate friction clutch 2, the inner plate spiral roller way sleeve 5 is translated relative to the main shaft 1 to compress the elastic element group 3, and a gap appears between each outer friction plate 2c and each inner friction plate 2d of the multi-plate friction clutch 2, namely the multi-plate friction clutch 2 is separated, and the power is transmitted through the following route, namely a low-speed power transmission route:

the rotor 16 → the motor hollow shaft 17 → the power transmission flange 18 → the first-stage driven gear for high-speed gear 10 → the gear shaft for high-speed gear 9 → the first outer ring 4a → the coupling flower case 41 → the first-stage driving gear for counter shaft 11 → the first-stage driven gear for counter shaft 13 → the counter shaft 12 → the second-stage driving gear for counter shaft 14 → the second overrunning clutch 6 → the inner core wheel case 7 → the main shaft 1 → the power output gear case 34 → the differential 35 → the left shaft 36 and the right shaft 37 for power output.

At this time, the first overrunning clutch 4 overruns, and the second overrunning clutch 6 does not overrun, so that the automatic speed changing mechanism capable of keeping a certain pressure is formed in the running process of the invention.

In the embodiment, taking an electric vehicle as an example, when the whole vehicle is started, the resistance force is greater than the driving force, the resistance force forces the driven friction piece 2b to compress the elastic element group 3 through the end face bearing 21, the driven friction piece 2b is separated from the driving friction piece 2a, namely, the friction clutch 2 is in a disconnected state and rotates at a low gear speed; therefore, the low-speed starting is automatically realized, and the starting time is shortened. Meanwhile, the elastic element group 3 absorbs the energy of the movement resistance moment and stores potential energy for restoring the high-speed gear to transmit power.

After the start is successful, the running resistance is reduced, and when the component force is reduced to be smaller than the pressure generated by the elastic element group 3, the driven friction member 2b and the driving friction member 2a of the friction clutch 2 are restored to a close contact state by being pushed by the elastic element group 3 which is compressed by the motion resistance and the pressure is rapidly released, and the friction clutch is rotated at a high-speed gear speed.

In the driving process, the automatic gear shifting principle is the same as the principle of automatic gear shifting along with the change of the motion resistance, gear shifting is realized under the condition of not cutting off power, the whole vehicle runs stably, safety and low consumption are realized, a transmission route is simplified, and the transmission efficiency is improved.

II, reversing gear: the reverse gear coupling sleeve 40 engages the reverse drive gear 39.

Reverse gear power transmission route: the rotor 16 → the motor hollow shaft 17 → the power transmission flange 18 → the first-stage high-speed driven gear 10 → the high-speed gear shaft 9 → the first outer race 4a → the coupling spline housing 41 → the first-stage counter drive gear 11 → the first-stage counter driven gear 13 → the counter shaft 12 → the reverse coupling bushing 40 → the reverse drive gear 39 → the reverse driven gear 38 → the inner spline housing 7 → the main shaft 1 → the power output gear housing 34 → the differential 35 → the left and

right shafts

36 and 37 output power.

Finally, it should be noted that the above-mentioned description is only a preferred embodiment of the present invention, and those skilled in the art can make various similar representations without departing from the spirit and scope of the present invention.

Claims

1. The utility model provides a two surpassing integrated form wisdom self-adaptation electric drive precursor systems of double helix, includes motor, self-adaptation transmission assembly and precursor power take off mechanism, its characterized in that: the motor comprises a stator (15), a rotor (16) and a motor shaft assembly driven by the rotor (16), the motor shaft assembly comprises a motor hollow shaft (17), and a power transmission flange (18) and an outer end mounting flange (19) which are respectively arranged at two ends of the motor hollow shaft (17), the motor hollow shaft (17) is fixed on the inner side of the rotor (16) through a power transmission flange (18) and an outer end mounting flange (19), the self-adaptive transmission assembly is at least partially arranged in a motor hollow shaft (17), the front drive power output mechanism comprises a differential (35) and a power output gear sleeve (34) used for transmitting power to the differential (35), the power transmission flange (18) transmits power to the power output gear sleeve (34) through the power output speed reducing assembly and the self-adaptive transmission assembly in sequence, and outputs power outwards through the differential (35).

