KR20050061718A - Double clutch transmission - Google Patents

Abstract

The present invention relates to a double clutch transmission, and to install three kinds of drive gears on the input shaft to output a differential gear ratio variably to output a six-speed transmission ratio, shortening the overall length of the transmission, even gear And repositioning of the hole means gears to enable skip shifting.

In order to achieve the above object, the present invention, the main input shaft is installed so as to receive the driving force from the engine, the first input shaft of the solid type arranged coaxially to enable the transmission of power via the main input shaft and the first clutch, The second input shaft of the hollow type is installed coaxially from the outer periphery of the first input shaft while being capable of transmitting power via the main input shaft and the second clutch, and installed to rotate integrally with the first input shaft and the second input shaft, respectively. To vary the differential gear ratio between a plurality of drive gears, an output shaft having a plurality of driven gears meshing with the plurality of drive gears while being disposed in a position opposite to the first input shaft, and a differential device interworking with the output shaft. Differential ratio variable drive gears installed in the output shaft, differential ratio variable driven gears installed in the differential device, It characterized in that the output shaft comprises a group with the fish species synchronous and differential non-variable longitudinal motive plurality of sink is provided for the power transmission between the fish giguryu.

Description

Double clutch transmission

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a double clutch transmission, and more particularly, to a double clutch transmission that reduces the overall length of the transmission and enables skip shifting.

In general, the double clutch transmission is a second-generation automated manual transmission that improves the shifting delay caused by clutch disconnection when shifting, which is a disadvantage in the ASG (automated shift gear) transmission currently applied to small vehicles. It is known to show excellent performance in terms of efficiency.

Such a double clutch transmission uses two clutches on the input shaft, engages a synchro of the gear to be shifted in advance, releases one clutch currently engaged, and shifts by engaging a new clutch. The shift delay (lowering torque during shifting) is improved.

Currently developed double clutch transmissions are classified into wet clutch and dry clutch, and dry double clutch transmission according to the application of dry clutch. In the case of dry clutch, clutch due to wear problems While there is difficulty in controlling the wet clutch, there is no difficulty in applying the technology already applied in the automatic transmission. Therefore, the current high torque model adopts the double clutch transmission using the wet clutch. . In addition, there is a need for a technology for configuring a system in a smaller space.

However, both the dry double clutch transmission and the wet double clutch transmission have a gear ratio of at least six gears for the expansion of the gear ratio. The front wheel drive type has a gear ratio of six gears and requires additional clutches. Therefore, the battlefield has a problem that is very increased. In particular, wet double clutch transmissions are being used for high-capacity high-torque engines because of their large clutch capacity, and in order to cope with high torques, the gear width of the gears must be greatly increased due to strength problems, which is more disadvantageous in terms of the overall length of the transmission. It becomes

Meanwhile, the structure of the double clutch transmission, which has a six-speed gear ratio while applying a wet clutch, is largely divided into two types, that is, a method in which six gears are arranged on the input shaft while using one output shaft, and the overall length There are methods of arranging five gears on the input shaft while using two output shafts for shortening. However, in case of arranging six gears on the input shaft while using one output shaft, it cannot be applied to a front wheel drive vehicle. Due to the long length, it was impossible to mount, and in the method of arranging five gears on the input shaft while using two output shafts as another, it was advantageous in terms of lay-out of shortening of the overall length. Since it is located on the second gear, the outer diameter of the reverse driven gear could not be increased. Due to this, there was a problem that the reverse reduction ratio is set too small compared to the reduction ratio of the first forward.

In addition, the current commercially available double clutch transmission, since the mating gear and the hole gear are separately installed on the input shaft, it is always possible to shift from the mating means to the hole means or the hole means to the mating means.

As a result, when shifting such as a kickdown, a shift shift such as 6 → 4, 5 → 3, and 3 → 1 cannot be performed structurally, resulting in a problem of deterioration in acceleration response.

Accordingly, the present invention has been made in view of the above, and by installing three types of drive gears on the input shaft, the differential gear ratio can be output variably, thereby outputting a six-speed transmission ratio and shortening the overall length of the transmission. It is an object of the present invention to provide a double clutch transmission that enables skip shifting through the rearrangement of the mating gear and the hole gear.

