CN212080078U

CN212080078U - Multi-stage automatic stepless speed changing box for tractor

Info

Publication number: CN212080078U
Application number: CN202020342662.8U
Authority: CN
Inventors: 王义平; 史金钟; 王东青; 冯春凌; 薛志飞; 徐书雷; 郭志强; 鞠超; 翟营; 王炜
Original assignee: Luoyang Tractor Research Institute Co ltd
Current assignee: Luoyang Tractor Research Institute Co ltd
Priority date: 2020-03-18
Filing date: 2020-03-18
Publication date: 2020-12-04
Anticipated expiration: 2030-03-18

Abstract

The utility model relates to a multi-section automatic stepless gearbox of a tractor, which mainly comprises a power input gear, a differential planet row, a CVT pump, a CVT motor, a reverse clutch, a double clutch, a synchronizer and a PTO input shaft, wherein the double clutch comprises an odd clutch and an even clutch; the utility model discloses the double power flow confluence technique that double entry double-gang differential planet row with two degrees of freedom has combines the stepless speed regulation characteristic of CVT pump and motor, fuses two separation and reunion multistage formula power transmission technique of shifting, has realized that the steady section of trading of transmission does not have the pause and frustrates and feels, and zero is to the uninterrupted stepless speed change of highest rotational speed.

Description

Multi-stage automatic stepless speed changing box for tractor

Technical Field

The utility model belongs to tractor machine field relates to an automatic infinitely variable speed formula gearbox of tractor multistage.

Background

The stepless speed change transmission system has the characteristic of continuous speed ratio of the gearbox, has stable power transmission and strong adaptability, and can ensure that the engine works at the optimal economic point or the optimal power point under any condition. The tractor is particularly suitable for occasions requiring ultra-low speed, occasions requiring frequent change of tractor load and occasions having high requirements on comfort and economy, has good fuel economy, dynamic property, comfort and emission performance, can adapt to the operation of the tractor in various occasions, can realize various functions required by fine agriculture, has incomparable advantages of other transmission systems, and represents the technical development direction of future high-end tractors.

Patent publication No.: EP1541898a2 discloses a CVT transmission for a vehicle, in particular an agricultural tractor, which has a range-changing structure of three synchronizers and two clutches to form four forward ranges and two reverse ranges, with the disadvantages of long axial distance and poor shaft rigidity; the two clutches are located behind the synchronizer, with the disadvantage that the clutches must carry both high torques in low gears and high rotational speeds in high gears.

Patent application publication No.: CN110145571A discloses a power-interruption-free hybrid transmission, wherein the input shaft includes a first input shaft and a second input shaft, the second input shaft is a hollow shaft sleeved on the first input shaft, and the first input shaft and the second input shaft can rotate independently from each other, the clutch structure is an inner and outer sleeved clutch, the structure is complex, and there is no reverse gear.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an adopt the clutch few, simple structure, efficient, the automatic infinitely variable speed formula gearbox technical route scheme of multistage that power does not have the interrupt.

In order to realize the purpose, the utility model discloses the technical scheme who adopts is: a multi-section automatic stepless gearbox of a tractor mainly comprises a power input gear, a differential planet row, a CVT pump, a CVT motor, a reverse clutch, a double-clutch, a synchronizer and a PTO input shaft, wherein the double-clutch comprises an odd-numbered clutch and an even-numbered clutch; the power input gear is respectively meshed with the differential planet row input gear and the CVT pump driving gear shaft; the differential planet row output sun gear shaft is connected with a drive gear of an even-numbered gear clutch, the drive gear is meshed with a gear of the even-numbered gear clutch, an even-numbered gear shaft is connected with an output shaft of the even-numbered clutch, and a driving gear of each gear on the even-numbered gear shaft is correspondingly meshed with a driven gear sleeved on a bevel gear shaft; the sleeved gears on the planet carrier in the differential planet row are also respectively meshed with the odd-numbered gear clutch and the gears on the reverse gear shaft, the odd-numbered gear clutch and the reverse gear clutch are positioned on the same output shaft and are in transmission connection with the odd-numbered gear shaft, each gear driving gear on the odd-numbered gear shaft is correspondingly meshed with the driven gear sleeved on the bevel gear shaft, and the reverse gear shaft is in transmission connection with the gears on the reverse gear clutch; the two synchronizers are respectively corresponding to an odd gear and an even gear and are sleeved on the bevel gear shaft; the CVT pump driving gear shaft is used for transmitting mechanical flow to a CVT pump, converting the mechanical flow into hydraulic flow output through a CVT motor, transmitting the hydraulic flow to a gear ring of a differential planet row through a gear, merging the hydraulic flow with the mechanical flow transmitted to an output sun gear shaft of the differential planet row in the differential planet row, outputting the merged mechanical hydraulic double power flow through two paths, outputting one path of mechanical hydraulic double power flow through a planet carrier, and outputting the other path of mechanical hydraulic double power flow through the output sun gear shaft of the differential planet row; the CVT pump drive gear shaft is also connected to the PTO input shaft through a gear mechanism.