2. The dual-helix dual-transcendence integrated intelligent adaptive electric drive precursor system according to claim 1, wherein: the motor hollow shaft (17) comprises a hollow shaft sleeve (17a) and a plurality of silicon steel sheets (17b) arranged between the hollow shaft sleeve (17a) and the rotor (16), and the hollow shaft sleeve (17a) is made of an aluminum alloy material.

3. The dual-helix dual-transcendence integrated intelligent adaptive electric drive precursor system according to claim 1, wherein: the self-adaptive transmission assembly comprises a main shaft (1), a high-speed transmission mechanism and a low-speed transmission mechanism;

the high-speed gear transmission mechanism comprises a multi-plate friction clutch (2) and an elastic element group (3) for applying pretightening force to the multi-plate friction clutch (2), at least parts of the multi-plate friction clutch (2) and the elastic element group (3) are positioned in a motor, a motor shaft assembly sequentially passes through a power output speed reduction component and a first overrunning clutch (4) to transmit power to the multi-plate friction clutch (2), the multi-plate friction clutch (2) is sleeved on a main shaft (1) through an inner plate spiral roller sleeve (5), and a first spiral transmission pair is formed between the inner plate spiral roller sleeve (5) and the main shaft (1) so that the inner plate spiral roller sleeve (5) can axially slide along the main shaft (1);

the low-speed gear transmission mechanism comprises a second overrunning clutch (6) and a countershaft transmission assembly for speed reduction transmission between a motor shaft assembly and the second overrunning clutch (6), the second overrunning clutch (6) can transmit power to a main shaft (1) through an inner core wheel sleeve (7), the main shaft (1) is sleeved with a double-cam transmission sleeve (42), and the end faces of the two ends of the double-cam transmission sleeve (42) are respectively matched with the corresponding end faces of a power output gear sleeve (34) and an inner sheet spiral roller sleeve (5) in an end face cam pair transmission manner and form a second spiral transmission pair with the main shaft (1).

4. The dual-helix dual-transcendence integrated intelligent adaptive electric drive precursor system according to claim 3, wherein: the multi-plate friction clutch (2) comprises a friction plate supporting piece arranged on the inner plate spiral roller way sleeve (5) and a plurality of outer friction plates (2c) and inner friction plates (2d) which are alternately arranged between the friction plate supporting piece and the inner plate spiral roller way sleeve (5), each outer friction plate (2c) can axially slide along the friction plate supporting piece, and each inner friction plate (2d) can axially slide along the inner plate spiral roller way sleeve (5);

the first overrunning clutch (4) transmits power to the friction plate supporting piece, the elastic element group (3) can apply pretightening force to the inner spiral roller way sleeve (5) to compress the outer friction plates (2c) and the inner friction plates (2d), a spiral transmission pair is formed between the inner spiral roller way sleeve (5) and the main shaft (1), the inner spiral roller way sleeve (5) can slide along the axial direction of the main shaft (1), and therefore the elastic element group (3) is compressed to release the outer friction plates (2c) and the inner friction plates (2 d).

5. The dual-helix dual-transcendence integrated intelligent adaptive electric drive precursor system according to claim 4, wherein: the inner-sheet spiral raceway sleeve (5) comprises a friction sheet pressing disc (5b) in a disc-shaped structure and an output spiral raceway barrel (5a) in a cylindrical structure, the output spiral raceway barrel (5a) is sleeved on the main shaft (1) and forms a first spiral transmission pair with the main shaft (1), and the friction sheet pressing disc (5b) is fixedly sleeved at one end of the output spiral raceway barrel (5 a);

the friction plate support piece comprises a friction plate supporting plate (2a) in a disc-shaped structure and an outer plate spline sleeve (2b) in a cylindrical structure, the power input mechanism can transmit power to the friction plate supporting plate (2a), the friction plate supporting plate (2a) is parallel to the friction plate pressing plate (5b), the outer plate spline sleeve (2b) is coaxially sleeved outside the output spiral raceway barrel (5a), one end of the outer plate spline sleeve is in spline fit with the outer edge of the friction plate supporting plate (2a), and the other end of the outer plate spline sleeve is rotatably supported on the outer edge of the friction plate pressing plate (5 b);

the outer edge of each outer friction plate (2c) is in spline fit with the inner wall of an outer plate spline sleeve (2b), the inner edge of each inner friction plate (2d) is in spline fit with the outer wall of an output spiral raceway barrel (5a), a plurality of inner plate starting check rings (2e) are sleeved on the outer wall of the output spiral raceway barrel (5a), and each inner plate starting check ring (2e) is respectively positioned on one side, close to a friction plate supporting disk (2a), of each inner friction plate (2 d);

