KR20160080996A - Transmission of vehicle - Google Patents

Abstract

The present invention relates to a transmission for transferring engine power of a vehicle. The transmission comprises: an input shaft which is rotated by an engine; a first connection shaft which is rotate by receiving power from the input shaft; a second connection shaft which mutually transfers power to the first connection shaft; and a driven shaft which is rotated by the power of the input shaft via the first connection shaft. A first wet multi-disk clutch, which is operated by hydraulic pressure to connect or cut off power, is formed in the input shaft. A synchromesh clutch, which connects or cuts off power by the synchromesh between gears, is formed in the first connection shaft. The first wet multi-disk clutch and the synchromesh clutch are functionally connected to change a power transfer path, thereby performing speed changing operation.

Description

[0001] Transmission of vehicle [0002]

The present invention relates to a vehicle transmission, and more particularly to a power shift transmission suitable for a working vehicle such as a tractor.

A power shift transmission that can be automatically shifted in place of a manual transmission has been developed. Most power shift gearboxes use the same wet multi-plate clutch as conventional cars to change speed and travel direction.

A wet multi-plate clutch is a must for an automatic transmission, but it has less power efficiency than a mechanical transmission. In addition, the wet multi-plate clutch requires hydraulic pressure for the operation of the hydraulic actuator, and the hydraulic pump must always be operated to provide a constant pressure and flow rate at all times.

When the hydraulic pump is driven, the power for driving the transmission and the working machine is lost because the power of the engine is consumed in proportion to the pressure and the flow rate to be formed. Further, since a separate pump and a cooler for cooling are required, the wet multi-plate clutch occupies a lot of installation space as compared with the mechanical transmission.

To overcome this limitation, attempts have been made to construct a transmission using a wet multi-plate clutch and a mechanical synchronous clutch.

However, according to the related art, the power transmission path is complicated by mixing the two types of clutches, and it is difficult to downsize. Also, the power efficiency was reduced.

Patent Publication No. 10-2005-0066090

SUMMARY OF THE INVENTION It is an object of the present invention to provide a transmission excellent in power transmission efficiency by simplifying a power transmission path while using a hydraulic multi-plate hydraulic clutch and a mechanical synchronous clutch in combination.

According to an aspect of the present invention, there is provided a transmission for transmitting engine power of a vehicle, comprising: an input shaft that is rotated by an engine; a first connection shaft that is rotated by transmitting power of the input shaft; A second connecting shaft capable of transmitting power from the first connecting shaft to the first connecting shaft, and a driven shaft rotating by the power of the input shaft via the first connecting shaft, wherein the input shaft is actuated by hydraulic pressure to connect or disconnect the power A first wet multi-plate clutch is provided on the first connection shaft, and a synchronous clutch for connecting or disconnecting power by synchronizing gears is provided on the first connection shaft, and the first wet multi-plate clutch and the synchronous clutch are functionally connected There is provided a transmission that changes the power transmission path to perform shifting.

According to one embodiment, the input shaft, the first connecting shaft, and the second connecting shaft extend in parallel relation to each other.

According to an embodiment of the present invention, a second wet multi-plate clutch is provided on the driven shaft to connect or disconnect power by operating with hydraulic pressure.

According to one embodiment, a second wet-type multi-plate clutch is provided on the driven shaft to connect or disconnect power by operating with hydraulic pressure,

Wherein the first multi-plate clutch is a two-stage clutch in which the first multi-plate clutch portion and the second multi-plate clutch portion are alternately engaged with the input shaft, and the second multi-plate clutch includes a third multi-plate clutch portion and a fourth multi- Wherein the four-speed shift is achieved by selectively changing the power transmitting path by engaging with the shaft selectively corresponding to the first wet multi-plate clutch and the second wet multi-plate clutch, the two-stage clutch engaged with the driven shaft.

According to one embodiment, the synchronous clutch is a two-stage clutch in which the first synchronous clutch portion and the second synchronous clutch portion alternately mesh with the first connection shaft, and the synchronous clutch, the first wet multi- And the second wet multi-plate clutch selectively engages a corresponding shaft to selectively change the power transmission path, thereby achieving an eight-speed shift.

According to one embodiment, the wet multi-plate clutch is operatively connected to the synchronous clutch via the second connecting shaft, the power of the input shaft is transmitted to the first connecting shaft via the second connecting shaft, 1 connection shaft to the driven shaft.

According to one embodiment, the wet multi-plate clutch is directly connected to the synchronous clutch, and the power of the input shaft is transmitted to the second connection shaft via the first connection shaft, .

According to one embodiment, the first connection shaft and the driven shaft are formed coaxially.

According to one embodiment, on the driven shaft, a forward-reverse clutch capable of changing the rotating direction of the driven shaft is formed.

According to one embodiment, the synchronous clutch and the forward / reverse clutch are constituted by a synchromesh mechanism.

According to one embodiment, the transmission further includes a sub-transmission portion for selectively transmitting the rotational driving force of the driven shaft to the output shaft connected to the wheels of the vehicle.

According to one embodiment, the auxiliary speed change portion includes a third connecting shaft extending in parallel with the driven shaft, a fourth connecting shaft formed coaxially with the driven shaft and the output shaft, and a second connecting shaft extending in parallel with the output shaft And a fifth connecting shaft extending in parallel, and performs three-stage shifting such that the power is transmitted via the third connecting shaft, the fourth connecting shaft, or the fifth connecting shaft by three paths.

According to one embodiment, in the first-stage shift, power is transmitted from the third connecting shaft to the fifth connecting shaft, and then from the fifth connecting shaft to the output shaft.

According to one embodiment, in the second-stage shift, power is directly transmitted from the third connecting shaft to the output shaft.

According to one embodiment, in the third-stage shifting, power is transmitted from the driven shaft to the output shaft via the fourth connecting shaft.

1 is a diagram of a transmission according to a first embodiment of the present invention.
FIG. 2 is a longitudinal axial view of the input shaft, the first connecting shaft, and the second connecting shaft of the transmission of FIG. 1;
Fig. 3A is a diagram for explaining a power transmission path in the vicinity of the first and third stages of the transmission of Fig. 1; Fig.
3B is a diagram for explaining a power transmission path in the vicinity of the second and fourth stages of the transmission of FIG.
Fig. 4A is a diagram for explaining a power transmission path in the vicinity of the fifth and seventh stages of the transmission of Fig. 1; Fig.
Fig. 4B is a diagram for explaining a power transmission path in the vicinity of the sixth and eighth stages of the transmission of Fig. 1; Fig.
5A to 5C are diagrams illustrating a power transmission path in the case of a negative speed change of the transmission of FIG.
Fig. 6 is a diagram for explaining a power transmission path when the transmission of Fig. 1 is reversed. Fig.
7 is a diagram of a transmission according to a second embodiment of the present invention.
FIG. 8 is a view of the input shaft, the first connecting shaft, and the second connecting shaft of the transmission of FIG. 7 in the axial direction.
Fig. 9A is a diagram for explaining a power transmission path in the vicinity of the first and second stages of the transmission of Fig. 7; Fig.
Fig. 9B is a diagram for explaining the power transmission path in the vicinity of the third and fourth stages of the transmission of Fig. 7; Fig.
Fig. 10A is a diagram for explaining a power transmission path in the vicinity of the fifth and sixth stages of the transmission of Fig. 7; Fig.
Fig. 10B is a diagram for explaining the power transmission path in the vicinity of the seventh and eighth stages of the transmission of Fig. 7; Fig.
Fig. 11 is a diagram for explaining the power transmission path when the transmission of Fig. 7 is reversed. Fig.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. Although the present invention has been described with reference to the embodiments shown in the drawings, it is to be understood that the technical idea of the present invention and its essential structure and operation are not limited thereby.

