CN111005990B - Compact self-adaptive automatic speed changing system - Google Patents
Compact self-adaptive automatic speed changing system Download PDFInfo
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- CN111005990B CN111005990B CN201911226476.6A CN201911226476A CN111005990B CN 111005990 B CN111005990 B CN 111005990B CN 201911226476 A CN201911226476 A CN 201911226476A CN 111005990 B CN111005990 B CN 111005990B
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16H—GEARING
- F16H3/00—Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion
- F16H3/02—Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion without gears having orbital motion
- F16H3/08—Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion without gears having orbital motion exclusively or essentially with continuously meshing gears, that can be disengaged from their shafts
- F16H3/10—Toothed gearings for conveying rotary motion with variable gear ratio or for reversing rotary motion without gears having orbital motion exclusively or essentially with continuously meshing gears, that can be disengaged from their shafts with one or more one-way clutches as an essential feature
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16D—COUPLINGS FOR TRANSMITTING ROTATION; CLUTCHES; BRAKES
- F16D41/00—Freewheels or freewheel clutches
- F16D41/06—Freewheels or freewheel clutches with intermediate wedging coupling members between an inner and an outer surface
- F16D41/064—Freewheels or freewheel clutches with intermediate wedging coupling members between an inner and an outer surface the intermediate members wedging by rolling and having a circular cross-section, e.g. balls
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16D—COUPLINGS FOR TRANSMITTING ROTATION; CLUTCHES; BRAKES
- F16D43/00—Automatic clutches
- F16D43/02—Automatic clutches actuated entirely mechanically
- F16D43/20—Automatic clutches actuated entirely mechanically controlled by torque, e.g. overload-release clutches, slip-clutches with means by which torque varies the clutching pressure
- F16D43/21—Automatic clutches actuated entirely mechanically controlled by torque, e.g. overload-release clutches, slip-clutches with means by which torque varies the clutching pressure with friction members
- F16D43/213—Automatic clutches actuated entirely mechanically controlled by torque, e.g. overload-release clutches, slip-clutches with means by which torque varies the clutching pressure with friction members with axially applied torque-limiting friction surfaces
- F16D43/215—Automatic clutches actuated entirely mechanically controlled by torque, e.g. overload-release clutches, slip-clutches with means by which torque varies the clutching pressure with friction members with axially applied torque-limiting friction surfaces with flat friction surfaces, e.g. discs
- F16D43/216—Automatic clutches actuated entirely mechanically controlled by torque, e.g. overload-release clutches, slip-clutches with means by which torque varies the clutching pressure with friction members with axially applied torque-limiting friction surfaces with flat friction surfaces, e.g. discs with multiple lamellae
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16D—COUPLINGS FOR TRANSMITTING ROTATION; CLUTCHES; BRAKES
- F16D45/00—Freewheels or freewheel clutches combined with automatic clutches
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16H—GEARING
- F16H37/00—Combinations of mechanical gearings, not provided for in groups F16H1/00 - F16H35/00
- F16H37/02—Combinations of mechanical gearings, not provided for in groups F16H1/00 - F16H35/00 comprising essentially only toothed or friction gearings
- F16H37/06—Combinations of mechanical gearings, not provided for in groups F16H1/00 - F16H35/00 comprising essentially only toothed or friction gearings with a plurality of driving or driven shafts; with arrangements for dividing torque between two or more intermediate shafts
- F16H37/08—Combinations of mechanical gearings, not provided for in groups F16H1/00 - F16H35/00 comprising essentially only toothed or friction gearings with a plurality of driving or driven shafts; with arrangements for dividing torque between two or more intermediate shafts with differential gearing
- F16H37/0806—Combinations of mechanical gearings, not provided for in groups F16H1/00 - F16H35/00 comprising essentially only toothed or friction gearings with a plurality of driving or driven shafts; with arrangements for dividing torque between two or more intermediate shafts with differential gearing with a plurality of driving or driven shafts
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16H—GEARING
- F16H37/00—Combinations of mechanical gearings, not provided for in groups F16H1/00 - F16H35/00
- F16H37/02—Combinations of mechanical gearings, not provided for in groups F16H1/00 - F16H35/00 comprising essentially only toothed or friction gearings
- F16H37/06—Combinations of mechanical gearings, not provided for in groups F16H1/00 - F16H35/00 comprising essentially only toothed or friction gearings with a plurality of driving or driven shafts; with arrangements for dividing torque between two or more intermediate shafts
- F16H37/08—Combinations of mechanical gearings, not provided for in groups F16H1/00 - F16H35/00 comprising essentially only toothed or friction gearings with a plurality of driving or driven shafts; with arrangements for dividing torque between two or more intermediate shafts with differential gearing
- F16H37/0833—Combinations of mechanical gearings, not provided for in groups F16H1/00 - F16H35/00 comprising essentially only toothed or friction gearings with a plurality of driving or driven shafts; with arrangements for dividing torque between two or more intermediate shafts with differential gearing with arrangements for dividing torque between two or more intermediate shafts, i.e. with two or more internal power paths
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16H—GEARING
- F16H63/00—Control outputs from the control unit to change-speed- or reversing-gearings for conveying rotary motion or to other devices than the final output mechanism
- F16H63/02—Final output mechanisms therefor; Actuating means for the final output mechanisms
- F16H63/30—Constructional features of the final output mechanisms
- F16H63/32—Gear shift yokes, e.g. shift forks
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16H—GEARING
- F16H2200/00—Transmissions for multiple ratios
- F16H2200/0021—Transmissions for multiple ratios specially adapted for electric vehicles
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- Engineering & Computer Science (AREA)
- General Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- Structure Of Transmissions (AREA)
Abstract
The invention discloses a compact self-adaptive automatic speed change system which comprises a motor, a shared speed reduction mechanism, a forward gear speed change system and a transmission axle for outputting power. The compact self-adaptive automatic speed changing system adopting the technical scheme has the advantages that the structure is novel, the realization is easy, the first transmission shaft and the second transmission shaft can directly drive the left front wheel and the right front wheel of the vehicle to rotate, the power output of the front-engine front-drive arrangement is realized, the transmission efficiency of the whole transmission axle is high, and the structure is simple, stable and reliable; and the motor can directly transmit power to a forward gear speed change system and a reverse gear speed change system of the transmission through the cooperation of the shared speed reducing mechanism, so that the number of parts is reduced, the structure of the speed change system is simplified, the size of the speed change system is reduced, the speed change system is more compact, and meanwhile, the assembly difficulty is reduced.
Description
Technical Field
The invention relates to the technical field of transmissions, in particular to a compact self-adaptive automatic speed changing system.
Background
The existing electric vehicle is controlled according to experience completely by a driver under the condition that the driving resistance cannot be accurately known due to the limitation of a transmission structure of the existing electric vehicle in the driving process, so that the condition 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.
In order to solve the problems, the inventor designs a series of cam self-adaptive automatic speed changing devices and speed changing bridges, drives the cams by using the driving resistance, achieves the purposes of automatic gear shifting and self-adaptive matching of vehicle speed output torque according to the driving resistance, and has a good application effect.
