RU2738665C1 - Multi-stage gearbox with dual clutch - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to multistage gearbox with dual clutch. Multistage transmission (10) comprises housing (12) of main reduction gear (13) with multiple paired gears (14-15), (16-17), (18-19), (20-21), (22-23), (24-25-26), controlled by couplings (27), (28) and (29), to obtain different gear ratios. Gears (14), (16), (18), (20), (22) and (24) are installed on primary shafts of round solid (30) and hollow (31) sections. Shafts (30) and (31) are connected via two clutch couplings (32) and (33) to input shaft (34). Gears (15), (17), (19), (21), (23) and (25) are arranged on intermediate shaft (35) passing through support plate (36). In gearbox (10) gears (14), (16), (18), (20), (22) and (24) are rigidly fixed on shafts (30) and (31) and located one after another. Double-sided couplings (27), (28) and (29) are mounted in series in gaps (38), (39) and (40) between each pair of gears (17-19), (15-23), (21-25), installed freely on intermediate shaft (35). Shaft (35) is rigidly fixed to block (42) of gears (43) and (44) of additional reduction gear (45). Gears (43) and (44) are engaged with gears (46) and (47) installed freely on output shaft (37). Gears (46) and (47) are controlled by two-way clutch (48). Output shaft (37) has section (49) passing through support plate (36). On section (49) one-way coupling (50) is installed, which is located coaxially to gear rim with friction cone (51). Gear rim with cone (51) is fixed on primary shaft (30) of solid cross-section.

EFFECT: higher traction-speed characteristics of vehicle.

4 cl, 2 dwg

Description

The invention relates to a vehicle transmission and, above all, to multi-stage dual-clutch transmissions.

US Patent Application Publication No. 2016/0116035 A1 shows a multi-stage dual clutch transmission comprising a main gearbox with two coaxially arranged input gear shafts driven by two clutches and permanently meshed with the countershaft drive gears on which couplings and gears controlled by them, having constant engagement with stationary gears located on the secondary shaft connected to the sun gear of an additional planetary gearbox controlled by its own clutch, the planetary gearbox carrier is connected to the output shaft, on which the clutch and the driven gear of the single-stage gearbox are installed, meshed with the drive gear mounted on the intermediate shaft of the gearbox. In this device, torque conversion is carried out in two separate streams using two parallel intermediate shafts. Each intermediate shaft is connected to its own clutch and has a gear meshed with the gear of its primary shaft, with different gear ratios. The kinematic diagram of this gearbox allows to obtain only seven forward gears with the highest direct and one reverse gear, which indicates a small range of gear ratios of the main gearbox, used mainly with the lowest stage of the auxiliary gearbox, limiting its functionality. Thus, this multistage gearbox has a complex structure with an increased number of parts and control clutches, with limited use of an additional gearbox, which leads to an increase in internal power losses in it, deteriorates the functionality and traction-speed performance of the vehicle.

A closer analogue is the multi-speed dual-clutch transmission presented in EP 1936234 published by the European Patent Office. It contains a main gearbox housing with paired gears of constant engagement, controlled by couplings to obtain different gear ratios, one of the paired gears are installed on coaxially located input shafts of round solid and hollow sections, connected through two normally open clutches with the input shaft, others are located on the intermediate a shaft passing through the base plate of the housing and connected to the output shaft of the gearbox through an additional step transmission with paired gears controlled by the clutch. This multi-stage gearbox has six gears in its main gearbox and two gears in the secondary gearbox. One of the stepped gears in the additional gearbox consists of a pair of gears, one of which is fixedly connected to the intermediate shaft, the other is fixedly connected to the output shaft, forming a constant reduction gear used throughout the entire range of gear ratios. As a result, the transmission allows for seven forward gears with top direct and one reverse gear. Reducing the range and number of gears, with such a gearbox scheme, with the limited functionality of the additional gearbox, in which the torque transformation is carried out by a constant gear and any other one of the forward gears when it is turned on by the clutch in the main or additional gearboxes, which increases the relative work under load and differences in angular speeds of gears of adjacent gears and their engagement couplings. In addition, operation in any of these gears is accompanied by an increase in internal power losses associated with a significant number of freely rotating gears that do not participate in the conversion of torque, which, in addition to the absence of a power distribution unit in this gearbox, impairs its functionality and traction and speed. vehicle performance.