The differential planet row input gear is connected with a differential planet row input sun gear shaft through a spline, a differential planet row duplex planet wheel is sleeved on a planet shaft of a planet carrier through a bearing, a large gear on the differential planet row duplex planet wheel is respectively meshed with a differential planet row gear ring and a differential planet row output sun gear shaft, and a small gear on the differential planet row duplex planet wheel is meshed with the differential planet row input sun gear shaft.

The bevel gear shaft is sleeved with a second-gear driven gear and a fourth-gear driven gear, the second-gear driving gear is meshed with the second-gear driven gear, and the fourth-gear driving gear is meshed with the fourth-gear driven gear.

The synchronizer is sleeved on the bevel gear shaft through a spline, the two synchronizers are respectively an S1 synchronizer and an S2 synchronizer, and the II-gear driven gear and the IV-gear driven gear are respectively positioned on two sides of the S2 synchronizer.

Odd number fender axle rigid coupling I keeps off driving gear and III keeps off the driving gear, I suit keeps off driven gear and III keeps off driven gear on the bevel gear axle, and I keeps off the driving gear and I keeps off driven gear and mesh mutually, and III keep off the driving gear and III keep off driven gear mesh mutually.

The synchronizer is sleeved on the bevel gear shaft through a spline, the two synchronizers are respectively an S1 synchronizer and an S2 synchronizer, and the I-gear driven gear and the III-gear driven gear are respectively positioned on two sides of the S1 synchronizer.

The odd gear shaft is fixedly connected with a gear I driving gear and a gear III driving gear, a gear I driven gear and a gear III driven gear are sleeved on the bevel gear shaft, the gear I driving gear is meshed with the gear I driven gear, and the gear III driving gear is meshed with the gear III driven gear; a second-gear driving gear and a fourth-gear driving gear are fixedly connected to the even-numbered gear shaft, a second-gear driven gear and a fourth-gear driven gear are sleeved on the bevel gear shaft, the second-gear driving gear is meshed with the second-gear driven gear, and the fourth-gear driving gear is meshed with the fourth-gear driven gear; the synchronizer is sleeved on the bevel gear shaft through a spline, the two synchronizers are respectively an S1 synchronizer and an S2 synchronizer, the I-gear driven gear and the III-gear driven gear are respectively positioned on two sides of the S1 synchronizer, and the II-gear driven gear and the IV-gear driven gear are respectively positioned on two sides of the S2 synchronizer.

And the bevel gear shaft is also fixedly connected with a four-wheel drive driving gear, and the four-wheel drive driving gear is arranged on one side of the IV-gear driven gear.

The CVT pump drive gear shaft comprises a CVT pump first drive gear shaft and a CVT pump second drive gear shaft which are coaxially connected, the CVT pump first drive gear shaft and the CVT pump second drive gear shaft are coaxially connected with a PTO leading back driving gear, the PTO leading back driving gear is meshed with a PTO leading back driven gear, and the PTO leading back driven gear is connected with a PTO input shaft.

The second driving gear shaft of the CVT pump is meshed with the input gear of the CVT pump through an idler gear, and the input gear of the CVT pump is connected with the input shaft of the CVT pump; and a CVT motor output gear is arranged on an output shaft of the CVT motor, and is meshed with a gear connected to the differential planet row gear ring through an intermediate gear.

The CVT pump described above is a hydraulic pump for a CVT, and the CVT motor is a motor for a CVT.