However, the existing cam self-adaptive automatic speed changing devices are only suitable for a transmission mode of rear drive or front drive and rear drive, and the transmission efficiency is not ideal all the time. Therefore, the inventor hopes to adopt a front-drive transmission mode to improve the transmission efficiency. In addition, the existing motor usually transmits power to a forward gear speed changing system and a reverse gear speed changing system of the transmission through a forward gear speed reducing assembly and a reverse gear speed reducing assembly respectively, so that the problems of multiple parts, complex structure, difficulty in assembly, large size and the like are caused.
It is urgent to solve the above problems.
Disclosure of Invention
To solve the above technical problems, the present invention provides a compact adaptive automatic transmission system.
The technical scheme is as follows:
a compact self-adaptive automatic speed change system is characterized by comprising a motor, a shared speed reducing mechanism, a forward gear speed change system and a transmission axle for outputting power;
the transmission bridge comprises a main shaft, a first transmission shaft and a second transmission shaft which are coaxially arranged at two ends of the main shaft, wherein a forward gear transmission sleeve is rotatably sleeved on the main shaft, one end of the main shaft, which is close to the first transmission shaft, drives the first transmission shaft to synchronously rotate through an intermediate transmission sleeve, one end of the main shaft, which is close to the second transmission shaft, is connected with the second transmission shaft through a differential mechanism, a power transmission sleeve which can rotate relative to the forward gear transmission sleeve is arranged between the differential mechanism and the forward gear transmission sleeve, the power transmission sleeve can transmit power to the main shaft and the second transmission shaft through the differential mechanism, and a reverse gear transmission gear which can rotate relative to the power transmission sleeve and a gear shifting fork sleeve which can axially slide along the power transmission sleeve are sleeved on the power transmission sleeve;
the shared speed reducing mechanism comprises a first-stage speed reducing gear shaft, a second-stage speed reducing gear shaft and a third-stage speed reducing gear shaft which are parallel to each other, the first-stage speed reducing gear shaft can rotate under the driving of a motor and is provided with a first-stage speed reducing driving tooth, a first-stage speed reducing driven gear meshed with the first-stage speed reducing driving tooth is fixedly sleeved on the second-stage speed reducing gear shaft and is provided with a second-stage speed reducing driving tooth, the third-stage speed reducing gear shaft is fixedly sleeved with a second-stage speed reducing driven gear meshed with the second-stage speed reducing driving tooth and a forward gear power gear used for transmitting power to a forward gear speed changing system, and is provided with a reverse gear power tooth meshed with a reverse gear transmission gear;
when the gear shifting fork sleeve is connected with the forward gear transmission sleeve and the power transmission sleeve, the forward gear transmission sleeve transmits power to the power transmission sleeve; when the gear shifting fork sleeve is connected with the reverse gear transmission gear and the power transmission sleeve, the reverse gear transmission gear transmits power to the power transmission sleeve.
By adopting the structure, the first transmission shaft and the second transmission shaft can directly drive the left front wheel and the right front wheel of the vehicle to rotate, so that the power output of the front-mounted front-wheel drive arrangement is realized, the transmission efficiency of the whole transmission axle is high, and the structure is simple, stable and reliable; and the motor can directly transmit power to a forward gear speed change system and a reverse gear speed change system of the transmission through the cooperation of the shared speed reducing mechanism, so that the number of parts is reduced, the structure of the speed change system is simplified, the size of the speed change system is reduced, the speed change system is more compact, and meanwhile, the assembly difficulty is reduced.
Preferably, the method comprises the following steps: the power transmission sleeve comprises a transmission sleeve main body part which is rotatably sleeved on the main shaft through a non-metal supporting sleeve and a differential mechanism mounting disc which synchronously rotates with the transmission sleeve main body part, the transmission sleeve main body part is of a cylindrical structure, the reverse gear transmission gear is rotatably sleeved on the transmission sleeve main body part, the differential mechanism mounting disc is formed by extending the main body part of the transmission sleeve close to one end of the differential mechanism outwards along the radial direction, and is fixedly connected with the differential mechanism through a plurality of bolts, a plurality of roller inner arc-shaped grooves distributed along the circumferential direction are arranged on the main body part of the transmission sleeve, the inner arc-shaped groove of the roller is provided with a first roller parallel to the axis of the power transmission sleeve, the hole wall of the gear shifting fork sleeve is provided with a plurality of outer arc-shaped grooves of the roller which are in one-to-one correspondence with the inner arc-shaped grooves of the roller and axially penetrate through the inner arc-shaped grooves of the roller, so that the shifting fork sleeve can axially slide through the first roller, and the radius in the groove of the arc-shaped groove in the roller and the radius in the groove of the arc-shaped groove outside the roller are both larger than the radius of the first roller. Structure more than adopting, shift and be connected through first roller between fork cover and the power transmission cover, make the fork cover of shifting rotate certain angle relative the transmission cover main part of power transmission cover, possess certain degree of freedom to make the fork cover of shifting change in with the fender transmission cover that advances and reverse gear drive gear combination, greatly improved the smooth and easy degree of shifting, overcome easy the appearance jamming when shifting, be difficult to into the fender, easily damaged scheduling problem, can bear super large moment of torsion simultaneously.
Preferably, the method comprises the following steps: the gear shifting fork sleeve is provided with a gear shifting fork sleeve, a gear shifting fork sleeve is arranged on the gear shifting fork sleeve, the gear shifting fork sleeve is provided with a gear shifting output tooth part, the gear shifting fork sleeve is provided with a gear shifting combination tooth which is capable of being meshed with the gear shifting output tooth part, and the gear shifting fork sleeve is provided with a gear shifting combination tooth which is capable of being meshed with the gear shifting output tooth part. With the above configuration, the power switching between the front and rear gears can be performed stably and reliably.
Preferably, the method comprises the following steps: the forward gear speed changing system comprises a forward gear power input assembly, a high-speed gear transmission mechanism and a low-speed gear transmission mechanism;
the high-speed gear transmission mechanism comprises a friction clutch and an elastic element group for applying pretightening force to the friction clutch, the friction clutch comprises a driving friction piece and a driven friction piece, the power input assembly of the forward gear transmits power to the driving friction piece, the driven friction piece is sleeved on the transmission sleeve of the forward gear and forms a spiral transmission pair with the transmission sleeve of the forward gear, so that the driven friction piece can axially slide along the transmission sleeve of the forward gear;
the low-speed gear transmission mechanism comprises an overrunning clutch and a countershaft transmission assembly, wherein the overrunning clutch is sleeved on the forward gear transmission sleeve through an inner core wheel cam sleeve, the countershaft transmission assembly performs speed reduction transmission between the driving friction piece and the overrunning clutch, and the inner core wheel cam sleeve is in transmission fit with the corresponding end face of the driven friction piece through an end face cam pair so as to transmit power to the forward gear transmission sleeve.
