KR101509983B1 - Transmission for vehicle - Google Patents

Abstract

A transmission for vehicle of the present invention prevents increase of volume and weight of the transmission by increase in diameters of driving gear and driven gear and increase in center distance between the same for obtaining strength of the driving gear formed on a hollow shaft, while forming multiple wanted change gear steps,thereby improving installability of the transmission on a vehicle, improving mileage of a vehicle, and having excellent gear change quality by overcoming reduction of gear changing sense by torque cut during gear change.

Description

[0001] TRANSMISSION FOR VEHICLE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a transmission for a vehicle, and more particularly, to a transmission structure that can overcome a torque disconnection phenomenon during shifting while utilizing a synchronous shift transmission mechanism.

Vehicle-mounted transmissions are a major challenge in the development of the number, weight, overall length, and volume of components required.

The volume of the transmission affects the mountability of the vehicle, and the weight is a factor that greatly affects the fuel efficiency of the vehicle.

On the other hand, the present invention is based on a synchronic transmission mechanism in which two transmission gears are externally engaged with each other and configured to transmit power through a transmission gear selected by a synchronizer.

The above-mentioned synchronized-gear type transmission has a torque disconnection phenomenon in which the transmission of power is interrupted during the engagement of the synchronous device in the transmission gear to release the synchronous device from the transmission that was previously in charge of transmission of power at the time of shifting This is a major cause of lowering the shift feeling, and the phenomenon of the reduction in the shift feeling due to such a cause is a big problem at the low end of about one to three stages where the vehicle speed is low, but the driver tends to feel relatively less at high speed .

FIG. 1 illustrates a structure of a transmission that has been studied in order to overcome the disadvantages of the conventional synchronous transmission as described above. The transmission includes a first input shaft 500 that receives power from the engine at all times, And a second input shaft 504 including a hollow shaft surrounding the first input shaft 500 so as to receive the power of the engine through the first input shaft 500. The second input shaft 500 is provided with a second- 2, 3, 4, 5, and 6 stages other than the two stages are disposed in the second input shaft 504, so that the first and second speeds When the second clutch 508 is engaged while disengaging the first clutch 502, the shift to the second gear can be achieved without torque disconnection. Even when the second gear and the third gear are engaged, The first clutch 502 is disengaged while releasing the second clutch 508. [ If she will allow the exclusion of torque disconnection phenomenon.

1, the power flow in which the first-stage output is formed in the transmission is indicated by a dotted line, and the power flow in which the R-stage output is formed is indicated by a solid line.

In order to secure the strength of the first-stage drive gear 510, the second input shaft 504 having the first-stage drive gear 510 is formed as a hollow shaft, When the diameter of the single-speed drive gear 510 is increased as described above, the diameter of the single-stage driven gear 512 engaged with the single-stage drive gear 510 and the inter- Must also be increased, which contributes to significantly increasing the weight and volume of the transmission.

Reference numeral 512 denotes a differential for distributing the power to both drive wheels, reference numeral 516 denotes a first output shaft, and reference numeral 518 denotes a second output shaft 520, which indicates a reverse idler shaft.

It will be appreciated that those skilled in the art will appreciate that the described embodiments are provided merely for the purpose of promoting an understanding of the background of the present invention, It will not.

JP 2004-301139 A

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems occurring in the prior art, and it is an object of the present invention to provide a hollow shaft having a large diameter and an increased axial distance between the drive gear and the driven gear, It is possible to improve the mountability of the transmission to the vehicle and to improve the fuel efficiency of the vehicle and to prevent the phenomenon of the reduction in transmission feeling due to the torque disconnection phenomenon during the shift And to provide an automotive transmission that can overcome the above-mentioned problems and achieve superior shift quality.

According to an aspect of the present invention, there is provided a vehicular transmission including:

A first input shaft directly connected to the engine;

A second input shaft formed of a hollow shaft which surrounds the first input shaft and forms a concentric shaft;

An engine clutch installed to intermittently supply power of the engine to the second input shaft;

A first output shaft disposed parallel to the first input shaft and the second input shaft, the first output shaft being provided with a first transmission gear and configured to draw power to the first output gear;

And a second transmission gear disposed parallel to the first output shaft and meshed with the first transmission gear so as to be always engaged with the first output shaft;

A first stage driven gear rotatably provided on the idler shaft;

A first drive gear and an R short-drive gear provided on the second input shaft;

An intermediate gear engaged with the first drive gear and the first-stage driven gear so as to be rotatable on the first output shaft so as to transmit first-stage power;

An R-stage driven gear rotatably installed on the idler shaft while being meshed with the R-short-speed gear;

And a 1 & R stage synchronizing device disposed between the first stage driven gear and the R stage driven gear of the idler shaft so that the first-stage driven gear or the R-stage driven gear can be connected to or released from the idler shaft .