The utility model discloses the theory of operation is: the mechanical flow transmitted from the engine is divided into two paths of mechanical flows, one path of mechanical flow is transmitted to an input sun gear of the differential planetary row, the other path of mechanical flow is transmitted to a CVT pump and is converted into hydraulic flow output capable of realizing stepless speed regulation through a CVT motor, the hydraulic flow is transmitted to a gear ring of the differential planetary row through a gear, the mechanical flow and the hydraulic flow realize power confluence in the differential planetary row, the converged mechanical hydraulic double-power flow is output through two paths through a double-clutch transmission technology, and power gear shifting among four gears is realized through a preset synchronizer hanging sequence, so that uninterrupted stepless speed change from zero to the highest rotating speed is realized.

Compared with the prior art, the utility model, reduced clutch quantity, simplified the drive train structure, the creative double power flow confluence technique that has the double entry double-coupling differential planet row of two degrees of freedom combines the stepless speed regulation characteristic of CVT pump and motor, fuses two separation and reunion multistage formula power transmission technique of shifting, has realized that the steady section of trading of drive train does not have the pause and frustrates and feels, and zero is to the uninterrupted infinitely variable speed of highest rotational speed. The double-clutch multi-section power gear-shifting transmission technology enables the functions of the hydraulic pump and the motor to realize stepless speed regulation only at corresponding gears instead of bearing a large amount of power flow, ensures higher efficiency of a transmission system, and is an ideal stepless speed change technology of a tractor.

Drawings

FIG. 1 is a schematic diagram of the transmission principle of the multi-stage automatic stepless transmission of the tractor;

the labels in the figure are: 1. a power input gear, 2, a differential planet row input gear, 3, a CVT pump first drive gear shaft, 4, an intermediate gear, 5, a CVT motor output gear, 6, a CVT pump input gear, 7, an idler gear, 8, a CVT pump second drive gear shaft, 9, a differential planet row ring gear, 10, a differential planet row input sun gear shaft, 11, a differential planet row duplex planet gear, 12, a planet carrier, 13, a differential planet row output sun gear shaft, 14, a K1 clutch, 15, a reverse gear shaft, 16, a reverse driven gear, 17, KR clutch, 18, a four wheel drive gear, 19, K2 clutch drive gear, 20, K2 clutch, 21, II/IV gear shaft, 22, IV gear drive gear, 23, IV gear driven gear, 24, II gear drive gear, 25, II gear driven gear, 26, I/III gear shaft, 27, III gear drive gear, 28. the power transmission system comprises a III-gear driven gear, a 29-gear I driving gear, a 30-gear I driven gear, a 31-gear bevel gear shaft, a 32-gear S1 synchronizer, a 33-gear S2 synchronizer, a 34-gear PTO leading back driving gear, a 35-gear PTO leading back driven gear, a 36-gear CVT pump, a 37-gear CVT motor, a 38-gear PTO input shaft.

Detailed Description

The following detailed description of the present invention is provided with reference to the accompanying drawings and examples, but not to be construed as limiting the present invention in any way.

Referring to the drawings, a multi-stage automatic continuously variable transmission system of a tractor mainly comprises a power input gear 1, a differential planet row input gear 2, a CVT pump first drive gear shaft 3, an intermediate gear 4, a CVT motor output gear 5, a CVT pump input gear 6, an idler gear 7, a CVT pump second drive gear shaft 8, a differential planet row ring gear 9, a differential planet row input sun gear shaft 10, a differential planet row duplex planet gear 11, a planet carrier 12, a differential planet row output sun gear shaft 13, a K1 clutch 14, a reverse gear shaft 15, a reverse gear driven gear 16, a KR clutch 17, a four-wheel drive gear 18, a K2 clutch drive gear 19, a K2 clutch 20, a II/IV gear shaft 21, an IV gear drive gear 22, an IV gear driven gear 23, a II gear drive gear 24, a II gear driven gear 25, an I/III gear shaft 26, a III gear drive gear 27, The third gear driven gear 28, the first gear driving gear 29, the first gear driven gear 30, the bevel gear shaft 31, the synchronizer 32 of S1, the synchronizer 33 of S2, the PTO return driving gear 34, the PTO return driven gear 35, the CVT pump 36, and the CVT motor 37. The K1 clutch 14 is an odd-numbered clutch, the K2 clutch 20 is an even-numbered clutch, and the KR clutch 17 is a reverse clutch. The mechanical hydraulic double-power flow confluence is realized through the differential planet row, the continuous uninterrupted power gear shifting of four gears is realized through double clutches, and the whole-course stepless speed change is realized.