By adopting the structure, under the common cooperation of the friction clutch and the overrunning clutch, when the load borne by the front gear-in transmission sleeve is not large, the power input mechanism transmits power to the front gear-in transmission sleeve sequentially through the active friction piece and the passive friction piece, the self-adaptive automatic speed change system can efficiently transmit power, the motor is in a high-rotating-speed and high-efficiency working state, and the energy consumption is low; when the pure electric vehicle is in low-speed and heavy-load conditions such as starting, climbing and headwind, the rotating speed of the forward gear transmission sleeve is smaller than that of the driven friction piece, the driven friction piece is axially displaced along the forward gear transmission sleeve, the driven friction piece is separated from the driven friction piece, the friction clutch is disconnected, the pure electric vehicle enters a low gear, the power input mechanism transmits power to the forward gear transmission sleeve through the driven friction piece, the auxiliary shaft transmission assembly, the overrunning clutch, the inner core wheel cam sleeve and the driven friction piece in sequence, and at the moment, the self-adaptive automatic speed changing system can be self-adaptively matched with the actual driving working condition and the motor working condition of the pure electric vehicle, so that the pure electric vehicle has strong climbing and heavy-load capabilities, the motor is always positioned on a high-efficiency platform, the efficiency of the motor under the conditions of climbing and heavy load is greatly improved, and the energy consumption of the motor is reduced.
Preferably, the method comprises the following steps: the inner core wheel cam sleeve comprises a power output sub sleeve and a clutch installation sub sleeve which are coaxially arranged, the power output sub sleeve is rotatably sleeved on the forward gear transmission sleeve, one end face of the power output sub sleeve, far away from the clutch installation sub sleeve, is in transmission fit with the corresponding end face of the driven friction piece through an end face cam pair, the overrunning clutch is sleeved on the clutch installation sub sleeve, one end of the clutch installation sub sleeve is fixedly connected with the power output sub sleeve, and the other end of the clutch installation sub sleeve is rotatably sleeved on the forward gear transmission sleeve through the inner core wheel installation sleeve. By adopting the structure, the overrunning clutch can be reliably installed, the power of the overrunning clutch can be stably and reliably transmitted to the driven friction piece, and meanwhile, the lightweight design is convenient.
Preferably, the method comprises the following steps: a third needle bearing is arranged between the inner core wheel mounting sleeve and the transmission sleeve, a first end face bearing is arranged between the forward gear transmission sleeve and the inner core wheel mounting sleeve, a fourth needle bearing is arranged between the power output sub-sleeve and the forward gear transmission sleeve, a second end face bearing is arranged at one end of the power output sub-sleeve close to the clutch mounting sub-sleeve, an end face bearing mounting assembly used for positioning the second end face bearing is arranged on the forward gear transmission sleeve, and the second end face bearing and the end face bearing mounting assembly are positioned in a gap between the clutch mounting sub-sleeve and the forward gear transmission sleeve. By adopting the structure, the reliable installation of the inner core wheel cam sleeve and the overrunning clutch and the reliable matching of adjacent parts can be ensured, meanwhile, the mass and the volume of the inner core wheel cam sleeve can be reduced, and the lightweight design is realized.
Preferably, the method comprises the following steps: the driven friction piece comprises an inner friction cone sleeve and a friction piece cam sleeve fixed at one end of the inner friction cone sleeve close to the inner core wheel cam sleeve, the driven friction piece comprises an outer friction cone sleeve sleeved outside the inner friction cone sleeve and a power output sleeve sleeved outside the friction piece cam sleeve, the inner conical surface of the outer friction cone sleeve is in friction fit with the outer conical surface of the inner friction cone sleeve, the power transmission assembly can transmit power to the outer friction cone sleeve, the cam profile of one end of the friction piece cam sleeve close to the inner core wheel cam sleeve is matched with the cam profile of one end of the inner core wheel cam sleeve to form an end face cam pair transmission pair, the inner hole wall of the inner friction cone sleeve and the outer peripheral surface of the forward blocking transmission sleeve form a spiral cam pair, and the elastic element group applies pretightening force to one end of the inner friction cone sleeve, which is far away from the friction piece cam sleeve. By adopting the structure, when the transmission is performed at a low gear, the elastic element group can be compressed by using the end face cam pair transmission pair of the inner core wheel cam sleeve and the friction piece cam sleeve, so that the friction clutch is in a separation state, and the slow gear transmission is performed.
Preferably, the method comprises the following steps: the overrunning clutch comprises an outer ring and an inner core wheel arranged between a cam sleeve of the inner core wheel and the outer ring, wherein rolling bodies are arranged between the outer ring and the inner core wheel, the rolling bodies are distributed along the periphery of the inner core wheel and are composed of thick rolling bodies and thin rolling bodies which are alternately arranged, two opposite retainers are arranged on the peripheral surface of each inner core wheel, a circle of annular groove is formed in the inner wall of each retainer, and two ends of each thin rolling body are respectively inserted into the corresponding annular grooves in a sliding mode. By adopting the structure, the thick rolling bodies have a meshing effect, and the thin rolling bodies have a sequencing effect, so that each thin rolling body can realize follow-up, the reliability of the overrunning clutch is improved, and the service life is prolonged; meanwhile, the thick rolling bodies and the thin rolling bodies around each inner core wheel are independent of each other, follow up with each other, do not interfere with each other, are self-adaptive, and further improve the overall reliability.
Preferably, the method comprises the following steps: the auxiliary shaft transmission assembly comprises an auxiliary shaft which is arranged in parallel with the forward gear transmission sleeve, an auxiliary shaft primary speed reduction driven gear which can drive the auxiliary shaft to rotate and an auxiliary shaft secondary driving gear which is driven by the auxiliary shaft are sleeved on the auxiliary shaft, an auxiliary shaft primary speed reduction driving gear which is driven by the auxiliary shaft primary speed reduction driving gear is sleeved on the active friction piece and meshed with the auxiliary shaft primary speed reduction driven gear, input driven teeth which are arranged along the circumferential direction are arranged on the outer wall of the outer ring and meshed with the auxiliary shaft secondary driving gear, forward gear combination teeth are arranged on the auxiliary shaft primary speed reduction driven gear, a forward gear combination sleeve which can slide along the axial direction of the auxiliary shaft is sleeved on the auxiliary shaft, and the forward gear combination sleeve can be meshed with the forward gear combination teeth. By adopting the structure, the speed reduction transmission of power can be stably and reliably carried out, the transmission efficiency is high, and the power can be disconnected and the reverse gear power output can be switched through the forward gear combination sleeve design.
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 second rollers parallel to the axis of the auxiliary shaft, the hole wall of the advancing stopper combining 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 advancing stopper combining sleeve can axially slide through the second 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 than the radius of the second rollers. The structure more than adopting, be connected through the roller between the fender combination cover that advances and the countershaft, make the fender combination cover that advances can rotate certain angle relative the countershaft, possess certain degree of freedom to make the fender combination cover that advances change in with the fender combination tooth that advances combine, greatly improved the smooth and easy degree of shifting, overcome easy the appearance jamming when advancing reverse gear, be difficult to advance the fender, easily damage scheduling problem, can bear super large moment of torsion simultaneously.