when the output spiral raceway cylinder (5a) axially moves towards the direction far away from the friction plate supporting disc (2a), each inner plate starting check ring (2e) can drive the adjacent inner friction plate (2d) to axially move towards the direction far away from the friction plate supporting disc (2a), so that each outer friction plate (2c) and each inner friction plate (2d) are separated from each other; when the output spiral raceway cylinder (5a) is axially moved in the direction close to the friction plate support plate (2a), the friction plate pressing plate (5b) can press each of the outer friction plate (2c) and the inner friction plate (2 d).

6. The dual-helix dual-transcendence integrated intelligent adaptive electric drive precursor system according to claim 5, wherein: the distance between the adjacent inner plate starting check rings (2e) is equal, the distance between the adjacent inner plate starting check rings (2e) is larger than the distance between the adjacent inner friction plates (2d), and when the friction plate pressing plate (5b) presses the outer friction plates (2c) and the inner friction plates (2d), the distance between the inner plate starting check rings (2e) and the adjacent inner friction plates (2d) is gradually reduced in an arithmetic progression relation towards the direction close to the friction plate pressing plate (5 b).

7. The dual-helix dual-transcendence integrated intelligent adaptive electric drive precursor system according to claim 5, wherein: the friction plate pressing disc (5b) is provided with an annular raceway (5b1) on the surface of one side close to the elastic element group (3), an end face bearing (21) is arranged between the elastic element group (3) and the friction plate pressing disc (5b), the end face bearing (21) comprises a bearing supporting disc (21b) and a plurality of bearing balls (21a) supported between the bearing supporting disc (21b) and the friction plate pressing disc (5b), and each bearing ball (21a) can roll along the annular raceway (5b 1).

8. The dual-helix dual-transcendence integrated intelligent adaptive electric drive precursor system according to claim 3, wherein: the auxiliary shaft transmission assembly comprises a combination pattern sleeve (41), an auxiliary shaft first-level driving gear (11), an auxiliary shaft (12), an auxiliary shaft first-level driven gear (13) and an auxiliary shaft second-level driving gear (14), wherein the auxiliary shaft first-level driving gear (11) and the auxiliary shaft first-level driven gear (13) and the auxiliary shaft second-level driving gear (14) are fixedly sleeved on the auxiliary shaft (12), the auxiliary shaft first-level driving gear (11) is rotatably sleeved on the double-cam transmission sleeve (42) and meshed with the auxiliary shaft first-level driven gear (13), the auxiliary shaft second-level driving gear (14) is meshed with a second-level driven gear (6b) of the second overrunning clutch (6), and the combination pattern sleeve (41) is in spline fit with the auxiliary shaft first-level driving gear (11) and a.

9. The dual-helix dual-transcendental integrated intelligent adaptive electric drive precursor system according to claim 8, wherein: the reverse gear mechanism is characterized in that a reverse gear driven gear (38) is fixedly sleeved on the inner core wheel sleeve (7), a reverse gear driving gear (39) meshed with the reverse gear driven gear (38) is rotatably sleeved on the auxiliary shaft (12), a reverse gear combination sleeve (40) capable of sliding along the axial direction of the auxiliary shaft (12) is sleeved on the auxiliary shaft (12), and the reverse gear combination sleeve (40) can be meshed with the reverse gear driving gear (39).

10. The dual-helix dual-transcendental integrated intelligent adaptive electric drive precursor system according to claim 9, wherein: the periphery of the auxiliary shaft (12) is provided with a plurality of roller inner side arc-shaped grooves distributed along the circumferential direction, the roller inner side arc-shaped grooves are internally provided with rollers (12a) parallel to the axis of the auxiliary shaft (12), the hole wall of the reverse gear combination sleeve (40) is provided with a plurality of roller outer side arc-shaped grooves (5a) which are in one-to-one correspondence with the roller inner side arc-shaped grooves and axially penetrate through the roller inner side arc-shaped grooves, so that the reverse gear combination sleeve (40) can axially slide through the rollers (12a), and the inner radius of the roller inner side arc-shaped grooves and the inner radius of the roller outer side arc-shaped grooves are both larger than the radius of.