Example 1

1 is a diagram of a transmission according to a first embodiment of the present invention.

1, the transmission includes an input shaft 10 rotated by an engine (not shown), a first connecting shaft 20 through which the power of the input shaft 10 is transmitted and rotated, A second connecting shaft 30 capable of transmitting power to the connecting shaft 20 and a driven shaft 40 rotated by the power of the input shaft 10 via the first connecting shaft 20. [

The input shaft 10, the first connecting shaft 20 and the second connecting shaft 30 extend parallel to each other in parallel relation to each other and transmit the power of the engine to the driven shaft 40.

A third connecting shaft 50 extending parallel to the driven shaft 40 in parallel relation to the driven shaft 40 is formed on the downstream side end of the driven shaft 40.

Here, "parallel relationship" means that the two axes are arranged side by side so that the gears connected to the two axes can be directly engaged with each other.

A fourth connecting shaft 60 is formed on the downstream side end of the driven shaft 40 such that the driven shaft 40 and its rotational center shaft coincide with each other (coaxially), and the downstream end of the fourth connecting shaft 60 And an output shaft 80 connected to a wheel 88 of the vehicle is arranged coaxially.

The term " upstream " as used herein refers to the direction in which the engine is located in the drawing, and the term "downstream " means the direction in which the final end of the transmission of power is located. Sometimes, the term " upstream "means the side to which power is input by one member, and the term" downstream " means that the power input from the member is transmitted.

2 is an axial view of the input shaft 10, the first connecting shaft 20 and the second connecting shaft 30.

2, the input shaft 10, the first connecting shaft 20, and the second connecting shaft 30 are arranged such that the line segments connecting the longitudinal center axes thereof form a triangle.

According to this embodiment, the first connecting shaft 20 is disposed below the input shaft 10 and the second connecting shaft 30 is eccentrically disposed on the side of the input shaft 10 (first connecting shaft 20) .

Referring again to FIG. 1, a first wet-type multi-plate clutch is provided on the input shaft 10 to operate or block power by hydraulic pressure, and a first wet multi-plate clutch is operatively connected to the first connection shaft 20 A synchronous clutch is formed which connects or disconnects the power by synchronizing the gears.

As will be described later, the first wet multi-plate clutch and the synchronizing clutch mutually change the power transmission path to perform the shifting.

According to the present embodiment, the first connecting shaft 20 is disposed below the input shaft 10, and the first wet type multi-plate clutch and the synchronizing clutch are directly connected, so that the power transmission path can be simplified.

In addition, the size of the entire transmission can be reduced by pulling the second connecting shaft 30 laterally of the other two shafts.

 On the input shaft 10, there are connected two first-stage wet multi-plate clutches 110 which are operated by hydraulic pressure to connect or disconnect the power.

The wet multi-disc clutch has a structure in which a plurality of drive discs and a driven disc are repeatedly arranged in turn in the clutch housing. More specifically, the clutch pressure spring simultaneously presses the pressure plate, the drive disk, and the driven disk so that the clutch hub is integrated with the clutch housing, so that the driving force of the shaft is transmitted to the clutch hub by the clutch housing rotating with the shaft, The formed drive gear can be rotated.

Conversely, by disengaging the clutch hub from the clutch housing, power transmission between the shaft and the clutch hub can be interrupted.

The structure of the wet type multi-plate clutch operated by the hydraulic pressure is already known, and a detailed description thereof will be omitted here.

The first wet multi-plate clutch 110 according to the present embodiment is a two-stage clutch in which the first multi-plate clutch portion 111 and the second multi-plate clutch portion 112 are opposed to each other.

The first clutch hub 113 is freely rotatably connected to the input shaft 10 in the clutch housing of the first multi-plate clutch portion 111 and the drive gear 114 is connected to the upstream end of the first clutch hub 113, Respectively.

The second clutch hub 115 is freely rotatably connected to the input shaft 10 in the clutch housing of the second multi-plate clutch portion 112 and the drive gear 116 is connected to the downstream end of the second clutch hub 115, Respectively.

Here, "freely rotatable" does not mean that one structure can rotate without any friction with respect to another structure, but bearing frictional force can be applied through a member such as a bearing, but rotational force is directly transmitted It is to be understood that the present invention encompasses cases where it can be seen that the present invention is not limited to the above.

On the first connecting shaft 20, a synchronous clutch 130 for connecting or disconnecting power by synchronizing the gears is formed.

According to the present embodiment, the first wet multi-plate clutch 110 and the synchronous clutch 130 are functionally connected to each other.

Here, "functionally connected" means not only that the first configuration and the second configuration are directly connected to each other, but also the power output from the first configuration is connected to the second configuration via the third configuration As shown in FIG.

The synchronous clutch 130 according to the present embodiment is formed by a synchromesh transmission mechanism.

The synchromesh transmission mechanism is a transmission mechanism that forms a clutch gear in front of the transmission, and a synchronizer ring that moves the clutch gear and the sleeve to move the sleeve to perform shifting. When shifting, the gear teeth of the sleeve and the gear teeth of the synchronizer ring engage as the sleeve moves. In this state, the sleeve is moved toward the clutch gear. At this time, the portion where the clutch gear and the synchronizer ring abut each other is smooth, and as the friction is increased, the number of revolutions of the two gears becomes equal.

The construction and operation principle of the synchromesh transmission mechanism are well known, and therefore, a detailed description thereof will be omitted here.

According to the present embodiment, the synchronizing clutch 130 includes a first synchronous clutch portion consisting of a driving gear 132, a first synchronous shaft 131 and a clutch gear 133, And a second synchronous clutch portion composed of a synchronous shaft 134 and a clutch gear 135. [

The synchronizing clutch 130 includes a hub 137 rotating integrally with the first connecting shaft 20 and a second connecting shaft 130 formed on the upstream and downstream sides of the hub 137 and capable of freely rotating with respect to the first connecting shaft 20 1 synchro shaft 131 and a second synchro shaft 134.

A drive gear 132 is formed at the upstream end of the first synchro shaft 131 and a clutch gear 133 is formed at the downstream end of the first synchro shaft 131. A clutch gear 135 is formed at the upstream end of the second synchro shaft 134 and a drive gear 136 is formed at the downstream end of the second synchro shaft 134.

The driving gear 132 is meshed with the driving gear 114 of the first multi-plate clutch part 111 and the driving gear 136 is meshed with the driving gear 116 of the second multi-

A sleeve 138 is formed between the first synchro shaft 131 and the second synchro shaft 134 so as to surround the hub 137.

The sleeve 138 moves left and right during shifting to selectively connect the clutch gear 133 and the hub 137 or the clutch gear 135 and the hub 137 to each other.