Compared with the prior art, the invention has the beneficial effects that:
the compact self-adaptive automatic speed changing system adopting the technical scheme has the advantages that the structure is novel, the realization is easy, the first transmission shaft and the second transmission shaft can directly drive the left front wheel and the right front wheel of the vehicle to rotate, the power output of the front-engine front-drive arrangement is realized, the transmission efficiency of the whole transmission axle is high, and the structure is simple, stable and reliable; and the motor can directly transmit power to a forward gear speed change system and a reverse gear speed change system of the transmission through the cooperation of the shared speed reducing mechanism, so that the number of parts is reduced, the structure of the speed change system is simplified, the size of the speed change system is reduced, the speed change system is more compact, and meanwhile, the assembly difficulty is reduced.
Drawings
FIG. 1 is a schematic view of the present invention;
FIG. 2 is a schematic view of a countershaft gearing assembly;
FIG. 3 is a schematic structural view of the forward transmission system;
FIG. 4 is a schematic illustration of a low range transmission;
FIG. 5 is a schematic illustration of a forward drive path of the transaxle;
FIG. 6 is a schematic illustration of a reverse drive path of the transaxle;
FIG. 7 is a schematic structural view of a friction clutch;
FIG. 8 is a cross-sectional view of the overrunning clutch;
fig. 9 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, a compact adaptive automatic transmission system has a main motor 17, a common reduction mechanism, a forward speed change system, and a transaxle 1 for outputting power.
Referring to fig. 5 and 6, the drive axle 1 includes a main shaft 1a, and a first drive shaft 1c and a second drive shaft 1d coaxially disposed at two ends of the main shaft 1a, a forward gear sleeve 1b rotatably sleeved on the main shaft 1a, one end of the main shaft 1a close to the first drive shaft 1c driving the first drive shaft 1c to rotate synchronously through an intermediate transmission sleeve 1f, one end of the main shaft 1a close to the second drive shaft 1d connected to the second drive shaft 1d through a differential 1e, a power transmission sleeve 1g capable of rotating relative to the forward gear sleeve 1b disposed between the differential 1e and the forward gear sleeve 1b, the power transmission sleeve 1g capable of transmitting power to the main shaft 1a and the second drive shaft 1d through the differential 1e, a reverse gear drive gear 1h capable of rotating relative to the power transmission sleeve 1g and a shift fork sleeve 1i capable of sliding axially along the power transmission sleeve 1g, the shift fork sleeve 1i can connect the forward gear transmission sleeve 1b and the power transmission sleeve 1g or connect the reverse gear transmission gear 1h and the power transmission sleeve 1g to perform power switching.
The power transmission sleeve 1g comprises a transmission sleeve main body part 1g1 rotatably sleeved on the main shaft 1a through a non-metal supporting sleeve 1j and a differential installation disc 1g2 synchronously rotating with the transmission sleeve main body part 1g1, the transmission sleeve main body part 1g1 is of a cylindrical structure, the reverse gear transmission gear 1h is rotatably sleeved on the transmission sleeve main body part 1g1, the differential installation disc 1g2 is formed by radially and outwardly extending one end, close to the differential 1e, of the transmission sleeve main body part 1g1 and fixedly connected with the differential 1e through a plurality of bolts, a plurality of roller inner arc-shaped grooves 1g11 distributed along the circumferential direction are arranged on the transmission sleeve main body part 1g1, a first roller 1n parallel to the axis of the power transmission sleeve 1g is arranged in the roller inner arc-shaped groove 1g11, and a plurality of shift fork sleeve 1i hole walls are in one-to one correspondence with the roller inner arc-to-one groove 1g11, And a roller outer arc groove 1i2 extending axially therethrough to enable the shift rail 1i to slide axially through the first roller 1n, the inner radius of the roller inner arc groove 1g11 and the inner radius of the roller outer arc groove 1i2 each being larger than the radius of the first roller 1 n. The nonmetal supporting sleeve 1j is made of nylon materials, has a self-lubricating effect, is good in wear resistance, low in cost and light in weight, and meets the requirement of light weight design.
The end part of the forward gear transmission sleeve 1b close to one end of the power transmission sleeve 1g is provided with a transmission sleeve supporting ring 1b2 extending outwards along the axial direction, the transmission sleeve supporting ring 1b2 is inserted into the transmission sleeve main body part 1g1, and a first needle bearing 1k is arranged between the transmission sleeve supporting ring and the transmission sleeve main body part 1g1, so that the stability and the reliability between adjacent parts are ensured.
The forward gear transmission sleeve 1b has a forward gear output tooth portion 1b1, the reverse gear transmission gear 1h has a reverse gear output tooth portion 1h1, the shift fork sleeve 1i has forward gear engaging teeth 1i1 capable of engaging with the forward gear output tooth portion 1b1 on the side close to the forward gear transmission sleeve 1b, and the shift fork sleeve 1i has reverse gear engaging teeth 1i2 capable of engaging with the reverse gear output tooth portion 1h1 on the side close to the reverse gear transmission gear 1h, so that the forward and reverse gear power switching can be performed stably and reliably.
The middle transmission sleeve 1f is in spline fit with the main shaft 1a and the first transmission shaft 1c, and a first end face bearing 1l is arranged between the end parts of the middle transmission sleeve 1f and the forward gear transmission sleeve 1b close to one end, so that reliable power transmission between the main shaft 1a and the first transmission shaft 1c is ensured, and mutual interference between the middle transmission sleeve 1f and the forward gear transmission sleeve 1b is ensured through the first end face bearing 1 l.
Further, in order to ensure reliable installation of the reverse transmission gear 1h, a second needle bearing 1m is provided between the reverse transmission gear 1h and the transmission sleeve main body portion 1g 1.
Referring to fig. 1, the common reduction mechanism includes a primary reduction gear shaft 18, a secondary reduction gear shaft 19, and a tertiary reduction gear shaft 20 that are parallel to each other, the primary reduction gear shaft 18 is rotatable by a motor 17 and has a primary reduction driving tooth 18a, the secondary reduction gear shaft 19 is fixedly sleeved with a primary reduction driven gear 22 engaged with the primary reduction driving tooth 18a and has a secondary reduction driving tooth 19a, and the tertiary reduction gear shaft 20 is fixedly sleeved with a secondary reduction driven gear 27 engaged with the secondary reduction driving tooth 19a and a forward gear power gear 23 for transmitting power to the forward gear transmission system, and has a reverse gear power tooth 20a engaged with the reverse gear transmission gear 1 h.
Referring to fig. 1 and 3, the forward speed change system includes a forward power input assembly, a high speed transmission mechanism and a low speed transmission mechanism. The forward gear power input assembly comprises a power input gear sleeve 8 and a power transmission sleeve 9, the power input gear sleeve 8 is meshed with the forward gear power gear 23, and the power transmission sleeve 9 is in spline fit with the power input gear sleeve 8 and is fixedly connected with the driving friction piece 2a through a welding process.