The technical problem to be solved is the creation of a multi-stage double-clutch gearbox with wide functionality that allows to increase the traction and speed indicators of the vehicle.

The solution to the technical problem of creating a multi-stage double-clutch gearbox, which has wide functionality, which makes it possible to increase the traction-speed performance of the vehicle, is achieved by the fact that the multi-stage double-clutch gearbox contains a main gearbox housing with a plurality of paired constant mesh gears controlled by couplings to obtain different gear ratios. One of the paired gears is mounted on coaxially located input shafts of round solid and hollow sections, connected to the input shaft through two normally open friction clutches. The other of the paired gears are located on an intermediate shaft passing through the base plate of the housing and connected kinematically with the output shaft of the gearbox, in which the gears on the input shafts of the main gearbox are fixed immovably, located one after the other and meshed with gears driven by double-sided couplings mounted in series in the intervals between each pair of these gears, mounted freely on the intermediate shaft, fixedly connected to the gear block of the additional two-stage gearbox, meshed with two controlled double-sided clutch gears, mounted freely on the output shaft of the gearbox, having a section passing through the base plate of the housing, and on it a one-way control clutch is installed, located coaxially to the gear rim with a friction cone, fixed on the input shaft of solid section.

With such a design of a multi-stage double-clutch transmission, its functionality is expanded, the relative work under load and the differences in angular speeds of the gears of adjacent gears and their engagement clutches are reduced, reducing internal power losses over the entire range of gear ratios, which increases the traction and speed indicators of the vehicle ...

The solution to the technical problem is also ensured by the fact that gear wheels of odd gears - the first, third and fifth - are installed in the main gearbox on the primary shaft of a hollow section. On the other input shaft of solid section there are gears of even gears: second, fourth, reverse gear and the sixth is located - direct gear. In the additional gearbox, one of the gears is distributed to the main row of gear ratios, except for the sixth - direct gear. The other gear is also distributed to the main row of gear ratios, except for the sixth-direct, while the driving gear of the fifth gear is simultaneously assigned to the driving gear of the ninth gear, the driving gear of the third gear is the driving gear of the seventh gear, the driving gear of the fourth gear is the driving gear of the eighth gear, and the leading gear the gears of the first, second and other reverse gears are simultaneously assigned as the driving gears of the intermediate gears.

The gear ratios of the intermediate gears obtained in the position of the upper stage engaged in the additional gearbox are located between the gear ratios of the individual gears resulting from the inclusion of its lower range.

Such an implementation of a multistage double-clutch transmission, which has a wide range of gear ratios and an increased number of gears due to intermediate gears, makes it possible to expand its functionality, reduce the relative work under load of adjacent gears and their engagement clutches, and reduce internal power losses in the entire range of gear ratios. providing better use of engine power, which increases the traction and acceleration performance of the vehicle, and the presence of higher accelerating gears can significantly increase its maximum speed.

The solution to the technical problem is also provided by the fact that in the main gearbox on the section of the output shaft located between the support plate and the one-way clutch, there is a fixed drive gear of the power distribution unit, meshed with a pair gear with a hub mounted by means of rolling bearings on a tubular bracket surrounding the intermediate shaft, fixed on the support plate, and connected to the drive discs of the normally open clutch, alternating with the driven discs meshed with its casing, which has an inner cylindrical hollow support installed on rolling bearings inside the tubular bracket, and an outer ring gear meshed with the driven gear, fixed on the output shaft of the power distribution unit.

The expansion of the functionality of the dual-clutch gearbox is facilitated by its completion with a power distribution unit for periodically engaging the wheels of the front axle, which increases the traction performance of the vehicle when operating in different road conditions.

The technical result is an increase in the traction and speed indicators of the vehicle.

Figure 1 shows a kinematic diagram of a multi-stage dual-clutch transmission.

Figure 2 shows the same as figure 1, but in a different configuration.

The multistage gearbox 10 with double clutch 11, shown in figure 1, contains a housing 12 of the main gearbox 13, in which a plurality of paired gears 14-15, 16-17, 18-19, 20-21, 22-23, 24-25 -26 constant mesh, driven by clutches 27, 28 and 29 to obtain different gear ratios. One of the paired gears 14, 16, 18, 20, 22 and 24 are mounted on coaxially located input shafts of round solid 30 and hollow 31 sections. Input shafts 30 and 31 are connected via two normally open clutches 32 and 33 of clutch 11 to input shaft 34. In double clutch 11, clutches 32 and 33 can be arranged in series or parallel to each other and have dry or wet friction elements. The input shaft 34 is connected to a motor shaft (not shown). The other of the paired gears 15, 17, 19, 21, 23, and 25 are located on an intermediate shaft 35 passing through a support plate 36 mounted in the housing 12. The intermediate shaft 35 is kinematically connected to the output shaft 37 of the gearbox 10.