When the sleeve 138 is moved to the left to functionally connect the clutch gear 133 and the hub 137, the first connecting shaft 20 and the first synchronizing shaft 131 rotate together. At this time, the second synchro shaft 134 is kept free to rotate with respect to the first connecting shaft 20, so that no power transmission occurs between the second synchro shaft 134 and the first connecting shaft 20.

Conversely, when the sleeve 138 is moved to the right and the clutch gear 135 and the hub 137 are functionally connected, the first connecting shaft 20 and the second synchronizing shaft 134 rotate together. At this time, the first synchro shaft 131 is kept free to rotate about the first connecting shaft 20, so that no power transmission occurs between the first synchro shaft 131 and the first connecting shaft 20.

A driving gear 31 and a driving gear 32 are formed on the second connecting shaft 30. [ The driving gear 31 and the driving gear 32 are engaged with the driving gear 132 and the driving gear 136 of the synchronizing clutch 130, respectively.

The driven shaft 40 is connected to the forward-reverse clutch 140. The forward-reverse clutch (140) is constituted by a synchromesh transmission mechanism.

The forward and reverse clutch 140 includes a hub 147 that rotates integrally with the driven shaft 40 and a forward synchro shaft 141 and a reverse synchro shaft 144 formed on the upstream and downstream sides of the hub 147 do.

The forward synchro shaft 141 is coupled to the first connection shaft 20 and is configured to rotate integrally with the first connection shaft 20 and is freely rotatable with respect to the driven shaft 40. The reverse synchro shaft 144 is disposed so as to surround the driven shaft 40 and is freely rotatable with respect to the driven shaft 40.

A drive gear 142 is formed at the upstream end of the forward synchro shaft 141 and a clutch gear 143 is formed at the downstream end of the forward synchro shaft 141. A clutch gear 145 is formed at the upstream end of the reverse synchronous shaft 144 and a drive gear 146 is formed at the downstream end of the reverse synchro shaft 144.

A sleeve 148 is formed between the forward synchro shaft 141 and the reverse synchro shaft 144 so as to surround the hub 147.

The sleeve 148 moves left and right during shifting so that the clutch gear 143 and the hub 147 or the clutch gear 145 and the hub 147 are functionally connected to each other.

When the sleeve 148 is moved to the left to functionally connect the clutch gear 143 and the hub 147, the driven shaft 40 and the forward synchro shaft 141 rotate together. At this time, the reverse synchro shaft 144 is kept free to rotate relative to the driven shaft 40, so that no power transmission occurs between the reverse synchro shaft 144 and the driven shaft 40.

Conversely, when the sleeve 148 is moved to the right and the clutch gear 145 and the hub 147 are functionally connected, the driven shaft 40 and the reverse synchro shaft 144 rotate together. At this time, the forward synchro shaft 141 is kept free to rotate with respect to the driven shaft 40, so that no power transmission occurs between the forward synchro shaft 141 and the driven shaft 40.

On the other hand, on the input shaft 10, a rotary shaft 151 is formed on the downstream side of the first wet multi-plate clutch 110 so as to freely rotate with respect to the input shaft 10.

Driving gears 152 and 153 are formed at both ends of the rotating shaft 151 and the driving gear 153 is meshed with the driving gear 142 formed on the shaft 141 by the forward synchromesh.

An idle gear 33 is formed on the second connecting shaft 30 so as to be freely rotatable with respect to the second connecting shaft 30 and an idle gear 34 is formed on the idle shaft 33.

The driving gear 152 is meshed with the idle gear 34 and the idle gear 34 is meshed with the driving gear 146 of the backward synchronizing shaft 144.

The rotational force of the first connecting shaft 20 is transmitted to the forward / backward clutch 150 through the idle gear 34 so that the rotational direction of the driven shaft 40 is changed.

A second wet multi-plate clutch 120 of two stages is connected to the driven shaft 40, which is downstream of the forward-reverse clutch 150.

The third multi-plate clutch portion 121 and the second multi-plate clutch portion 122 are opposed to each other in the second wet multi-plate clutch 120.

The third clutch hub 123 is freely rotatably connected to the driven shaft 40 at the clutch housing of the third multi-plate clutch portion 121 and the drive gear 124 Is formed.

A fourth clutch hub 125 is freely rotatably connected to the driven shaft 40 at the clutch housing of the fourth multi-plate clutch portion 122 and a drive gear 126 Is formed.

Four driving gears 51, 52, 53 and 54 are formed on the third connecting shaft 50 formed in a side-by-side relationship with the driven shaft 40. The driving gear 51 is meshed with the driving gear 124 of the third multi-plate clutch portion 121 and the driving gear 52 is meshed with the driving gear 126 of the fourth multi-plate clutch portion 122.

At the downstream end of the driven shaft 40, a fourth connecting shaft 60 having a coaxial axis coinciding with the driven shaft 40 (coaxial) is formed.

A cylindrical rotary shaft 61 is formed at the upstream end of the fourth connecting shaft 60 so as to surround the driven shaft 40 and freely rotatable with respect to the driven shaft 40. (62) is formed. The driving gear 62 is engaged with the driving gear 53 of the third connecting shaft 50.

An output shaft (80) is formed coaxially with the fourth connecting shaft (60) at the downstream end of the fourth connecting shaft (60). The wheels 88 of the vehicle are connected to the output shaft 80 and the rotational force of the output shaft 80 is dispersed by the wheels 88 to rotate the wheels 88.

The output shaft 80 is provided with a hub 81 rotating integrally with the output shaft 80 and two synchronous shafts 63 and 83 formed on the upstream and downstream sides of the hub 81 and freely rotatable with respect to the output shaft 20. [ Lt; / RTI >

The synchro shaft 63 is connected to the downstream end of the fourth connecting shaft 60 so as to rotate integrally with the fourth connecting shaft 60. A clutch gear 64 is formed at the downstream side end of the synchro-shaft 63.

A clutch gear 86, a drive gear 84, and a drive gear 85 are formed on the synchro shaft 83 from the upstream side. The driving gear 84 is engaged with the driving gear 54 formed on the most downstream side of the fourth connecting shaft 60.

Between the synchro shaft 63 and the synchro shaft 83, a sleeve 87 is formed to surround the hub 81.

The sleeve 87 moves leftward and rightward in the shifting direction so that the clutch gear 64 and the hub 81 or the clutch gear 86 and the hub 81 are functionally connected to each other.

The fourth connecting shaft 60 and the output shaft 80 are rotated together when the sleeve 87 is moved to the left so that the clutch gear 64 and the hub 81 are functionally connected.

Conversely, when the sleeve 87 is moved to the right and the clutch gear 86 and the hub 81 are functionally connected, the output shaft 80 is not affected by the rotation of the fourth connecting shaft 60, And receives power from the shaft 50 to rotate.

On the other hand, a fifth connecting shaft 70 is formed in parallel relation to the output shaft 80, and a synchromesh transmission unit is formed in the fifth connecting shaft 70 as well.

The fifth connecting shaft 70 is formed with a clutch gear 75 that rotates integrally with the fifth connecting shaft 70 and a synchronizing shaft 71 is formed so as to freely rotate with respect to the fifth connecting shaft 70 .