The power input gear 1 is connected with the output end of an engine, the power input gear 1 is respectively meshed with a differential planet row input gear 2 and a CVT pump first drive gear shaft 3, the differential planet row input gear 2 is connected with a differential planet row input sun gear shaft 10 through a spline, a differential planet row duplex planet gear 11 is sleeved on a planet shaft on a planet carrier 12 through a bearing, a large gear on the differential planet row duplex planet gear 11 is respectively meshed with a differential planet row gear ring 9 and a differential planet row output sun gear shaft 13, and a small gear on the differential planet row duplex planet gear 11 is meshed with the differential planet row input sun gear shaft 10.

The differential planet row output sun gear shaft 13 is connected with a K2 clutch driving gear 19, the K2 clutch driving gear 19 is meshed with a gear of a K2 clutch 20, an II/IV gear shaft 21 is connected with an output shaft of the K2 clutch 20, an IV gear driving gear 22 and an II gear driving gear 24 are fixedly connected on the II/IV gear shaft 21, the II gear driving gear 24 is meshed with an II gear driven gear 25 sleeved on a bevel gear shaft 31, and the IV gear driving gear 22 is meshed with an IV gear driven gear 23 sleeved on the bevel gear shaft 31.

The suit gear on the planet carrier 12 meshes with the gear on K1 clutch 14 and the reverse gear wheel axle 15 respectively mutually, K1 clutch 14 and KR clutch 17 are located same output shaft and are connected with I/III fender axle 26, III keep off driving gear 27 and I fender driving gear 29 rigid couplings are on I/III fender axle 26, I keeps off driving gear 29 and the I fender driven gear 30 of suit on bevel gear axle 31 meshes mutually, III keeps off driving gear 27 and the III fender driven gear 28 of suit on bevel gear axle 31 meshes mutually, reverse gear wheel axle 15 is connected with reverse gear driven gear 16, reverse gear driven gear 16 meshes with the gear on the KR clutch 17 mutually.

The S1 synchronizer 32 and the S2 synchronizer 33 are sleeved on the bevel gear shaft 31 through splines, the III-gear driven gear 28 and the I-gear driven gear 30 are respectively positioned on two sides of the S1 synchronizer 32, the IV-gear driven gear 23 and the II-gear driven gear 25 are respectively positioned on two sides of the S2 synchronizer 33, and the four-wheel drive driving gear 18 is fixedly connected to the bevel gear shaft 31 and is arranged beside the IV-gear driven gear 23.

The CVT pump first drive gear shaft 3 is connected to a CVT pump second drive gear shaft 8 and a PTO drive gear 34, the CVT pump second drive gear shaft 8 is engaged with a CVT pump input gear 6 via an idler gear 7, the CVT pump input gear 6 is connected to an input shaft of a CVT pump 36, an output shaft of a CVT motor 37 is connected to a CVT motor output gear 5, the CVT motor output gear 5 is engaged with a gear connected to the differential planet row ring gear 9 via an intermediate gear 4, the PTO drive gear 34 is engaged with a PTO drive driven gear 35, and the PTO drive driven gear 35 is connected to a PTO input shaft 38.

In the mechanical hydraulic double-power flow converging embodiment, a mechanical flow transmitted from an engine is transmitted to a power input gear 1, and then is divided into two mechanical flows through a differential planet row input gear 2 which is simultaneously meshed with the power input gear 1 and a CVT pump first drive gear shaft 3, wherein one mechanical flow is transmitted to a differential planet row input sun gear shaft 10 connected with the differential planet row input gear 2; the other path of mechanical flow is transmitted to a CVT pump second drive gear shaft 8 through the CVT pump first drive gear shaft 3, the CVT pump second drive gear shaft 8 transmits mechanical flow to a CVT pump input gear 6 through an idle gear 7 meshed with the CVT pump second drive gear shaft, the CVT pump input gear 6 is connected with the CVT pump input shaft and transmits the mechanical flow to the CVT pump, the mechanical flow is converted into hydraulic flow capable of achieving stepless speed regulation through a CVT motor and is output to a CVT motor output gear 5 connected with the CVT motor output gear, the CVT motor output gear 5 transmits the hydraulic flow to a differential planet row gear ring 9 through an intermediate gear 4, the mechanical flow at the differential planet row input sun gear shaft 10 and the hydraulic flow at the differential planet row gear ring 9 achieve power confluence in the differential planet row, the converged mechanical hydraulic double power flow is output through two paths, one path of mechanical hydraulic double power flow is output through a planet carrier 12, and the other path of mechanical hydraulic double power flow is output through a differential planet row output sun.