In this multistage gearbox 10 with double clutch 11, gears 14, 16, 18, 20, 22 and 24 on the input shafts 30 and 31 of the main gearbox 13 are fixed, located one after the other and meshed with gears 15, 17, 19, 21 , 23 and 25, controlled by double-sided clutches 27, 28 and 29. Clutches 27, 28 and 29 are mounted in series at intervals 38, 39 and 40 between each pair of these gears 17-19, 15-23, 21-25, mounted freely on the intermediate shaft 35. Gear 26 has constant engagement with gears 24 and 25 and is freely installed on axle 41. Intermediate shaft 35 is fixedly connected by splined connection with block 42 of gears 43 and 44 of an additional two-stage gearbox 45. Gears 43 and 44 of block 42 have constant mesh with gears 46 and 47, controlled by a double-sided clutch 48 and mounted freely on the output shaft 37 of the gearbox 10. Free installation of gears 15, 17, 19, 21, 23 and 25 implies the possibility of their free angular about movement relative to the intermediate shaft 35. The free installation of the gear 26 implies the possibility of free rotation about the axis 41, and the free installation of the gears 46 and 47 means the possibility of free rotation relative to the shaft 37. The output shaft 37 has a section 49 passing through the support plate 36 attached to the housing 12, with an outlet to the inner cavity of the main gearbox 13. In section 49, a one-way clutch 50 is installed, located coaxially to the gear rim with the friction cone 51. The gear rim with the friction cone 51 is fixed on the input shaft 30 of solid section. On the other hand, the output shaft 37 is installed through the bearing 52 in the cover 53 of the additional gearbox 45, connected to the housing 12 of the gearbox 13, with an outlet to other transmission units (not shown).

In the main gearbox 13, gears 14, 16 and 18 of odd gears 1, 3 and 5 are installed on the input shaft 31 of hollow section. Gears 20, 22 and 24 of even gears 2, 4, reverse gears R and 5 are installed on the other input shaft 30 of solid section. the sixth direct gear is located 6. In the additional gearbox 45 one of the gears with gears 44 and 47 is distributed to the main row of gear ratios 1, 2, 3, 4, 5 and R, except for the sixth direct gear 6. Another gear with gears 43 and 46 is also distributed to the main row of gear ratios, except for the sixth direct gear 6, while the drive gear 18 of the fifth gear 5 is at the same time the driving gear of the ninth gear 9, the driving gear 16 of the third gear 3 is the driving gear of the seventh gear 7, the driving gear 22 of the fourth gear 4 - the driving gear of the eighth gear 8, and the driving gears 14, 20 and 24 of the first 1, second 2 and the reverse gear R are simultaneously the driving gears of the intermediate gears P2, P1 and the other before Reverse gear R 'respectively. Thus, the kinematic diagram of the multistage gearbox 10 with double clutch 11 allows nine main forward gears (1, 2, 3, 4, 5) with the 6th direct gear, with three higher accelerating gears (7, 8 and 9) and reverse gear R, as well as additional intermediate gears (P1, P2 and R '). The gear ratios of the intermediate gears P1 and P2 obtained in the position of the upper stage with gears 43 and 46 in the additional gearbox 45 are located between the gear ratios of the fourth-fifth and second-third gears, respectively.

In a multistage gearbox 10 'in another configuration, shown in figure 2, in the main gearbox 13 in the section 49 of the output shaft 37 located between the support plate 36 and the one-way clutch 50, a fixed driving gear 54 of the power distribution unit 55 is installed, having a gear ratio equal to unit. Gear 54 meshes with a pair of gear 56 having a hub 57. The hub 57 is mounted by means of rolling bearings 58 on a tubular bracket 59 surrounding the intermediate shaft 35. The bracket 59 is fixed on the support plate 36. The hub 57 of the gear 56 is connected to the drive discs 60 of the normally open multi-plate clutch 61, alternating with driven discs 62. The discs 62 are engaged with the casing 63 of the clutch 61, which has an inner cylindrical hollow support 64. The support 64 of the casing 63 is mounted on rolling bearings 65 inside the tubular bracket 59. The casing 63 of the clutch 61 also has an outer ring gear 66, meshed with a driven gear 67 fixed on the output shaft 68 of the power distribution unit 55 with an exit towards the wheels of the front axle (not shown).