The synchro shaft (71) has a clutch gear (72) at an upstream end and a drive gear (73) at a downstream end. The drive gear 73 is engaged with the drive gear 85 of the synchro shaft 83 formed on the output shaft 80.

A sleeve 76 is provided in the form of surrounding the clutch gear 75 and the sleeve 76 is movable toward the synchromesh 71.

The fifth linking shaft 70 and the synchro-shaft 71 are freely rotatable relative to each other and the sleeve 76 moves to the right to engage the clutch gear 72 75 and the clutch gear 72 are connected to each other, the fifth connecting shaft 70 and the synchromesh 71 rotate together.

A driving gear 74 is integrally rotatably formed near the downstream end of the fifth connecting shaft 70. The drive gear 74 is engaged with the drive gear 82 formed on the output shaft 80.

A single-stage wet multi-plate clutch 77 capable of stopping the rotation of the fifth connecting shaft 70 is coupled to the upstream end of the fifth connecting shaft 70.

According to this embodiment, the rotational driving force of the driven shaft 40 is transmitted to the output shaft (not shown) by using the third connecting shaft 50, the fourth connecting shaft 60, the fifth connecting shaft 70 and the synchromesh transmission unit connected thereto 80) is selectively formed.

Hereinafter, with reference to Figs. 1, 3A, and 3B, a power transmission path along the periphery of the first to fourth stages of the transmission of the present embodiment will be described.

FIG. 3A is a diagram illustrating a power transmission path in the first and third stages, and FIG. 3B is a diagram illustrating a power transmission path in the second and fourth stages.

It is assumed that the forward and reverse clutch 140 is connected to the forward side in the peripheral speed.

And follows the path indicated by the solid black solid arrow in FIG.

The first multi-plate clutch portion 111 of the first wet multi-plate clutch 110 engages with the input shaft 10 and at the same time the third multi-plate clutch portion 121 of the second wet multi- And is connected to the coaxial shaft 40.

The synchronous clutch 130 according to the present embodiment is a clutch used in a shift from a low speed (1-4 ranks) to a high speed (5-8 ranks).

In the first to fourth stages, the sleeve 138 moves to the left so that the first synchronous clutch portion of the synchronous clutch 130 is connected to the first connecting shaft 20. [

The first multi-plate clutch portion 111 is engaged with the input shaft 10, so that the drive gear 114 rotates together with the input shaft 10. The rotational force of the driving gear 114 is transmitted to the driving gear 132 meshed with the driving gear 114 to rotate the first synchro shaft 131.

Since the first synchro shaft 131 is connected to the first connecting shaft 20 in a dynamic fashion, the first synchro shaft 131 rotates the first connecting shaft 20. When the first connecting shaft 20 rotates, the forward synchro shaft 141 connected to the end portion is rotated.

Since the forward synchro shaft 141 and the driven shaft 40 are integrally rotated in the forward mode, the driven shaft 40 rotates as the forward synchro shaft 141 rotates.

As the driven gear 40 rotates, the drive gear 124 of the third multi-plate clutch portion 121 rotates and the drive gear 51 meshed with the drive gear 124 rotates, 50 are rotated.

The first multi-plate clutch portion 111 of the first wet multi-plate clutch 110 is separated from the input shaft 10 while the second multi-plate clutch portion 112 is engaged with the input shaft 10 and the second multi- Respectively.

Following the path indicated by the solid black solid arrow in FIG.

The second multi-plate clutch portion 112 is engaged with the input shaft 10 so that the drive gear 116 rotates together with the input shaft 10. [ The rotational force of the driving gear 116 is transmitted to the driving gear 136 engaged with the driving gear 116 to rotate the second synchro shaft 134.

The rotational force of the second synchro shaft 134 is transmitted to the driving gear 32 of the second connecting shaft 30 so that the driving force of the driving gear 32 32).

As the driving gear 32 rotates, the second connecting shaft 30 rotates, and the driving gear 31 rotates together.

When the driving gear 31 rotates, the driving gear 132 engaged with the driving gear 31 rotates. When the driving gear 132 rotates, the first synchro shaft 131 rotates.

Since the first synchro shaft 131 is connected to the first connecting shaft 20 in a dynamic fashion, the first synchro shaft 131 rotates the first connecting shaft 20.

The rotational force of the first connecting shaft 20 is transmitted to the third connecting shaft 50 in the same manner as the power transmitting path in the first-stage peripheral speed described above.

The first multi-plate clutch portion 111 of the first wet multi-plate clutch 110 is engaged with the input shaft 10 and the fourth multi-plate clutch portion 120 of the second wet multi- (122) is connected to the driven shaft (40).

And follows the path indicated by the thick black solid line and the dotted line arrow in FIG.

In the third stage, the power transmission path from the input shaft 10 to the driven shaft 40 is the same as the first stage.

As the driven shaft 40 rotates, the driving gear 126 of the fourth multi-plate clutch portion 122 rotates and the driving gear 52 meshed with the driving gear 126 rotates, 50 are rotated.

The first multi-plate clutch portion 111 is controlled to be separated from the input shaft 10 while the second multi-plate clutch portion 112 is connected to the input shaft 10 when the third multi-plate clutch portion 111 is shifted from the third stage to the fourth stage.

Followed by the path indicated by the thick black solid line and the dotted line arrow in FIG.

In the fourth stage, the power transmission path from the input shaft 10 to the driven shaft 40 is the same as the second stage. The power transmission path from the driven shaft 40 to the third connecting shaft 50 in the fourth stage is the same as the third stage.

The transmission according to the present embodiment is capable of eight stages of peripheral speed through the synchronous clutch 130. [

Hereinafter, referring to Figs. 4A and 4B, a power transmission path along the periphery of the fifth to eighth stages of the transmission of the present embodiment will be described.

And the path indicated by an arrow in bold black solid line in FIG.

The first multi-plate clutch portion 111 of the first wet multi-plate clutch 110 is engaged with the input shaft 10 and the third multi-plate clutch portion 121 of the second wet multi-plate clutch portion 120 is engaged And is connected to the driven shaft 40. At the same time, the sleeve 138 of the synchronizing clutch 130 moves to the right and the second synchronizing clutch portion of the synchronizing clutch 130 is engaged with the first connecting shaft 20. [

In the fifth to eighth stages, the second synchronous clutch portion remains connected to the first connecting shaft 20. [

The first multi-plate clutch portion 111 is engaged with the input shaft 10, so that the drive gear 114 rotates together with the input shaft 10. The rotational force of the driving gear 114 is transmitted to the driving gear 132 meshed with the driving gear 114 to rotate the first synchro shaft 131.

The rotational force of the first synchro shaft 131 is transmitted to the driving gear 31 of the second connecting shaft 30 and is transmitted to the driving gear 31 31).

As the driving gear 31 rotates, the second connecting shaft 30 rotates, and the driving gear 32 rotates together.

When the driving gear 32 rotates, the driving gear 136 engaged with the driving gear 32 rotates. When the driving gear 136 rotates, the second synchro shaft 134 rotates.

Since the second synchro shaft 134 is connected to the first connecting shaft 20 in a dynamic manner, the second synchro shaft 134 rotates the first connecting shaft 20.

The rotational force of the first connecting shaft 20 is transmitted to the third connecting shaft 50 in the same manner as the power transmitting path in the first-stage peripheral speed described above.