The technical implementation of the multi-section power shifting transmission is as follows: the mechanical hydraulic double power flow after the confluence of the differential planet row is transmitted to the driving end of the K1 clutch 14 through the gear connected with the planet carrier 12, the driven end of the K1 clutch 14 is connected with the I/III gear shaft 26, the III gear driving gear 27 and the I gear driving gear 29 are positioned on the I/III gear shaft 26 and are fixedly connected with the I/III gear shaft, when the K1 clutch 14 is engaged, the double power flow is transmitted through the driven end of the K1 clutch 14 to the i/iii shift shaft 26, and further to the iii gear drive gear 27 and the i gear drive gear 29, when the synchronizer 32 is in the neutral position at S1, the mechanical hydraulic double power flow is not transmitted, when the synchronizer 32 of S1 hitches the driven gear 30 of the first gear, the mechanical hydraulic double power flow is transmitted to the driven gear 30 of the first gear through the driving gear 29 of the first gear and further transmitted to the bevel gear shaft 31, and the first gear is the first gear; similarly, when the synchronizer 32 of S1 hitches the driven gear 28 of the third gear, the mechanical hydraulic double power flow is transmitted to the driven gear 28 of the third gear through the driving gear 27 of the third gear, and then transmitted to the bevel gear shaft 31, which is the third gear at this time.

The other path of the mechanical hydraulic double power flow is transmitted to the K2 clutch driving gear 19 through the differential planet row output sun gear shaft 13 and further transmitted to the driving end of the K2 clutch 20 meshed with the same, the driven end of the K2 clutch 20 is connected with the II/IV gear shaft 21, the IV gear driving gear 22 and the II gear driving gear 24 are positioned on the II/IV gear shaft 21 and fixedly connected with the II/IV gear shaft 21, when the K2 clutch is combined, the mechanical hydraulic double power flow is transmitted to the II/IV gear shaft 21 through the driven end of the K2 clutch 20 and further transmitted to the IV gear driving gear 22 and the II gear driving gear 24, when the S2 synchronizer 33 is positioned at the middle neutral position, the mechanical hydraulic double power flow is not transmitted, when the S2 synchronizer 33 hooks the II gear driven gear 25, the mechanical hydraulic double power flow is transmitted to the II gear driven gear 25 through the II gear driving gear 24 and further transmitted to the bevel gear shaft 31, at this time, gear II is performed; similarly, when the synchronizer 33 of S2 hooks the driven gear 23 of the iv gear, the mechanical hydraulic double power flow is transmitted to the driven gear 23 of the iv gear through the driving gear 22 of the iv gear, and further transmitted to the bevel gear shaft 31, which is the iv gear at this time.

The sequential automatic gear shifting among the four gears can be realized through the preset hooking sequence of the synchronizers.

Reverse gear embodiment: after the differential planet row confluence, the mechanical hydraulic double power flow is transmitted to the driving end of the K1 clutch 14 through the gear connected with the planet carrier 12, and is simultaneously transmitted to the reverse gear shaft 15 simultaneously meshed with the gear connected with the planet carrier 12, the reverse driven gear 16 is connected with the reverse gear shaft 15, the reverse driven gear 16 is connected with the master and slave ends of the KR clutch 17, the slave end of the reverse driven gear 16 is shared with the slave end of the K1 clutch 14, therefore, after the KR clutch 17 is combined, the mechanical hydraulic double power flow is transmitted to the I/III gear shaft 26 through the slave end of the KR clutch 17 and is further transmitted to the III gear driving gear 27 and the I gear driving gear 29, when the S1 synchronizer 32 is located at the middle neutral position, the mechanical hydraulic double power flow is not transmitted, when the S1 synchronizer 32 hitches the I gear driven gear 30, the mechanical hydraulic double power flow is transmitted to the I gear driven gear 30 through the I driving gear 29, further transmitted to the bevel gear shaft 31, and at this time, the reverse gear i is achieved; similarly, when the synchronizer 32 of S1 hitches the driven gear 28 of the third gear, the mechanical hydraulic double power flow is transmitted to the driven gear 28 of the third gear through the driving gear 27 of the third gear, and then transmitted to the bevel gear shaft 31, which is the third gear of the reverse gear at this time.