The gearbox shown in figure 1 operates as follows.

To obtain a certain gear and movement of the vehicle in the gearbox 10, it is necessary to turn on three control elements in it: one clutch in the main gearbox 13 and one clutch in the additional gearbox 45, and in the double clutch 11 turn on one of the friction clutches 32 or 33 to connect one from the input shafts 30 or 31, corresponding to this selected gear, with the input shaft 34, which is carried out by automatic control (electro-hydraulic, electromagnetic or other type of control).

When the first gear is engaged, the gear 47 in the additional gearbox 45 is connected by the clutch 48 to the output shaft 37, and the gear 15 in the main gearbox 13 is connected by the clutch 28 to the intermediate shaft 35 and the friction clutch 33 of the double clutch 11 is engaged 11. The torque in the first gear is transmitted from the input shaft 34 through the double clutch 11 to the hollow-section input shaft 31 and its gear 14. From the gear 14, the torque is transmitted to the gear 15, the intermediate shaft 35, the block 42 and its gear 44. The gear 44 transmits the torque to the paired gear 47 and the output shaft 37, further the wheel drive shaft of the rear axle of the vehicle (not shown).

To engage the second gear, the gear 21 is connected by the clutch 29 to the intermediate shaft 35. The clutch 48 is turned on, connecting the gear 47 with the output shaft 37. Then the friction clutch 32 of the double clutch 11 is turned on. In the second gear, the torque is transmitted by the double clutch 11 to the input shaft 30 of the round solid section and gear 20. From gear 20, torque is transmitted to gear 21, intermediate shaft 35, block 42 and its gear 44. Gear 44 of additional reducer 45 transmits torque to paired gear 47 and output shaft 37.

To engage the third gear, the clutch 27 is turned on, and the gear 17 is connected to the intermediate shaft 35. The clutch 48 is turned on, connecting the gear 47 with the output shaft 37. The friction clutch 33 of the double clutch 11 is turned on. The torque in the third gear is transmitted through the double clutch 11 to the input shaft 31 of circular hollow section and gear 16. From gear 16, torque is transmitted to gear 17, then the same as when the first gear is engaged.

To engage the fourth gear, the gear 23 is connected to the intermediate shaft 35 when the clutch 28 is turned on. The clutch 48 is turned on, connecting the gear 47 with the output shaft 37. The friction clutch 32 of the double clutch 11 is activated. The torque in the fourth gear is transmitted through the double clutch 11 to the input shaft 30 circular solid section and gear 22. From gear 22, the torque is transmitted to gear 23, then the same as when the first gear is engaged.

To engage the fifth gear, the gear 19 is connected to the intermediate shaft 35 when the clutch 27 is turned on. The clutch 48 is turned on, connecting the gear 47 with the output shaft 37. Then the friction clutch 33 of the double clutch 11 is turned on. The torque from the shaft 34 is transmitted through the double clutch 11 to the input shaft 31 circular hollow section and gear 18. From gear 18, the torque is transmitted to gear 19 and further, as when engaging the first gear.

To engage the sixth direct gear, the clutch 50 is switched on, connecting to the ring gear with a friction cone 51, thereby blocking the input shaft 30 with the output shaft 37. Then the friction clutch 32 of the double clutch 11 is turned on. In the sixth direct gear, the torque from the input shaft 34 is transmitted through the double clutch 11 by the input shaft 30 of a solid circular section directly to the output shaft 37 of the gearbox 10.

To engage the seventh gear, the gear 17 is connected to the intermediate shaft 35 when the clutch 27 is turned on. The clutch 48 is turned on, connecting the gear 46 to the output shaft 37. The friction clutch 33 of the double clutch 11 is activated. The torque is transmitted from the input shaft 34 through the double clutch 11 to the input shaft 31 circular hollow section and gear 16. Gear 16 transmits torque to gear 17, intermediate shaft 35, block 42 and its gear 43. Gear 43 transmits torque to paired gear 46 and output shaft 37.