When the first multi-plate clutch portion 111 of the first wet multi-plate clutch 110 is disengaged from the input shaft 10 while the second multi-plate clutch portion 112 is engaged with the input shaft 10 Respectively.

And follows the path indicated by the bold black solid arrow in FIG.

The second multi-plate clutch portion 112 is engaged with the input shaft 10 so that the drive gear 116 rotates together with the input shaft 10. [ The rotational force of the driving gear 116 is transmitted to the driving gear 136 engaged with the driving gear 116 to rotate the second synchro shaft 134.

Since the second synchro shaft 134 is connected to the first connecting shaft 20 in a dynamic manner, the second synchro shaft 134 rotates the first connecting shaft 20.

The rotational force of the first connecting shaft 20 is transmitted to the third connecting shaft 50 in the same manner as the power transmitting path in the two-stage peripheral speed described above.

The first multi-plate clutch portion 111 of the first wet multi-plate clutch 110 is engaged with the input shaft 10 and the fourth multi-plate clutch portion 120 of the second wet multi- (122) is connected to the driven shaft (40).

And the path indicated by the solid black solid lines and dotted line arrows in FIG.

In the seventh stage, the power transmission path from the input shaft 10 to the driven shaft 40 is the same as the fifth stage.

As the driven shaft 40 rotates, the driving gear 126 of the fourth multi-plate clutch portion 122 rotates and the driving gear 52 meshed with the driving gear 126 rotates, 50 are rotated.

The first multi-plate clutch portion 111 is controlled to be disconnected from the input shaft 10 while the second multi-plate clutch portion 112 is connected to the input shaft 10 in the case of shifting from the seventh stage to the eighth stage.

And the path indicated by the thick black solid line and the dotted line arrow in FIG.

The power transmission path from the input shaft 10 to the driven shaft 40 at the eighth stage is the same as the seventh stage. The power transmission path from the driven shaft 40 to the third connecting shaft 50 in the eighth stage is the same as the sixth stage.

The transmission according to the present embodiment is provided with a third speed change portion capable of three-speed shifting, so that a total of 24 speeds are possible (except for reverse speed change).

Hereinafter, with reference to Figs. 5A to 5C, the power transmission path according to the negative speed change of the transmission of the present embodiment will be described.

5A is a diagram for explaining the power transmission path of the one-stage shift, FIG. 5B is a diagram for explaining the power transmission path of the two-stage shift, and FIG. 5C is a diagram for explaining the power transmission path of the three- .

The sleeve 76 moves to the right to synchronize the clutch gear 75 and the clutch gear 72 in the first-speed shifting. At this time, the sleeve 87 is in a neutral state where it is not connected to either the clutch gear 64 or the clutch gear 86.

5A, as the third connecting shaft 50 rotates, the driving gear 54 rotates, and the driving gear 54 rotates the driving gear 84 to rotate the synchro shaft 83 . At this time, the synchromesh shaft 83 makes idle with respect to the output shaft 80.

As the synchro shaft 83 rotates, the driving gear 73 engaged with the driving gear 85 rotates, and the synchro shaft 71 rotates together with the driving gear 73.

The clutch gear 72 of the synchro shaft 71 is synchronized with the clutch gear 75 integrally formed with the fifth connecting shaft 70 so that the fifth connecting shaft 70 rotates together with the synchro shaft 71. [

The fifth gear shaft 70 rotates and the drive gear 74 rotates and the drive gear 74 rotates the drive gear 82 to finally rotate the output shaft 80.

5B, the sleeve 76 moves to the left side in the second-speed shifting state to disconnect the clutch gear 75 and the clutch gear 72 from each other. Therefore, the synchro shaft 71 makes idle with respect to the fifth connecting shaft 70.

On the other hand, the sleeve 87 moves to the right to connect the hub 81 and the clutch gear 86.

As the third connecting shaft 50 rotates, the driving gear 54 rotates, and the driving gear 54 rotates the driving gear 84 to rotate the synchromesh 83. The synchro shaft 83 rotates the output shaft 80.

5C, the sleeve 87 moves to the left in the third-speed shifting, and connects the hub 81 and the clutch gear 64 to each other. At this time, the sleeve 76 moves to the left to maintain the state in which the clutch gear 75 and the clutch gear 72 are disconnected from each other.

As the third connecting shaft 50 rotates, the driving gear 53 rotates, and the driving gear 53 rotates the driving gear 62 to rotate the rotating shaft 61.

The rotary shaft 61 rotates the synchro-shaft 63 again, and the synchro-shaft 63 finally rotates the output shaft 80 synchronized therewith.

Fig. 6 is a diagram for explaining the power transmission path when the transmission is retracted according to the present embodiment. Fig. For ease of explanation, the power transmission to the first connection shaft 20 is shown as being in the state of the first-stage peripheral speed (or the fifth-speed peripheral speed) state.

The sleeve 148 moves to the right to connect the hub 147 and the clutch gear 145 of the reverse synchronous shaft 144 to each other.

6, when the forward synchro shaft 141 rotates by the rotation of the first connecting shaft 20, the driving gear 153 engaged with the driving gear 142 is rotated by the driving gear 142. [

As the driving gear 153 rotates, the driving gear 152 formed on the rotating shaft 151 also rotates, and the driving gear 152 rotates the idle gear 34. [

The idle gear 34 rotates and the driven gear 146 engaged with the idle gear 34 rotates. The rotation of the driving gear 146 causes the reverse synchro shaft 144 to rotate and the driven shaft 40 synchronized with the rotation thereof is rotated. The process of transmitting the rotational driving force of the driven shaft 40 to the wheel 88 has been described above.

At this time, the rotational direction of the driven shaft 40 is changed by the idle gear 34 as opposed to the forward direction.

According to the present embodiment, by mixing a hydraulic multi-plate hydraulic clutch and a mechanical synchronous clutch, the size of the transmission can be reduced and the structure can be simplified.

In addition, since the length of the shafts for transmitting the power is short, a ball bearing capable of receiving an inexpensive but thrust can be used as a bearing for supporting the shaft on the frame, and a helical gear having an axial thrust .

In the drawing, black circles represent ball bearings, and black squares represent needle bearings.

Also, since the rotational force of the input shaft 10 can be transmitted to the driven shaft 40 directly via the first connecting shaft 20 without passing through the other connecting shaft according to the number of stages, the power transmitting path is simplified, Is high.

Example  2

7 is a diagram of a transmission according to a second embodiment of the present invention.

7, the transmission includes an input shaft 10 rotated by an engine (not shown), a first connecting shaft 20 rotating and transmitting power of the input shaft 10, A second connecting shaft 30 capable of transmitting power to the connecting shaft 20 and a driven shaft 40 rotated by the power of the input shaft 10 via the first connecting shaft 20. [

The input shaft 10, the first connecting shaft 20 and the second connecting shaft 30 extend parallel to each other in parallel relation to each other and transmit the power of the engine to the driven shaft 40.

A third connecting shaft 50 extending parallel to the driven shaft 40 in parallel relation to the driven shaft 40 is formed on the downstream side end of the driven shaft 40.

A fourth connecting shaft 60 is formed on the downstream side end of the driven shaft 40 such that the driven shaft 40 and its rotational center shaft coincide with each other (coaxially), and the downstream end of the fourth connecting shaft 60 And an output shaft 80 connected to a wheel 88 of the vehicle is arranged coaxially.