Referring to fig. 3 and 7, the high-speed gear transmission mechanism includes a friction clutch 2 and an elastic element set 3 for applying a pre-tightening force to the friction clutch 2, the friction clutch 2 includes a driving friction member 2a and a driven friction member 2b, the power transmission sleeve 9 transmits power to the driving friction member 2a, and the driven friction member 2b is sleeved on the forward gear transmission sleeve 1b and forms a screw transmission pair with the forward gear transmission sleeve 1b, so that the driven friction member 2b can slide axially along the forward gear transmission sleeve 1 b.
The driven friction element 2b includes an inner friction cone 2b1 and a friction element cam sleeve 2b2 fixed to the end of inner friction cone 2b1 adjacent inner cam sleeve 7. The friction inner taper sleeve 2b1 is of a taper cylinder structure, and the friction piece cam sleeve 2b2 is of a cylindrical structure. The driving friction piece 2a comprises a friction outer taper sleeve 2a1 sleeved outside the friction inner taper sleeve 2b1 and a power output sleeve 2a2 sleeved outside the friction piece cam sleeve 2b2, wherein the power output sleeve 2a2 is of a cylindrical structure, and the friction outer taper sleeve 2a1 is of a taper-tube structure. The inner conical surface of the friction outer conical sleeve 2a1 is in friction fit with the outer conical surface of the friction inner conical sleeve 2b1, and the power transmission sleeve 9 is welded with the friction outer conical sleeve 2a1, so that power can be transmitted to the friction outer conical sleeve 2a 1.
Referring to fig. 3, the cam profile structures are machined at the ends of the friction piece cam sleeve 2b2 and the inner core wheel cam sleeve 7 close to each other, and an end face cam pair transmission pair is formed between the cam profile structures. Further, a double cam transmission sleeve 15 is arranged between the inner core wheel cam sleeve 7 and the friction piece cam sleeve 2b2, and cam profile structures which are matched with the cam profile structures on the end faces of the inner core wheel cam sleeve 7 and the friction piece cam sleeve 2b2 are respectively machined on the two end faces of the double cam transmission sleeve 15, so that the double cam transmission sleeve 15 is respectively in transmission fit with the corresponding end faces of the inner core wheel cam sleeve 7 and the friction piece cam sleeve 2b2 through an end face cam pair. The double-cam transmission sleeve 15 is additionally arranged, so that the gear shifting and the disengaging are facilitated.
Referring to fig. 3, the inner hole wall of the inner friction taper sleeve 2b1 and the outer circumferential surface of the forward gear transmission sleeve 1b form a screw transmission pair. Specifically, the helical transmission pair comprises an inner helical raceway 2b12 circumferentially distributed on the inner wall of the inner friction cone sleeve 2b1 and an outer helical raceway 1b3 circumferentially distributed on the outer wall of the forward gear transmission sleeve 1b, wherein a plurality of outwards-protruding balls are embedded in each outer helical raceway 1b3, and each ball can roll in the corresponding inner helical raceway 2b12 and outer helical raceway 1b3 respectively. When the inner friction cone 2b1 rotates relative to the forward gear sleeve 1b, it can move axially relative to the forward gear sleeve 1b, so that the driven friction piece 2b is engaged with or disengaged from the driving friction piece 2a, i.e. the friction clutch 2 is engaged or disengaged.
The elastic element group 3 applies a preload force to one end of the inner friction cone sleeve 2b1 far away from the cam sleeve 2b2 of the friction piece. Specifically, a plurality of concentric annular raceways 2b11 are distributed on the end face of the inner friction cone 2b1 close to one end of the elastic element group 3, an end face bearing 21 is arranged between the inner friction cone 2b1 and the elastic element group 3, the end face bearing 21 comprises a bearing support plate 21b and a plurality of bearing balls 21a supported between the bearing support plate 21b and the inner friction cone 2b1, and each bearing ball 21a can roll along the corresponding annular raceway 2b 11. Through the structure, the end face of the friction inner taper sleeve 2b1 can be used as a bearing supporting disc on one side, so that the manufacturing cost is saved, and the assembly space is saved.
The elastic element group 3 can apply a pre-tightening force to the driven friction piece 2b, so that the driving friction piece 2a and the driven friction piece 2b are kept in a combined state, namely the friction clutch 2 is kept in a combined state. In this embodiment, the elastic element group 3 preferably adopts a disc spring, which is stable, reliable, low in cost, and capable of continuously applying an axial thrust to the end bearing 21.
Referring to fig. 3 and 4, the low-speed gear transmission mechanism comprises an overrunning clutch 6 sleeved on the forward gear transmission sleeve 1b through an inner core wheel cam sleeve 7, and a countershaft transmission assembly for reducing the speed between the active friction piece 2a and the overrunning clutch 6, wherein the inner core wheel cam sleeve 7 is in transmission fit with the corresponding end face of the passive friction piece 2b through an end face cam pair so as to transmit power to the forward gear transmission sleeve 1 b.
The overrunning clutch 6 includes an outer ring 6a and an inner core 6c provided between the inner core cam sleeve 7 and the outer ring 6a, and rolling elements are provided between the outer ring 6a and the inner core 6 c.
The inner core wheel cam sleeve 7 comprises a power output sub sleeve 7a and a clutch installation sub sleeve 7b which are coaxially arranged, the power output sub sleeve 7a is rotatably sleeved on the forward gear transmission sleeve 1b, one end face, far away from the clutch installation sub sleeve 7b, of the power output sub sleeve 7a is in transmission fit with the corresponding end face of the driven friction piece 2b through an end face cam pair, the multi-row overrunning clutch 6 is sleeved on the clutch installation sub sleeve 7b, one end of the clutch installation sub sleeve 7b is fixedly connected with the power output sub sleeve 7a, and the other end of the clutch installation sub sleeve 7b is rotatably sleeved on the forward gear transmission sleeve 1b through the inner core wheel installation sleeve 30.
A third needle bearing 31 is arranged between the inner core wheel mounting sleeve 30 and the middle transmission sleeve 1f, a first end surface bearing 1l is arranged between the forward gear transmission sleeve 1b and the inner core wheel mounting sleeve 30, a fourth needle bearing 33 is arranged between the power output sub-sleeve 7a and the forward gear transmission sleeve 1b, a second end surface bearing 34 is arranged at one end of the power output sub-sleeve 7a close to the clutch mounting sub-sleeve 7b, an end surface bearing mounting assembly 35 for positioning the second end surface bearing 34 is arranged on the forward gear transmission sleeve 1b, and the second end surface bearing 34 and the end surface bearing mounting assembly 35 are positioned in a gap between the clutch mounting sub-sleeve 7b and the forward gear transmission sleeve 1 b.