The present invention for achieving the above object,

A main input shaft installed to receive driving force from the engine,

A solid first input shaft disposed coaxially to enable transmission of power through the main input shaft and the first clutch;

A hollow second input shaft coaxially installed at an outer circumference of the first input shaft while transmitting power through the main input shaft and the second clutch;

A plurality of drive gears installed to rotate integrally with the first input shaft and the second input shaft, respectively;

An output shaft having a plurality of driven gears meshed with the plurality of drive gears while being installed at a position opposite to the first input shaft,

A differential ratio variable drive gear installed in the output shaft to vary the differential gear ratio between the differential devices interlocked with the output shaft, a differential ratio variable driven gear installed in the differential device;

And a plurality of synchro mechanisms installed for power transmission between the output shaft and the driven gears and the differential ratio variable driven gears.

The drive gears may include a 3-4 stage drive gear and a reverse drive gear installed on the first input shaft; Characterized in that the 1-2 stage drive gear and 5-6 stage drive gear installed on the second input shaft.

In addition, the driven gear is installed on the output shaft, the 3-4 stage driven gear meshed with the 3-4 stage drive gear, the 1-2 stage driven gear meshed with the 1-2 stage drive gear, And 5-6 stage driven gears meshed with 5-6 stage drive gears and backward driven gears meshed with the reverse drive gears.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the main input shaft 12 is installed to be directly connected to the crank shaft of the engine 10 to receive a driving force, and the first input shaft 14 is coaxial with the main input shaft 12. And a second input shaft 16 are provided, respectively.

Here, the first input shaft 14 is made of a solid type that is arranged to enable the interruption of power via the main input shaft 12 and the first clutch (C1), the second input shaft 16 is the main It is possible to control the power via the input shaft 12 and the second clutch (C2) as well as a hollow type arranged coaxially on the outer periphery of the first input shaft (14).

In addition, the first clutch C1, the second clutch C2, and the brake B are fastened and released according to control by a controller (not shown) during shifting, which is the same as in a conventional automatic transmission. For this reason, the detailed operation is omitted since it is a publicly known issue that takes into account the response and the shank by pressure control when fastening and releasing.

In addition, the first input shaft 14 and the second input shaft 16 are each provided with a plurality of drive gears that are integrally rotated, first, the first input shaft 14, 3-4 stage drive gear (G- 3 and 4 and a reverse drive gear (R) are respectively provided, and the second input shaft (16), the 1-2 stage drive gear (G-1, 2) and the 5-6 stage drive gear (G-5, 6) Are installed respectively.

On the other hand, the output shaft 18 having a plurality of driven gears are installed in the position opposite to the first input shaft 14 having a plurality of driven gears meshing with the plurality of drive gears, the driven gears are the output shaft 3-4 stage driven gear (G'-3,4) which is provided on (18) and meshes with said 3-4 stage drive gear (G-3,4), and said 1-2 stage drive gear (G) 1-2 stage driven gear (G'-1,2) engaged with -1,2), 5-6 stage driven gear (G'- engaged with 5-6 stage drive gear (G-5,6) 5, 6) and a reverse driven gear R 'meshed with the reverse drive gear R.

In addition, between the differential device (D) interlocked with the output shaft (18) and the differential ratio variable drive gears provided on the output shaft (18) so as to vary the differential gear ratio, and is installed in the differential device (D) The differential ratio variable driven gears are provided, and the differential ratio variable drive gears include a first differential drive gear D-1 and a second differential drive gear D-2 provided on the output shaft 18. The differential ratio variable driven gear may include a first differential driven gear D'-1 and a second differential driven gear D'-2 installed in the differential device D.

In addition, a plurality of synchro mechanisms are provided for power transmission between the output shaft 18 and the driven gears and the differential ratio variable driven gears. The synchro mechanisms are the 1-2 stage driven gears (G'-). 1,2) and 5-6-stage driven gear (G'-5,6), the first sink mechanism (S1), the 3-4 stage driven gear (G'-3,4) and the reversing driven gear A second synchro mechanism S2 provided between R 'and a third synchro mechanism S3 provided between the first differential drive gear D-1 and the second differential drive gear D-2. .