Implementation of the four-wheel drive: the four-wheel drive driving gear 18 is located on the bevel gear shaft 31 and is fixedly connected with the bevel gear shaft 31 to serve as a four-wheel drive power gear, and the mechanical hydraulic double-power flow transmitted to the bevel gear shaft 31 is transmitted to the four-wheel drive mechanism through the four-wheel drive driving gear 18, so that four-wheel drive of the tractor is achieved.

PTO driven embodiment: the PTO drive gear 34 is connected to the CVT pump first drive gear shaft 3 and the PTO drive driven gear 35 is connected to the PTO input shaft 38. The PTO drive gear 34 intermeshes with the PTO driven gear 35 and engine mechanical flow is transmitted through the power input gear 1 and the CVT pump first drive gear shaft 3 to the PTO drive gear 34 and then to the PTO driven gear 35 which in turn transmits mechanical flow to the PTO input shaft 38.

It should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalent changes may be made in some technical features of the embodiments, such as the type and adjustment of the bearing, and the positioning of the parts. All changes, modifications, equivalents and the like which come within the spirit of the invention are intended to be embraced therein.

Claims

1. Automatic infinitely variable transmission of tractor multistage, its characterized in that: the transmission mainly comprises a power input gear (1), a differential planetary gear, a CVT pump (36), a CVT motor (37), a reverse clutch, a double-clutch, a synchronizer and a PTO input shaft (38), wherein the double-clutch comprises an odd-gear clutch and an even-gear clutch; the power input gear (1) is respectively meshed with the differential planet row input gear (2) and a CVT pump driving gear shaft; the differential planet row output sun gear shaft (13) is connected with a drive gear of an even-numbered gear clutch, the drive gear is meshed with a gear of the even-numbered gear clutch, an even-numbered gear shaft is connected with an output shaft of the even-numbered clutch, and a gear drive gear on the even-numbered gear shaft is correspondingly meshed with a driven gear sleeved on a bevel gear shaft (31); the sleeved gear on the planet carrier (12) in the differential planet row is also respectively meshed with the odd-numbered gear clutch and the gear on the reverse gear shaft (15), the odd-numbered gear clutch and the reverse gear clutch are positioned on the same output shaft and are in transmission connection with the odd-numbered gear shaft, each gear driving gear on the odd-numbered gear shaft is correspondingly meshed with the driven gear sleeved on the bevel gear shaft (31), and the reverse gear shaft (15) is in transmission connection with the gear on the reverse gear clutch; the two synchronizers are respectively corresponding to an odd gear and an even gear and are sleeved on the bevel gear shaft (31); the CVT pump driving gear shaft is used for transmitting mechanical flow to a CVT pump (36), converting the mechanical flow into hydraulic flow output through a CVT motor (37), transmitting the hydraulic flow to a differential planet row gear ring (9) through a gear, merging the mechanical flow transmitted to a differential planet row output sun gear shaft (13) in the differential planet row, outputting the merged mechanical hydraulic double power flow through two paths, outputting one path of mechanical hydraulic double power flow through a planet carrier (12), and outputting the other path of mechanical hydraulic double power flow through the differential planet row output sun gear shaft (13); the CVT pump drive gear shaft is also connected to the PTO input shaft through a gear mechanism.

2. The tractor multistage automatic continuously variable transmission according to claim 1, characterized in that: the differential planet row input gear (2) is connected with a differential planet row input sun gear shaft (10) through a spline, a differential planet row duplex planet wheel (11) is sleeved on a planet shaft of a planet carrier (12) through a bearing, a large gear on the differential planet row duplex planet wheel (11) is respectively meshed with a differential planet row gear ring (9) and a differential planet row output sun gear shaft (13), and a small gear on the differential planet row duplex planet wheel (11) is meshed with the differential planet row input sun gear shaft (10).