The inner core wheel cam sleeve 7 is made of a high-strength anti-torsion material, the inner core wheel 6c is made of a pressure-resistant wear-resistant material, specifically, the inner core wheel cam sleeve 7 is made of alloy steel, and the inner core wheel 6c is made of bearing steel or alloy steel or hard alloy. In this embodiment, the material of the inner core wheel cam sleeve 7 is preferably 20CrMnTi, and has strong torsion resistance, low cost and high cost performance, and the material of the inner core wheel 6c is preferably GCr15, and has good wear-resistant and pressure-resistant performance, low cost and high cost performance. The torsion resistance and the pressure resistance of the inner core wheel cam sleeve 7 are high, the reliability and the stability of transmission can be ensured, and the abrasion resistance and the pressure resistance of the inner core wheel 6c are high, so that the inner core wheel cam sleeve 7 and the inner core wheel 6c are made of two different materials, the production cost is effectively saved, and the service life of the heavy-load overrunning clutch is greatly prolonged.
Referring to fig. 8 and 9, the rolling elements distributed along the outer periphery of the inner core wheel 6c are composed of thick rolling elements 6d and thin rolling elements 6e which are alternately arranged, two opposite retainers 6f are arranged on the outer peripheral surface of the inner core wheel 6c, a ring of annular grooves 6f1 are formed in the inner wall of each retainer 6f, and two ends of each thin rolling element 6e are slidably inserted into the corresponding annular grooves 6f 1. 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 outer ring 6a has input driven teeth 6a1 on its outer wall, which are circumferentially disposed. The outer wall of the inner core wheel cam sleeve 7 is in spline fit with the inner wall of the inner core wheel 6 c. With the above configuration, power transmission can be reliably performed.
The number of teeth of the inner spline of the inner core wheel 6c is twice that of the outer teeth 6c 1. The installation and debugging are convenient, so that the problem that the inner rings are not synchronous is solved.
The external teeth 6c1 include top arc section 6c12 and short side section 6c11 and long side section 6c13 that are located top arc section 6c12 both sides respectively, short side section 6c11 is the arc structure of inside sunken, long side section 6c13 is the arc structure of outside protrusion, the camber of short side section 6c11 is less than the camber of long side section 6c 13. By adopting the structure, the stability and the reliability of the one-way transmission function can be ensured.
Referring to fig. 1-3, the countershaft gearing assembly includes a countershaft 12 disposed parallel to the forward drive sleeve 1b, an auxiliary shaft primary reduction driven gear 13 capable of driving the auxiliary shaft 12 to rotate and an auxiliary shaft secondary driving gear 14 driven by the auxiliary shaft 12 are sleeved on the auxiliary shaft 12, the driving friction piece 2a is sleeved with a primary reduction driving gear 16 of an auxiliary shaft driven by the driving friction piece, the primary countershaft reduction drive gear 16 meshes with the primary countershaft reduction driven gear 13, the outer ring 6a has input driven teeth 6a1 on the outer wall thereof, the input driven teeth 6a1 mesh with a secondary countershaft driving gear 14, which has forward gear engaging teeth 13a on the primary reduction driven gear 13, a forward gear coupling sleeve 5 that is slidable in the axial direction thereof is fitted over the counter shaft 12, and the forward gear coupling sleeve 5 is engageable with the forward gear coupling teeth 13 a.
The outer periphery of the auxiliary shaft 12 is provided with a plurality of roller inner side arc-shaped grooves 12a distributed along the circumferential direction, the roller inner side arc-shaped grooves 12a are internally provided with second rollers 12b parallel to the axis of the auxiliary shaft 12, the hole wall of the forward gear combination sleeve 5 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 12a and axially penetrate through the roller inner side arc-shaped grooves 12a, so that the forward gear combination sleeve 5 can axially slide through the second rollers 12b, and the inner radius of the roller inner side arc-shaped grooves 12a and the inner radius of the roller outer side arc-shaped grooves 5a are both larger than the radius of the second rollers 12 b. The forward gear coupling sleeve 5 has forward gear drive teeth 5b corresponding to the forward gear coupling teeth 13 a. Specifically, in the forward gear, the forward gear drive teeth 5b are engaged with the forward gear engagement teeth 13 a; in reverse gear, the forward drive gear 5b is disengaged from the forward engaging gear 13 a.
First, forward gear (forward rotation of motor): the forward gear drive teeth 5b are engaged with the forward gear engaging teeth 13 a; the forward speed output gear portion 1b1 meshes with the forward speed engagement gear 1i 1.
In the present embodiment, the elastic element group 3 applies pressure via each end face bearing 21 to couple the driven friction member 2b and the driven friction member 2a of the friction clutch 2, and at this time, the friction clutch 2 is in a coupled state under the pressure of the elastic element group 3, and the power is in a high-speed power transmission path:
the motor 17 → the first reduction gear shaft 18 → the first reduction driven gear 22 → the second reduction gear shaft 19 → the second reduction driven gear 27 → the third reduction gear shaft 20 → the forward gear power gear 23 → the power input sleeve 8 → the power transmitting sleeve 9 → the driving friction member 2a → the driven friction member 2b → the forward gear sleeve 1b → the shift sleeve 1i → the power transmitting sleeve 1g → the differential 1e → the main shaft 1a, the first transmission shaft 1c and the second transmission shaft 1d, and the power is output from the first transmission shaft 1c and the second transmission shaft 1 d.
At this time, the overrunning clutch 6 overruns, and the elastic element group 3 is not compressed. Currently, the resistance transmission route: the forward gear transmission sleeve 1b → the inner core wheel cam sleeve 7 → the double cam transmission sleeve 15 → the driven friction member 2b → the end face bearing 21 → the elastic element group 3; when the resisting torque transmitted to the friction clutch 2 by the forward gear transmission sleeve 1b is larger than or equal to the preset load limit of the friction clutch 2, the double-cam transmission sleeve 15 and the screw transmission pair jointly use the driven friction piece 2b to compress the elastic element group 3, so that the driven friction piece 2b and the driven friction piece 2a of the friction clutch 2 are separated, a gap is formed, and the power is transmitted through the following route instead, namely a low-gear power transmission route:
the motor 17 → the first-stage reduction gear shaft 18 → the first-stage reduction driven gear 22 → the second-stage reduction gear shaft 19 → the second-stage reduction driven gear 27 → the third-stage reduction gear shaft 20 → the forward gear power gear 23 → the power input sleeve 8 → the power transmission sleeve 9 → the driving friction member 2a → the first-stage reduction driving gear 16 of the counter shaft → the first-stage reduction driven gear 13 of the counter shaft → the counter shaft 12 → the second-stage driving gear 14 of the counter shaft → the overrunning clutch 6 → the inner core cam sleeve 7 → the double cam sleeve 15 → the driving friction member 2b → the forward gear sleeve 1b → the shift sleeve 1i → the power transmission sleeve 1g → the differential 1e → the main shaft 1a, the first transmission shaft 1c and the second transmission shaft 1d, and the power is output from the first transmission shaft 1c and the second transmission shaft 1 d.
At this time, the overrunning clutch 6 is not overrunning, and the elastic element group 3 is compressed. As can be seen from the above transmission path, the present invention forms an automatic transmission mechanism that maintains a certain pressure during operation.