8 is an axial view of the input shaft 10, the first connecting shaft 20 and the second connecting shaft 30 of the transmission according to the present embodiment.

8, the input shaft 10, the first connecting shaft 20, and the second connecting shaft 30 are arranged such that the line segments connecting the longitudinal center axes thereof form a triangle. According to the present embodiment, the second connecting shaft 30 is disposed below the input shaft 10, and the first connecting shaft 20 is disposed on the side of the input shaft 10 (second connecting shaft 30) Eccentrically disposed.

Referring again to FIG. 7, on the input shaft 10, there is provided a first wet multi-plate clutch which is actuated by hydraulic pressure to connect or disconnect the power, and is operatively connected to the first wet multi-plate clutch on the first connection shaft 20 A synchronous clutch is formed which connects or disconnects the power by synchronizing the gears.

The clutch pack in which the components constituting the wet multi-plate clutch and the synchronous clutch are concentrated has a certain volume, so that there is a certain limit to bring the distance between the input shaft 10 and the first connecting shaft 20 close to each other.

According to the present embodiment, the second connecting shaft 30, to which the clutch is not connected, is disposed below the input shaft 10 so that the distance between the two shafts can freely be adjusted to reduce the overall size of the transmission.

The first wet multi-plate clutch 210 is connected to the input shaft 10 by a hydraulic pressure to connect or disconnect the power.

The first wet multi-plate clutch 210 according to the present embodiment is a two-stage clutch in which the first multi-plate clutch portion 211 and the second multi-plate clutch portion 212 are opposed to each other.

The first clutch hub 213 is rotatably connected to the input shaft 10 in the clutch housing of the first multi-plate clutch 211. A driving gear 214 is connected to the upstream end of the first clutch hub 213, Respectively.

The second clutch hub 215 is freely rotatably connected to the input shaft 10 in the clutch housing of the second multi-plate clutch portion 212 and the drive gear 216 is connected to the downstream end of the second clutch hub 215, Respectively.

On the first connecting shaft 20, a synchronous clutch 230 for connecting or disconnecting power by synchronizing the gears is formed.

According to the present embodiment, the first wet multi-plate clutch 210 and the synchronous clutch 230 are functionally connected to each other. The synchronous clutch 230 according to the present embodiment is formed by a synchromesh transmission mechanism.

According to the present embodiment, the synchronous clutch 230 includes a first synchronous clutch portion including a driving gear 232, a first synchronous shaft 231 and a clutch gear 233, and a second synchronous clutch portion including a driving gear 236, And a second synchronous clutch portion including a synchromesh shaft 234 and a clutch gear 235.

The synchronizing clutch 230 includes a hub 237 that rotates integrally with the first connecting shaft 20 and a second connecting shaft 237 which is formed on the upstream and downstream sides of the hub 237 and is freely rotatable about the first connecting shaft 20 1 synchronous shaft 231 and a second synchronous shaft 234. [

A drive gear 232 is formed at the upstream end of the first synchro shaft 231 and a clutch gear 233 is formed at the downstream end of the first synchro shaft 231. A clutch gear 235 is formed at the upstream end of the second synchro shaft 234 and a drive gear 236 is formed at the downstream end.

A sleeve 238 is formed between the first synchro shaft 231 and the second synchro shaft 234 so as to surround the hub 237.

The sleeve 238 moves left and right during shifting to selectively couple the clutch gear 233 and the hub 237 or the clutch gear 235 and the hub 237 to each other.

When the sleeve 238 is moved to the left and the clutch gear 233 and the hub 237 are functionally connected, the first connecting shaft 20 and the first synchronizing shaft 231 rotate together. At this time, the second synchro shaft 234 is kept free to rotate with respect to the first connecting shaft 20, so that no power transmission occurs between the second synchro shaft 234 and the first connecting shaft 20.

Conversely, when the sleeve 238 is moved to the right and the clutch gear 235 and the hub 237 are functionally connected, the first connecting shaft 20 and the second synchronizing shaft 234 rotate together. At this time, the first synchro shaft 231 is kept free to rotate with respect to the first connecting shaft 20, so that no power transmission occurs between the first synchro shaft 231 and the first connecting shaft 20.

A driving gear 31 and a driving gear 32 are formed on the second connecting shaft 30. [

The drive gear 214 of the first wet multi-plate clutch 210 is engaged with the drive gear 31 and the drive gear 31 is engaged with the drive gear 232 of the synchronous clutch 230.

The drive gear 216 of the first wet multi-plate clutch 210 is engaged with the drive gear 32 and the drive gear 32 is engaged with the drive gear 236 of the synchronous clutch 230.

The driven shaft 40 is connected to the forward / backward clutch 240. The forward / backward clutch 240 is constituted by a synchromesh transmission mechanism.

The forward and reverse clutch 240 includes a hub 247 that rotates integrally with the driven shaft 40 and a forward synchro shaft 241 that is formed on the upstream and downstream sides of the hub 247 and freely rotatable about the driven shaft 40 And a reverse synchro shaft 244. As shown in FIG.

A drive gear 242 is formed at the upstream end of the forward synchro shaft 241 and a clutch gear 243 is formed at the downstream end of the forward synchro shaft 241. A clutch gear 245 is formed at the upstream end of the reverse synchro shaft 244 and a drive gear 246 is formed at the downstream end.

A sleeve 248 is formed between the forward synchro shaft 241 and the reverse synchro shaft 244 so as to surround the hub 247.

Sleeve 248 moves left and right during shifting to selectively couple clutch gear 243 and hub 247 or clutch gear 245 and hub 247 to each other.

When the sleeve 248 is moved to the left and the clutch gear 243 and the hub 247 are functionally connected, the driven shaft 40 and the forward synchro shaft 241 rotate together. At this time, the reverse synchro shaft 244 is maintained to rotate freely with respect to the driven shaft 40, so that no power transmission occurs between the reverse synchro shaft 244 and the driven shaft 40.

Conversely, when the sleeve 248 is moved to the right and the clutch gear 245 and the hub 247 are functionally connected, the driven shaft 40 and the reverse synchro shaft 244 rotate together. At this time, the forward synchro shaft 241 is kept free to rotate relative to the driven shaft 40, so that no power transmission occurs between the forward synchro shaft 241 and the driven shaft 40.

On the downstream side of the first connecting shaft 20, a driving gear 21 and a driving gear 22 are formed. The drive gear 21 meshes with the drive gear 242 formed on the shaft 241.

On the other hand, an idle shaft 251 is formed on the input shaft 10 on the downstream side of the wet multi-plate clutch 210 so as to freely rotate with respect to the input shaft 10. An idle gear 252 is formed at the downstream end of the idle shaft 251.

The drive gear 22 meshes with the idle gear 252 and the idle gear 252 meshes with the drive gear 246 formed on the shaft 244.

The rotational force of the first connecting shaft 20 is transmitted to the forward clutch 240 through the idle gear 252 so that the rotational direction of the driven shaft 40 is changed.

The second wet multi-plate clutch 220 of the second stage is connected to the driven shaft 40 downstream of the forward / backward clutch 240.