To engage the eighth gear, the gear 23 is connected by the clutch 28 to the intermediate shaft 35. The clutch 48 is turned on, connecting the gear 46 to the output shaft 37. The friction clutch 32 of the double clutch 11. The torque from the input shaft 34 is transmitted through the double clutch 11 to the input shaft 30 and the gear 22. Gear 22 transmits torque to gear 23 and further, as when engaging the seventh gear.

To engage the ninth gear, the gear 19 is connected to the intermediate shaft 35, when the clutch 27 is turned on. The clutch 48 is turned on, connecting the gear 46 with the output shaft 37. Then the friction clutch 33 of the double clutch 11 is turned on. The torque from the input shaft 34 is transmitted by the double clutch 11 to the input shaft 31 and gear 18. Gear 18 transmits torque to gear 19 and further, as if the seventh gear is engaged.

In the multistage gearbox 10 shown in figure 1, the nine main gears of the forward gear are shifted without interrupting the power flow when changing from odd gears to even gears, and vice versa, when shifting up or down due to the simultaneous disengagement of one of the friction clutches 11 and engaging another friction clutch 11 corresponding to the engaged gear.

To move the vehicle backward, reverse gear R is engaged. When reverse gear R is engaged, gear 47 is connected to the output shaft 37 when clutch 48 is engaged, and gear 25 is connected to the intermediate shaft 35 by clutch 29. For movement, the friction clutch 32 of the double clutch 11 The torque from the input shaft 34 is transmitted by the double clutch 11 to the input shaft 30 and the gear 24. The gear 24 transmits the torque through the intermediate gear 26 to the gear 25, the intermediate shaft 35, the block 42 with the gear 44. The gear 44 transmits the torque to the gear 47 and the output shaft 37 gearboxes. R 'gear is also used to drive the vehicle in reverse. To engage this transmission, the gear 46 is connected by the clutch 48 to the output shaft 37, and the gear 25 is connected by the clutch 29 to the intermediate shaft 35. For the movement, the friction clutch 32 of the double clutch 11. The torque from the input shaft 34 is transmitted by the double clutch 11 to the input shaft 30 and its gear 24. Gear 24 transmits torque through the intermediate gear 26 to gear 25, intermediate shaft 35, block 42 with its gear 43. Gear 43 of reducer 45 transmits torque to gear 46 and output shaft 37.

To turn on additional intermediate gears, for example, P1 from the seventh gear without interrupting the power flow, the gear 21 is connected to the intermediate shaft 35 when the clutch 29 is turned on. The friction clutch 33 of the double clutch 11 is turned off and the friction clutch 32 is simultaneously turned on. Torque is transmitted from the input shaft 34. through double clutch 11 to input shaft 30 and gear 20. Gear 20 transmits torque to gear 21, intermediate shaft 35, block 42 and its gear 43. Gear 43 transmits torque to gear 46 and output shaft 37. The inclusion of intermediate gear P2 after P1 occurs without breaking the power flow. To engage the P2 gear, the gear 15 is connected by the clutch 28 to the intermediate shaft 35. The clutch 33 of the double clutch 11 is turned on and at the same time its friction clutch 32 is turned off. The torque from the input shaft 34 is transmitted through the double clutch 11 to the input shaft 31 and its gear 14. The gear 14 transmits torque to gear 15, countershaft 35, block 42 and its gear 43. From gear 43, torque is transmitted to gear 46 and output shaft 37. The presence of intermediate gears P1 and P2 increases the density of the row of gear ratios throughout the entire range of gearbox 10 with dual clutch 11 , which allows the inclusion of these gears without interrupting the power flow and without switching on another range in the additional gearbox 45.

The multistage gearbox 10 'with double clutch 11, shown in figure 2, in its design and principle of operation generally corresponds to the multistage gearbox 10 shown in figure 1, but is equipped with a power distribution unit 55 installed in the housing 12 of the main gearbox 13 for intermittent front axle wheels (not shown).