Here, the first synchro mechanism (S1) to the third synchro mechanism (S3) is operated in accordance with the driving of the actuator provided in each, the operation of each actuator is the controller (not shown) as in the already known semi-automatic transmission Since it is made by), detailed configuration thereof will be omitted.

In addition, between the reverse drive gear (R) and the reverse driven gear (R '), the reverse idle gear (I) is provided to be engaged on the idle axis.

Hereinafter, a detailed operation of the double clutch transmission according to the present invention will be described.

First, the operation table for the friction element and the synchro mechanism which are fastened and operated respectively in the 1 to 6 speed and the reverse speed in the double clutch transmission according to the present invention are as follows.

Gearshift Working element One 2nd clutch (C2) + 1st sync mechanism (S1) + 3rd sync mechanism (S3) 2 2nd clutch (C2) + 1st sync mechanism (S1) + 3rd sync mechanism (S3) 3 First clutch (C1) + second sync mechanism (S2) + third sync mechanism (S3) 4 First clutch (C1) + second sync mechanism (S2) + third sync mechanism (S3) 5 2nd clutch (C2) + 1st sync mechanism (S1) + 3rd sync mechanism (S3) 6 2nd clutch (C2) + 1st sync mechanism (S1) + 3rd sync mechanism (S3) R First clutch (C1) + second sync mechanism (S2) + third sync mechanism (S3)

In addition, a synchro mechanism operating at each shift stage is as follows.

First, the first synchro mechanism S1 is operated to switch the selection between the 1-2 stage and the 5-6 stage in shifting, and the second synchro mechanism S2 is located between the 3-4 stage and the R stage. The shift is switched, and the third sync mechanism S3 is selected to increase or decrease the differential ratio output through the differential device D.

In more detail, in the first stage, as shown in FIG. 1, the driving force transmitted from the engine 10 is driven by the second clutch C2 as the second clutch C2 is fastened. It is transmitted to the input shaft 16, the driving force according to the engagement between the first stage drive gear (G-1) and the first stage driven gear (G'-1) according to the operation of the first sink mechanism (S1) is the output shaft ( 18), the driving force according to the engagement between the second differential drive gear (D-2) and the second differential driven gear (D'-2) in accordance with the operation of the third sink mechanism (S3) Output to the differential device (D). In this case, the transmission path of the power is indicated by the thick line in the figure.

As shown in FIG. 2, in the second stage, the second clutch C2 is fastened as in the first stage, and the driving force transmitted from the engine 10 is transmitted through the second clutch C2. The driving force transmitted to the second input shaft 16 and according to the engagement between the second-stage driving gear G-2 and the second-stage driven gear G'-2 according to the operation of the first sync mechanism S1. The output shaft 18 is transferred to the output shaft 18. At this time, the engagement between the first differential drive gear D-1 and the first differential driven gear D'-1 depends on the operation of the third sink mechanism S3. Driving force according to the output is output to the differential device (D). Also in this case, the transmission path of the power is indicated by the thick line in the figure.

That is, the difference between the first stage and the second stage is determined according to the engagement between the differential drive gear and the differential driven gear according to the operation direction of the third sync mechanism S3.

In addition, in the third and fourth stages, as shown in FIGS. 3 and 4, respectively, the driving force transmitted from the engine 10 according to the fastening of the first clutch C1 and the operation of the second sync mechanism S2. It is transmitted to the output shaft 18 through the first input shaft 14, the second differential drive gear (D-2) and the second differential driven gear (D2) according to the operation direction of the third sink mechanism (S3) D'-2) or the shift to the third to fourth gears is determined according to the engagement between the first differential drive gear D-1 and the first differential driven gear D'-1. Also in this case, the transmission path of the power is indicated by the thick line in the figure.

On the other hand, the driving force of the engine 10 is output to the differential device (D) in the same manner as described above in the state of the fifth to sixth stage and the reverse shift stage, which is shown in Figs. Since the detailed process thereof is the same as in the above-described steps 1 to 4, the description thereof will be omitted.