The third multi-plate clutch portion 221 and the second multi-plate clutch portion 222 are opposed to each other in the second wet multi-plate clutch 220.

A third clutch hub 223 is freely rotatably connected to the driven shaft 40 at the clutch housing of the third multi-plate clutch portion 221 and a drive gear 224 is provided at the upstream end of the third clutch hub 223 Is formed.

A fourth clutch hub 225 is freely rotatably connected to the driven shaft 20 at the clutch housing of the fourth multi-plate clutch portion 222 and a drive gear 226 Is formed.

The structure of the transmission formed after the driven shaft 40, such as the auxiliary transmission portion, is the same as that of the first embodiment, and a detailed description thereof will be omitted.

Hereinafter, referring to Figs. 9A and 9B, the power transmission path along the periphery of the first to fourth stages of the transmission of the present embodiment will be described.

FIG. 9A is a diagram for explaining a power transmission path in the first and second stages, and FIG. 9B is a diagram illustrating a power transmission path in the third and fourth stages.

It is assumed that the front and rear clutch 240 is connected to the forward side.

And the path indicated by the solid black solid arrow in FIG.

The first multi-plate clutch portion 211 of the first wet multi-plate clutch 210 is engaged with the input shaft 10 and at the same time the third multi-plate clutch portion 221 of the second wet multi- And is connected to the coaxial shaft 40.

The synchronous clutch 230 according to the present embodiment is a clutch used in a shift from a low speed (1-4 ranks) to a high speed (5-8 ranks).

In the first to fourth stages, the sleeve 238 moves to the left so that the first synchronous clutch portion of the synchronous clutch 230 is connected to the first connecting shaft 20.

The first multi-plate clutch portion 211 is engaged with the input shaft 10, so that the drive gear 214 rotates together with the input shaft 10. The rotational force of the driving gear 214 rotates the driving gear 31 of the second connecting shaft 30.

The driving gear 232 rotates by the rotation of the driving gear 31 and the first synchronizing shaft 231 rotates together with the driving gear 232.

Since the first synchro shaft 231 is synchronized to rotate together with the first connecting shaft 20, the first connecting shaft 20 rotates by the first synchro shaft 231.

As the first connecting shaft 20 rotates, the driving gear 21 rotates together with the first connecting shaft 20, and the driving gear 242 meshed therewith by the rotation of the driving gear 21 rotates The forward synchro shaft 241 is rotated.

Since the forward synchro shaft 241 and the driven shaft 40 are integrally rotated in the forward mode, the driven shaft 40 rotates as the forward synchro shaft 241 rotates.

As the driven gear 40 rotates, the drive gear 224 of the third multi-plate clutch portion 221 rotates and the drive gear 51 meshed with the drive gear 224 rotates, 50 are rotated.

The first multi-plate clutch portion 211 of the first wet multi-plate clutch 210 is separated from the input shaft 10 while the second multi-plate clutch portion 212 is engaged with the input shaft 10 and the second multi- Respectively.

And follows the paths indicated by the solid black solid lines and dotted line arrows in FIG.

The second multi-plate clutch portion 212 is engaged with the input shaft 10 so that the drive gear 216 rotates together with the input shaft 10. [ The rotational force of the driving gear 216 rotates the driving gear 32 of the second connecting shaft 30.

When the driving gear 32 rotates, the second connecting shaft 30 rotates, and the driving gear 31 rotates together with the second connecting shaft 30. [

The driving gear 232 is rotated by the rotation of the driving gear 31 and the first synchro shaft 231 rotates together with the driving gear 232 to rotate the first connecting shaft 20. [

The rotational force of the first connecting shaft 20 is transmitted to the third connecting shaft 50 in the same manner as the power transmitting path in the first-stage peripheral speed described above.

The first multi-plate clutch portion 211 of the first wet multi-plate clutch 210 is engaged with the input shaft 10 and the fourth multi-plate clutch portion 220 of the second wet multi- (222) is connected to the driven shaft (40).

And follows the path indicated by the solid black solid arrow in FIG.

In the third stage, the power transmission path from the input shaft 10 to the driven shaft 40 is the same as the first stage.

As the driven shaft 40 rotates, the drive gear 226 of the fourth multi-plate clutch portion 222 rotates and the drive gear 52 meshed with the drive gear 226 rotates, 50 are rotated.

The first multi-plate clutch portion 211 is controlled to be disconnected from the input shaft 10 while the second multi-plate clutch portion 212 is connected to the input shaft 10 when the third multi-plate clutch portion 211 is shifted from the third stage to the fourth stage.

Along the path indicated by the solid black solid lines and dotted line arrows in FIG.

In the fourth stage, the power transmission path from the input shaft 10 to the driven shaft 40 is the same as the second stage. The power transmission path from the driven shaft 40 to the third connecting shaft 50 in the fourth stage is the same as the third stage.

The transmission according to the present embodiment is capable of eight stages of peripheral speed through the synchronous clutch 230. [

Hereinafter, with reference to Figs. 10A and 10B, a power transmission path along the periphery of the fifth to eighth stages of the transmission of the present embodiment will be described.

And the path indicated by an arrow in bold black solid line in FIG.

The first multi-plate clutch portion 211 of the first wet multi-plate clutch 210 is engaged with the input shaft 10 and the third multi-plate clutch portion 221 of the second wet multi-plate clutch portion 220 is engaged And is connected to the driven shaft 40. At the same time, the sleeve 238 of the synchronizing clutch 230 moves to the right and the second synchronizing clutch portion of the synchronizing clutch 230 is connected to the first connecting shaft 20. [

In the fifth to eighth stages, the second synchronous clutch portion remains connected to the first connecting shaft 20. [

The first multi-plate clutch portion 211 is engaged with the input shaft 10, so that the drive gear 214 rotates together with the input shaft 10. The rotational force of the driving gear 214 rotates the driving gear 31 of the second connecting shaft 30.

When the driving gear 31 rotates, the second connecting shaft 30 rotates, and the driving gear 32 rotates together with the second connecting shaft 30.

The driving gear 236 is rotated by the rotation of the driving gear 32 and the second synchro shaft 234 is rotated together with the driving gear 236 to rotate the first connecting shaft 20. [

The rotational force of the first connecting shaft 20 is transmitted to the third connecting shaft 50 in the same manner as the power transmitting path in the first-stage peripheral speed described above.

The first multi-plate clutch portion 211 of the first wet multi-plate clutch 210 is separated from the input shaft 10 while the second multi-plate clutch portion 212 is engaged with the input shaft 10 and the second multi- Respectively.

And follows the path indicated by the solid black solid lines and dotted line arrows in FIG.

The second multi-plate clutch portion 212 is engaged with the input shaft 10 so that the drive gear 216 rotates together with the input shaft 10. [ The rotational force of the driving gear 216 rotates the driving gear 32 of the second connecting shaft 30.

The driving gear 236 is rotated by the rotation of the driving gear 32 and the second synchronous shaft 234 is rotated together with the driving gear 236.

Since the second synchro shaft 234 is synchronized to rotate together with the first connecting shaft 20, the first connecting shaft 20 is rotated by the second synchro shaft 234.

The rotational force of the first connecting shaft 20 is transmitted to the third connecting shaft 50 in the same manner as the power transmitting path in the two-stage peripheral speed described above.