Periodic engagement of the front axle wheels occurs automatically based on the analysis of vehicle movement parameters. For this, the driving discs 60 of the clutch 61 are closed with its driven discs 62 of the power distribution unit 55. As a result, the hub 57 of the gear 56 is locked with the housing 63 and its gear rim 66. When the gear is engaged in the main gearbox 13 from a number of gear ratios (1, 2 , 3, 4, 5 and R) and when the clutch 48 is on, the gear 47 in the additional gear 45 is connected to the output shaft 37. Part of the torque from the input shaft 34, when one of the friction clutches 32 or 33 of the double clutch 11 is closed, depending on the included transmission, is transmitted by one of the primary shafts 30 or 31 to the intermediate shaft 35, the block 42 and its gear 44 of the additional reducer 45. The gear 44 transfers part of the torque to the gear 47, the output shaft 37 and to the drive of the wheels of the rear axle of the vehicle. At the same time, part of the torque from the shaft 37 is transmitted by the drive gear 54 of the power distribution unit 55 to the gear 56 and the ring gear 66 of the housing 63 of the clutch 61. From the ring gear 66, part of the torque is transmitted to the driven gear 67 and the output shaft 68 of the power distribution unit 55, then to the wheel drive shaft front axle (not shown). When the clutch 61 is turned off, the driving discs 60 and the driven discs 62 are opened, the hub 57 of the gear 56 is disconnected from the housing 63 and its ring gear 66. The wheels of the front axle are turned off, and the torque is transmitted only to the rear axle. In the 10 'gearbox, it is possible to periodically turn on the wheels of the front axle at another stage of the additional gearbox 45, distributed for gear ratios 6, 7, 8, 9, P1, P2 and R' gears in the main gearbox 13. Turning on and off the power distribution unit 55 occurs similar to the case considered earlier.

Thus, in the created multi-stage transmission with a double clutch, due to an increase in the range of gear ratios, an increase in the number of gears, a decrease in the time for switching them, carried out without interrupting the power flow, which reduces the relative work under load of adjacent gears and their engagement clutches, in the presence of higher accelerating gears, allowing to significantly increase the maximum speed, and the power distribution unit for engaging the wheels of the front axle, the functional capabilities of the gearbox are expanded, the use of the engine power of the vehicle is improved, and its traction and speed indicators are increased when operating under different road conditions.

Claims (4)

1. A multistage double-clutch transmission containing a main gearbox housing with a plurality of paired constant mesh gears, controlled by couplings to obtain different gear ratios, one of the paired gears is installed on coaxially located input shafts of solid round and hollow sections, connected through two normally open frictional clutches with the input shaft, the other of the paired gears are located on the intermediate shaft passing through the base plate of the housing and connected kinematically with the output shaft of the gearbox, characterized in that the gears on the input shafts of the main gearbox are fixed motionless, located one after the other and meshed with the gears controlled by double-sided clutches mounted in series in the intervals between each pair of these gears, mounted freely on the intermediate shaft, fixedly connected to the gear block of the additional two-stage gearbox, meshed with two controlled and a double-sided clutch with gears mounted freely on the output shaft of the gearbox, having a section passing through the base plate of the housing, and a one-way control clutch is installed on it, located coaxially to a gear rim with a friction cone fixed on the input shaft of solid section. 2. A multistage gearbox according to claim 1, characterized in that in the main gearbox on the primary shaft of a hollow section, gears of odd gears of the first, third and fifth gears are installed, on the other input shaft of a solid section of gears of even gears of the second, fourth, reverse gear and is located sixth - direct gear, in the additional gearbox one of the gears is distributed to the main row of gear ratios, except for the sixth - direct gear, the other gear is also distributed to the main row of gear ratios, except for the sixth - direct, while the drive gear of the fifth gear is simultaneously assigned to the driving gear of the ninth gears, the driving gear of the third gear - the driving gear of the seventh gear, the driving gear of the fourth gear - the driving gear of the eighth gear, and the driving gears of the first, second gears and the other reverse gears are simultaneously assigned as the driving gears of the intermediate gears. 3. Multistage gearbox according to claim 2, characterized in that the gear ratios of the intermediate gears obtained in the position of the included higher stage in the additional gearbox are located between the gear ratios of the individual gears obtained as a result of the inclusion of its lower range. 4. A multistage gearbox according to claim 3, characterized in that in the main gearbox housing at the output shaft section located between the support plate and the one-way clutch, there is a stationary drive gear of the power distribution unit meshed with a paired gear with a hub mounted by means of rolling bearings on the tubular bracket surrounding the intermediate shaft, fixed on the support plate and connected to the drive discs of the normally open clutch, alternating with driven discs meshed with its housing, which has an inner cylindrical hollow support mounted on rolling bearings inside the tubular bracket and an outer gear ring, meshed with a driven gear, fixed on the output shaft of the power distribution unit.

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