As described above, in transmitting the same level of driving force generated from the engine 10 to the input shaft of the transmission, six gear ratios can be realized even by three gears installed on the input shaft, thereby greatly reducing the total length of the transmission. In addition, the first clutch C1 and the second clutch C2 provided between the main input shaft 12 and the first input shaft 14 to the second input shaft 16 and the first to third sync mechanisms. By appropriately controlling the operations of (S1, S2, S3), it is possible to skip shifts such as 6 → 4, 5 → 3, 3 → 1.

As described above, according to the double clutch transmission according to the present invention, the driving force is transferred from the main input shaft 12 directly connected to the engine 10 to the first input shaft 14 and the second input shaft 16. In addition, by appropriately adjusting the operation of the first to third sync mechanisms (S1, S2, S3), it is possible to output at multiple speed ratios.

In particular, since the driving force output according to the operation of the third sync mechanism S3 installed in the differential device D can be reduced or reduced, six gear ratios can be realized even by installing three types of drive gears on the input shaft. Therefore, there is an advantage that can greatly reduce the overall length of the transmission. In addition, through the operation of the third sink mechanism (S3) installed in the differential device (D) there is an effect that can be increased or decreased the driving force when reversing.

The first clutch C1, the second clutch C2, and the first to third sync mechanisms S1, which are provided between the main input shaft 12, the first input shaft 14, and the second input shaft 16. By appropriately controlling the operations of S2 and S3, skipping shifts such as 6 → 4, 5 → 3, and 3 → 1 are possible.

1 is a schematic diagram showing a first speed change state in a configuration of a double clutch transmission according to the present invention;

2 to 7 are schematic views showing the paths of power transmission for each shift stage of the double clutch transmission shown in FIG. 1.

<Description of Symbols for Main Parts of Drawings>

10-engine 12-main input shaft

14-first input shaft 16-second input shaft

18-output shaft

Claims (6)

A main input shaft installed to receive a driving force from the engine; A solid first input shaft disposed coaxially to transmit power through the main input shaft and the first clutch; A hollow second input shaft installed coaxially from an outer circumference of the first input shaft while transmitting power through the main input shaft and the second clutch; A plurality of drive gears installed to rotate integrally with the first input shaft and the second input shaft, respectively; An output shaft having a plurality of driven gears meshed with the plurality of drive gears while being installed at a position opposite to the first input shaft; A differential ratio variable drive gear installed in the output shaft to vary the differential gear ratio between the differential devices interlocked with the output shaft, and differential ratio variable driven gears installed in the differential device; And a plurality of synchro mechanisms provided for power transmission between the output shaft and the driven gears and the differential ratio variable driven gears. The method of claim 1, The main input shaft is a double clutch transmission, characterized in that directly connected to the crank shaft of the engine. The method of claim 1, The drive gears may include a 3-4 stage drive gear and a reverse drive gear installed on the first input shaft; A double clutch transmission, characterized in that consisting of a 1-2 stage drive gear and 5-6 stage drive gear installed on the second input shaft. The method of claim 1, The driven gears are installed on the output shaft, the 3-4 stage driven gear meshed with the 3-4 stage drive gear, the 1-2 stage driven gear meshed with the 1-2 stage drive gear, and the 5- 5. A double clutch transmission comprising: a 5-6 stage driven gear meshed with a 6-speed drive gear; and a backward driven gear meshed with said reverse drive gear. The method of claim 1, The differential ratio variable drive gears may include a first differential drive gear and a second differential drive gear installed in the output shaft, and the differential ratio variable driven gears may include a first differential driven gear and a second differential drive installed in the differential device. Double clutch transmission characterized in that consisting of a driven gear. The method of claim 1, The synchro mechanism includes a first sink mechanism provided between the 1-2 stage driven gear and the 5-6 stage driven gear, a second sync mechanism provided between the 3-4 stage driven gear and the reverse driven gear, and the first sync mechanism. A double clutch transmission comprising a third sink mechanism provided between a differential drive gear and a second differential drive gear.