In the embodiment, taking an electric automobile as an example, when the whole automobile is started, the resistance is greater than the driving force, the resistance forces the forward gear transmission sleeve 1b to rotate a certain angle relative to the driven friction piece 2b, under the action of a spiral transmission pair, the driven friction piece 2b compresses the elastic element group 3 through the end face bearing 21, the driven friction piece 2b is separated from the driven friction piece 2a, namely, the friction clutch 2 is in a disconnected state, and meanwhile, the power is transmitted to the forward gear transmission sleeve 1b through the auxiliary shaft transmission assembly, the overrunning clutch 6, the inner core wheel cam sleeve 7 and the inner driven friction piece 2b in sequence 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, when the component force is reduced to be smaller than the pressure generated by the elastic element group 3, the driven friction piece 2b and the driven friction piece 2a of the friction clutch 2 are restored to the close fit state under the pushing action of the rapid release of the pressure generated by the elastic element group 3 due to the compression of the motion resistance, the overrunning clutch 6 is in the overrunning state, and the power is transmitted to the forward gear transmission sleeve 1b through the driven friction piece 2a and the driven friction piece 2b in sequence to rotate at the high 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.
Second, reverse gear (motor reverse): the forward gear driving teeth 5b are separated from the forward gear engaging teeth 13 a; the reverse output gear 1h1 meshes with the reverse engagement gear 1i 2.
Reverse gear power transmission route: the motor 17 → the first reduction gear shaft 18 → the first reduction driven gear 22 → the second reduction gear shaft 19 → the second reduction driven gear 27 → the third reduction gear shaft 20 → the reverse drive gear 1h → the shift fork bush 1i → the power transmission bush 1g → the differential 1e → the main shaft 1a, the first drive shaft 1c and the second drive shaft 1d, and the first drive shaft 1c and the second drive shaft 1d 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 (9)
1. A compact adaptive automatic transmission system characterized by: comprises a motor (17), a common speed reducing mechanism, a forward gear speed changing system and a transmission axle (1) for outputting power; the transmission bridge (1) comprises a main shaft (1 a), a first transmission shaft (1 c) and a second transmission shaft (1 d) which are coaxially arranged at two ends of the main shaft (1 a), a forward gear transmission sleeve (1 b) is rotatably sleeved on the main shaft (1 a), one end of the main shaft (1 a) close to the first transmission shaft (1 c) drives the first transmission shaft (1 c) to synchronously rotate through an intermediate transmission sleeve (1 f), one end of the main shaft (1 a) close to the second transmission shaft (1 d) is connected with the second transmission shaft (1 d) through a differential (1 e), a power transmission sleeve (1 g) which can rotate relative to the forward gear transmission sleeve (1 b) is arranged between the differential (1 e) and the forward gear transmission sleeve (1 b), and the power transmission sleeve (1 g) can transmit power to the main shaft (1 a) and the second transmission shaft (1 d) through the differential (1 e), a reverse gear transmission gear (1 h) capable of rotating relative to the power transmission sleeve (1 g) and a gear shifting fork sleeve (1 i) capable of sliding along the axial direction of the power transmission sleeve are sleeved on the power transmission sleeve (1 g); the shared speed reducing mechanism comprises a primary speed reducing gear shaft (18), a secondary speed reducing gear shaft (19) and a tertiary speed reducing gear shaft (20) which are parallel to each other, the primary speed reducing gear shaft (18) can be driven by a motor (17) to rotate and is provided with a primary speed reducing driving tooth (18 a), a primary speed reducing driven gear (22) meshed with the primary speed reducing driving tooth (18 a) is fixedly sleeved on the secondary speed reducing gear shaft (19) and is provided with a secondary speed reducing driving tooth (19 a), the tertiary speed reducing gear shaft (20) is fixedly sleeved with a secondary speed reducing driven gear (27) meshed with the secondary speed reducing driving tooth (19 a) and a forward gear power gear (23) used for transmitting power to a forward gear speed changing system, and is provided with a reverse gear power tooth (20 a) meshed with a reverse gear (1 h); when the gear shifting fork sleeve (1 i) is connected with the forward gear transmission sleeve (1 b) and the power transmission sleeve (1 g), the forward gear transmission sleeve (1 b) transmits power to the power transmission sleeve (1 g); when the gear shifting fork sleeve (1 i) is connected with the reverse gear transmission gear (1 h) and the power transmission sleeve (1 g), the reverse gear transmission gear (1 h) transmits power to the power transmission sleeve (1 g); the forward gear speed changing system comprises a forward gear power input assembly, a high-speed gear transmission mechanism and a low-speed gear transmission mechanism; the high-speed gear transmission mechanism comprises a friction clutch (2) and an elastic element group (3) for applying pretightening force to the friction clutch (2), the friction clutch (2) comprises a driving friction piece (2 a) and a driven friction piece (2 b), the driving friction piece (2 a) is transmitted by the driving gear power input assembly, the driven friction piece (2 b) is sleeved on a driving gear transmission sleeve (1 b), and a spiral transmission pair is formed between the driven friction piece and the driving gear transmission sleeve (1 b), so that the driven friction piece (2 b) can axially slide along the driving gear transmission sleeve (1 b); the low-speed gear transmission mechanism comprises an overrunning clutch (6) which is sleeved on the forward gear transmission sleeve (1 b) through an inner core wheel cam sleeve (7) and a countershaft transmission assembly which performs speed reduction transmission between the driving friction piece (2 a) and the overrunning clutch (6), wherein the inner core wheel cam sleeve (7) is in transmission fit with the corresponding end surface of the driven friction piece (2 b) through an end surface cam pair so as to transmit power to the forward gear transmission sleeve (1 b).
2. The compact adaptive automatic transmission system according to claim 1, characterized in that: the power transmission sleeve (1 g) comprises a transmission sleeve main body part (1 g 1) rotatably sleeved on the main shaft (1 a) through a non-metal supporting sleeve (1 j) and a differential mechanism mounting disc (1 g 2) synchronously rotating with the transmission sleeve main body part (1 g 1), the transmission sleeve main body part (1 g 1) is of a cylindrical structure, a reverse gear transmission gear (1 h) is rotatably sleeved on the transmission sleeve main body part (1 g 1), the differential mechanism mounting disc (1 g 2) is formed by radially and outwardly extending one end, close to the differential mechanism (1 e), of the transmission sleeve main body part (1 g 1) and fixedly connected with the differential mechanism (1 e) through a plurality of bolts, a plurality of roller inner arc-shaped grooves (1 g 11) distributed along the circumferential direction are formed in the transmission sleeve main body part (1 g 1), and first rollers (1 n) parallel to the axis of the power transmission sleeve (1 g) are arranged in the roller inner arc-shaped grooves (1 g 11), the hole wall of the gear shifting fork sleeve (1 i) is provided with a plurality of outer roller arc-shaped grooves (1 i 2) which are in one-to-one correspondence with the inner roller arc-shaped grooves (1 g 11) and axially penetrate through the inner roller arc-shaped grooves, so that the gear shifting fork sleeve (1 i) can axially slide through the first roller (1 n), and the inner radius of the inner roller arc-shaped groove (1 g 11) and the inner radius of the outer roller arc-shaped groove (1 i 2) are both larger than the radius of the first roller (1 n).