3. The tractor multistage automatic continuously variable transmission according to claim 1, characterized in that: the transmission gear is characterized in that an even number gear shaft is fixedly connected with an II-gear driving gear (24) and an IV-gear driving gear (22), the bevel gear shaft (31) is sleeved with an II-gear driven gear (25) and an IV-gear driven gear (23), the II-gear driving gear (24) is meshed with the II-gear driven gear (25), and the IV-gear driving gear (22) is meshed with the IV-gear driven gear (23).

4. The tractor multistage automatic continuously variable transmission according to claim 3, characterized in that: the synchronizer is sleeved on the bevel gear shaft (31) through a spline, the two synchronizers are respectively an S1 synchronizer (32) and an S2 synchronizer (33), and the II-gear driven gear (25) and the IV-gear driven gear (23) are respectively located on two sides of the S2 synchronizer (33).

5. The tractor multistage automatic continuously variable transmission according to claim 1, characterized in that: odd number keeps off I fender driving gear (29) of axle rigid coupling and III fender driving gear (27), I fender driven gear (30) of suit and III fender driven gear (28) are gone up in bevel gear axle (31), and I keeps off driving gear (29) and I fender driven gear (30) mesh mutually, and III keeps off driving gear (27) and III fender driven gear (28) mesh mutually.

6. The tractor multistage automatic continuously variable transmission according to claim 5, characterized in that: the synchronizer is sleeved on the bevel gear shaft (31) through a spline, the two synchronizers are respectively an S1 synchronizer (32) and an S2 synchronizer (33), and the I-gear driven gear (30) and the III-gear driven gear (28) are respectively located on two sides of the S1 synchronizer (32).

7. The tractor multistage automatic continuously variable transmission according to claim 1, characterized in that: the odd gear shaft is fixedly connected with a first-gear driving gear (29) and a third-gear driving gear (27), a first-gear driven gear (30) and a third-gear driven gear (28) are sleeved on the bevel gear shaft (31), the first-gear driving gear (29) is meshed with the first-gear driven gear (30), and the third-gear driving gear (27) is meshed with the third-gear driven gear (28); the bevel gear shaft (31) is sleeved with a second-gear driven gear (25) and a fourth-gear driven gear (23), the second-gear driving gear (24) is meshed with the second-gear driven gear (25), and the fourth-gear driving gear (22) is meshed with the fourth-gear driven gear (23); the synchronizer is sleeved on the bevel gear shaft (31) through a spline, the two synchronizers are respectively an S1 synchronizer (32) and an S2 synchronizer (33), the I-gear driven gear (30) and the III-gear driven gear (28) are respectively located on two sides of the S1 synchronizer (32), and the II-gear driven gear (25) and the IV-gear driven gear (23) are respectively located on two sides of the S2 synchronizer (33).

8. The tractor multistage automatic continuously variable transmission according to claim 7, characterized in that: the bevel gear shaft (31) is further fixedly connected with a four-wheel drive driving gear (18), and the four-wheel drive driving gear (18) is arranged on one side of the IV gear driven gear (23).

9. The tractor multistage automatic continuously variable transmission according to claim 1, characterized in that: the CVT pump drive gear shaft comprises a CVT pump first drive gear shaft (3) and a CVT pump second drive gear shaft (8) which are coaxially connected, and both are coaxially connected with a PTO lead-back drive gear (34), the PTO lead-back drive gear (34) is meshed with a PTO lead-back driven gear (35), and the PTO lead-back driven gear (35) is connected with a PTO input shaft (38).

10. The tractor multistage automatic continuously variable transmission of claim 9, characterized in that: the CVT pump second drive gear shaft (8) is meshed with the CVT pump input gear (6) through an idler gear (7), and the CVT pump input gear (6) is connected with an input shaft of the CVT pump (36); a CVT motor output gear (5) is mounted on an output shaft of the CVT motor (37), and the CVT motor output gear (5) is meshed with a gear connected to the differential planet row ring gear (9) through an intermediate gear (4).