The first multi-plate clutch portion 211 of the first wet multi-plate clutch 210 is engaged with the input shaft 10 and the fourth multi-plate clutch portion 220 of the second wet multi- (222) is connected to the driven shaft (40).

And follows the path indicated by the solid black solid arrow in FIG.

In the seventh stage, the power transmission path from the input shaft 10 to the driven shaft 40 is the same as the fifth stage.

As the driven shaft 40 rotates, the drive gear 226 of the fourth multi-plate clutch portion 222 rotates and the drive gear 52 meshed with the drive gear 226 rotates, 50 are rotated.

The first multi-plate clutch portion 211 is controlled to be separated from the input shaft 10 while the second multi-plate clutch portion 212 is connected to the input shaft 10 in the case of shifting from the seventh stage to the eighth stage.

And the path indicated by the bold black solid line and dotted line arrow in Fig.

The power transmission path from the input shaft 10 to the driven shaft 40 at the eighth stage is the same as the seventh stage. The power transmission path from the driven shaft 40 to the third connecting shaft 50 in the eighth stage is the same as the sixth stage.

The configuration of the negative speed change portion and the principle of the negative speed change are the same as those of the first embodiment, and a detailed description thereof will be omitted.

Fig. 11 is a diagram for explaining the power transmission path when the transmission is retracted according to the present embodiment. Fig. For ease of explanation, the power transmission to the first connection shaft 20 is shown as being in the state of the first-stage peripheral speed (or the fifth-speed peripheral speed) state.

The sleeve 248 moves to the right to connect the hub 247 and the clutch gear 245 of the reverse synchro shaft 244. In this case,

11, the forward synchro shaft 241 idles relative to the driven shaft 40, so that the rotational force of the first connecting shaft 20 is transmitted to the idle gear 252 through the driving gear 22 .

The idle gear 252 rotates and the driven gear 246 meshed with the idle gear 252 rotates. The rotation of the driving gear 246 causes the reverse synchro shaft 244 to rotate and the driven shaft 40 synchronized with the rotation thereof is rotated. The process of transmitting the rotational driving force of the driven shaft 40 to the wheel 88 has been described above.

At this time, the rotational direction of the driven shaft 40 is reversed by the idle gear 252 as opposed to the forward direction.

According to the present embodiment, by mixing a hydraulic multi-plate hydraulic clutch and a mechanical synchronous clutch, the size of the transmission can be reduced and the structure can be simplified.

In addition, the hydraulic power type multi-plate clutch and the mechanical synchronous clutch are mixed, and the power transmission structure is simple, and the power transmission efficiency is excellent.

In addition, since the length of the shafts for transmitting the power is short, a ball bearing capable of receiving an inexpensive but thrust can be used as a bearing for supporting the shaft on the frame, and a helical gear having an axial thrust .

In the drawing, black circles represent ball bearings, and black squares represent needle bearings.

Claims (15)

1. A transmission for transmitting engine power of a vehicle,
An input shaft 10 rotated by an engine;
A first connection shaft 20 through which the power of the input shaft is transmitted and rotated;
A second connecting shaft 30 capable of transmitting power to the first connecting shaft 20; And
And a driven shaft (40) rotated by the power of the input shaft (10) via the first connecting shaft (20)
A first wet multi-plate clutch 110 or 210 is provided on the input shaft 10 to operate or shut off power by being operated by hydraulic pressure,
On the first connecting shaft 20, there are provided synchronous clutches 130 and 230 for connecting or disconnecting power due to synchronization between the gears,
Wherein the first wet multi-plate clutch (110, 210) and the synchronous clutch (130, 230) are functionally connected to change the power transmission path to perform the shifting. The method according to claim 1,
Wherein the input shaft (10), the first connecting shaft (20), and the second connecting shaft (30) extend parallel to each other in parallel relationship. The method according to claim 1,
And a second wet multi-plate clutch (120, 220) that is actuated by hydraulic pressure to connect or disconnect power to the driven shaft (40). The method of claim 3,
The first wet multi-plate clutches 110 and 210 are two-stage clutches in which the first multi-plate clutch portions 111 and 211 and the second multi-plate clutch portions 112 and 212 interlock with the input shaft 10,
The second wet multi-plate clutch 120, 220 is a two-stage clutch in which the third multi-plate clutch portions 121, 221 and the fourth multi-plate clutch portions 122, 222 interlock with the driven shaft 40 alternately,
Wherein the first wet multi-plate clutch (110, 210) and the second wet multi-plate clutch (120, 220) selectively engage with corresponding axes to selectively change the power transmission path, . 5. The method of claim 4,
The synchronizing clutches 130 and 230 are configured such that the first synchronizing clutch portions 131, 132, 133, 231, 232 and 233 and the second synchronizing clutch portions 134, 135, 136, 234, 235 and 236 And is a two-stage clutch that alternately meshes with the first connecting shaft (20)
The synchronous clutch 130, 230, the first wet multi-plate clutch 110, 210 and the second wet multi-plate clutch 120 selectively engage corresponding axes to selectively change the power transmission path, And an 8-speed shift is performed. The method according to claim 1,
The first wet multi-plate clutch 210 is operatively connected to the synchronous clutch 230 via the second connecting shaft 30,
The power of the input shaft 10 is transmitted to the first connection shaft 20 via the second connection shaft 30 and transmitted to the driven shaft 40 through the first connection shaft 20 . The method according to claim 1,
The first wet multi-plate clutch 110 is directly connected to the synchronous clutch 130,
The power of the input shaft 10 is transmitted to the second connection shaft 30 via the first connection shaft 20 and transmitted to the driven shaft 40 via the second connection shaft 30 . 8. The method of claim 7,
And the first connecting shaft (20) and the driven shaft (40) are formed coaxially. The method according to claim 1,
And a forward / backward clutch (140, 240) capable of changing a rotating direction of the driven shaft (40) is formed on the driven shaft (40). 10. The method of claim 9,
Wherein the synchromesh clutches (130, 230) and the forward and reverse clutches (140, 240) are constituted by a synchromesh mechanism. The method according to claim 1,
Further comprising a sub transmission portion for selectively transmitting the rotational driving force of the driven shaft (40) to an output shaft (80) connected to a wheel (88) of the vehicle. 12. The method of claim 11,
Wherein the auxiliary speed-
A third connecting shaft (50) extending in parallel relation to the driven shaft (40) in parallel relationship;
A fourth connecting shaft 60 formed coaxially with the driven shaft 40 and the output shaft 80; And
And a fifth connecting shaft (70) extending in parallel relation to the output shaft (80)
Wherein the transmission performs three-stage shifting such that the power is transmitted via the third connecting shaft (50), the fourth connecting shaft (60) or the fifth connecting shaft (70) by three paths. 13. The method of claim 12,
Power is transmitted from the third connecting shaft 50 to the fifth connecting shaft 70 and then from the fifth connecting shaft 70 to the output shaft 80. In this case, The transmission. 13. The method of claim 12,
And the power is directly transmitted from the third connecting shaft (50) to the output shaft (80) in the second step of shifting. 13. The method of claim 12,
Wherein power is transmitted from the driven shaft (40) to the output shaft (80) via the fourth connecting shaft (60) when the third gear is shifted.

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