3. The compact adaptive automatic transmission system according to claim 1, characterized in that: the forward gear transmission sleeve (1 b) is provided with a forward gear output tooth part (1 b 1), the reverse gear transmission gear (1 h) is provided with a reverse gear output tooth part (1 h 1), one side of the gear shifting fork sleeve (1 i) close to the forward gear transmission sleeve (1 b) is provided with a forward gear combination tooth (1 i 1) capable of being meshed with the forward gear output tooth part (1 b 1), and one side of the gear shifting fork sleeve (1 i) close to the reverse gear transmission gear (1 h) is provided with a reverse gear combination tooth (1 i 2) capable of being meshed with the reverse gear output tooth part (1 h 1).
4. The compact adaptive automatic transmission system according to claim 1, characterized in that: the inner core wheel cam sleeve (7) comprises a power output sub sleeve (7 a) and a clutch installation sub sleeve (7 b) which are coaxially arranged, the power output sub sleeve (7 a) is rotatably sleeved on the forward gear transmission sleeve (1 b), one end face of the power output sub sleeve (7 a), far away from the clutch installation sub sleeve (7 b), is in transmission fit with the corresponding end face of the driven friction piece (2 b) through an end face cam pair, the overrunning clutch (6) is sleeved on the clutch installation sub sleeve (7 b), one end of the clutch installation sub sleeve (7 b) is fixedly connected with the power output sub sleeve (7 a), and the other end of the clutch installation sub sleeve (7 b) is rotatably sleeved on the forward gear transmission sleeve (1 b) through the inner core wheel installation sleeve (30).
5. The compact adaptive automatic transmission system according to claim 4, characterized in that: a third needle bearing (31) is arranged between the inner core wheel mounting sleeve (30) and the middle transmission sleeve (1 f), a first end face bearing (1 l) is arranged between the forward gear transmission sleeve (1 b) and the inner core wheel mounting sleeve (30), a fourth needle bearing (33) is arranged between the power output sub-sleeve (7 a) and the forward gear transmission sleeve (1 b), a second end face bearing (34) is arranged at one end, close to the clutch mounting sub-sleeve (7 b), of the power output sub-sleeve (7 a), an end face bearing mounting assembly (35) used for positioning the second end face bearing (34) is arranged on the forward gear transmission sleeve (1 b), and the second end face bearing (34) and the end face bearing mounting assembly (35) are located in a gap between the clutch mounting sub-sleeve (7 b) and the forward gear transmission sleeve (1 b).
6. The compact adaptive automatic transmission system according to claim 1, characterized in that: the driven friction piece (2 b) comprises an inner friction cone sleeve (2 b 1) and a friction piece cam sleeve (2 b 2) fixed at one end, close to the inner core wheel cam sleeve (7), of the inner friction cone sleeve (2 b 1), the driven friction piece (2 a) comprises an outer friction cone sleeve (2 a 1) sleeved outside the inner friction cone sleeve (2 b 1) and a power output sleeve (2 a 2) sleeved outside the friction piece cam sleeve (2 b 2), an inner conical surface of the outer friction cone sleeve (2 a 1) is in friction fit with an outer conical surface of the inner friction cone sleeve (2 b 1), the power transmission assembly can transmit power to the outer friction cone sleeve (2 a 1), one end cam profile surfaces, close to each other, of the inner friction piece cam sleeve (2 b 2) and the inner core wheel cam sleeve (7) are in friction fit to form an end face cam pair transmission pair, an inner wall of the inner friction cone sleeve (2 b 1) and an outer peripheral surface of the forward stop transmission sleeve (1 b) form a spiral transmission pair, the elastic element group (3) applies pretightening force to one end of the friction inner taper sleeve (2 b 1) far away from the friction piece cam sleeve (2 b 2).
7. The compact adaptive automatic transmission system according to claim 1, characterized in that: the overrunning clutch (6) comprises an outer ring (6 a) and an inner core wheel (6 c) arranged between an inner core wheel cam sleeve (7) and the outer ring (6 a), rolling bodies are arranged between the outer ring (6 a) and the inner core wheel (6 c), the rolling bodies distributed along the periphery of the inner core wheel (6 c) are composed of thick rolling bodies (6 d) and thin rolling bodies (6 e) which are alternately arranged, two opposite retainers (6 f) are arranged on the peripheral surface of each inner core wheel (6 c), a circle of annular groove (6 f 1) is formed in the inner wall of each retainer (6 f), and two ends of each thin rolling body (6 e) are slidably inserted into the corresponding annular grooves (6 f 1).
8. The compact adaptive automatic transmission system according to claim 7, characterized in that: the auxiliary shaft transmission assembly comprises an auxiliary shaft (12) which is arranged in parallel with a forward gear transmission sleeve (1 b), an auxiliary shaft primary speed reduction driven gear (13) which can drive the auxiliary shaft (12) to rotate and an auxiliary shaft secondary driving gear (14) which is driven by the auxiliary shaft (12) are sleeved on the auxiliary shaft (12), an auxiliary shaft primary speed reduction driving gear (16) which is driven by the auxiliary shaft primary speed reduction driven gear is sleeved on the driving friction piece (2 a), the auxiliary shaft primary speed reduction driving gear (16) is meshed with the auxiliary shaft primary speed reduction driven gear (13), input driven teeth (6 a 1) which are arranged along the circumferential direction are arranged on the outer wall of the outer ring (6 a), the input driven teeth (6 a 1) are meshed with the auxiliary shaft secondary driving gear (14), forward gear combination teeth (13 a) are arranged on the primary speed reduction driven gear (13), and a forward gear combination sleeve (5) which can slide along the axial direction of the auxiliary shaft (12) is sleeved on the auxiliary shaft, the forward gear coupling sleeve (5) can be meshed with the forward gear coupling teeth (13 a).
9. The compact adaptive automatic transmission system according to claim 8, characterized in that: the outer periphery of the auxiliary shaft (12) is provided with a plurality of roller inner side arc-shaped grooves (12 a) distributed along the circumferential direction, second rollers (12 b) parallel to the axis of the auxiliary shaft (12) are arranged in the roller inner side arc-shaped grooves (12 a), a plurality of roller outer side arc-shaped grooves (5 a) which are in one-to-one correspondence with the roller inner side arc-shaped grooves (12 a) and axially penetrate through the hole wall of the forward gear combination sleeve (5) are arranged, so that the forward gear combination sleeve (5) can axially slide through the second rollers (12 b), and the inner radius of the roller inner side arc-shaped grooves (12 a) and the inner radius of the roller outer side arc-shaped grooves (5 a) are both larger than the radius of the second rollers (12 b).
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