The present invention relates to a structure for preventing the increase in the volume and weight of the transmission and the increase in the diameter of the drive gear and the driven gear due to an increase in the diameter of the drive gear and the driven gear, It is possible to improve the mountability of the transmission to the vehicle and to improve the fuel economy of the vehicle so as to overcome the phenomenon of the reduction in the transmission feeling caused by the torque disconnection phenomenon during shifting to realize an excellent shifting quality.

1 is a view showing a structure of a transmission that is being studied to overcome the disadvantages of a conventional synchronous gear type transmission;
2 is a view showing a configuration of a vehicular transmission according to the present invention,
Fig. 3 is a view schematically showing the configuration of Fig. 2 viewed in the axial direction.

2 and 3, an embodiment of a transmission for an automobile according to the present invention includes a first input shaft IN-1 directly connected to an engine E; A second input shaft IN-2 formed of a hollow shaft concentrically surrounding the first input shaft IN-1; An engine clutch EC provided so as to intermittently supply power of the engine to the second input shaft IN-2; A first output shaft T 1 disposed parallel to the first input shaft IN-1 and the second input shaft IN-2 and having a first transmission gear T 1 and a first output shaft O 2, OUT-1); And a second transmission gear T2 disposed parallel to the first output shaft OUT-1 and meshed with the first transmission gear T1 so as to be always engaged with the first output shaft OUT- (IS); A first stage driven gear P1 rotatably provided on the idler shaft IS; A first drive gear DR1 and an R-short-speed drive gear DR provided on the second input shaft IN-2; An intermediate gear rotatably mounted on the first output shaft OUT-1 to engage both the first drive gear DR1 and the first-stage driven gear P1 so as to transmit the first-stage power; An R-stage driven gear (PR) rotatably provided on the idler shaft (IS) while being meshed with the R-short driving gear (DR); Is disposed between the first stage driven gear P1 and the R stage driven gear PR of the idler shaft IS so that the first stage driven gear P1 or the R stage driven gear PR is supported on the idler shaft IS And a 1 & R stage synchronization device 1 &

That is, in implementing the first stage and the R stage, the first stage driven gear P1, the R stage driven gear PR and the 1 & R stage stage synchronizer 1 & RS are provided on the idler shaft IS, 1 to the first stage driven gear P1 through the intermediate gear of the first output shaft OUT-1 and the power from the first drive gear DR1 of the idler shaft IS- The output of the one-stage transmission stage can be taken out through the second transmission gear T2 and the first transmission gear T1 of the first output shaft OUT-1, and the implementation of the R- And the power of the R-stage driven gear PR is transmitted to the second transmission gear T2 via the first transmission gear T2, So that a diagnosis can be formed when the gear T1 is drawn out.

Accordingly, in order to secure the strength of the single-stage drive gear, the diameter of the single-stage single-drive gear and the single-stage driven gear P1 is increased and the distance between the shafts is increased to increase the volume and weight of the transmission. .

The present invention may also be applied to an internal combustion engine having a two-stage drive gear D2 rotatably provided on the first input shaft IN-1 and a second input shaft D2 connected to the first input shaft IN- , And a two-stage driven gear (P2) provided on the first output shaft (OUT-1) so as to be meshed with the two-stage drive gear (D2) do.

In order to eliminate the torque disconnection phenomenon in the first to third gear shift stages, the two-stage gear stage must be implemented through an input shaft separate from the first and third gear stages. To this end, D2 are provided on the first input shaft IN-1 and the first and third speed change stages are realized by the second input shaft IN-2.

That is, in this embodiment, the intermediate gear is made up of a three-stage driven gear P3 which is formed with the first drive gear DR1 so as to form a three-speed gear stage, so that the second input shaft IN- And the first drive gear DR1 of the first drive gear DR1.

In this embodiment, a second drive gear DR2 is integrally provided on the second input shaft IN-2, and the first output shaft OUT-1 is engaged with the second drive gear DR2 And a fourth stepped gear P4 for forming a stepped gear is provided and the first output shaft OUT-1 is provided between the third stage driven gear P3 and the fourth stage driven gear P4, And a 3 & 4 stage synchronizer 3 & 4S for connecting or disconnecting the driven gear P3 or the 4th driven gear P4 to or from the first output shaft OUT-1.

In addition to the above-described first to fourth-speed gear positions, the sixth embodiment also includes a second output shaft OUT (2) provided parallel to the second input shaft IN-2, -2)

A fifth-stage driven gear P5 provided on the second output shaft OUT-2 so as to be meshed with the first drive gear DR1 to form a fifth-speed gear stage, and a fifth-stage driven gear P5 meshed with the second drive gear DR2 Stage driven gear P6 provided on the second output shaft OUT-2 so as to form a six-speed gear stage and the five-stage driven gear P5 and six-stage driven gear P6 of the second output shaft OUT- And a 5 & 6 stage synchronizing device 5 & 6S provided between the gear P6 and connecting or disconnecting the 5th step driven gear P5 or the 6th step driven gear P6 to the second output shaft OUT- .

In this embodiment, the first output gear O1 of the first output shaft OUT-1 is engaged with a ring gear of a differential (DIFF), and the second output gear O2 And the second output gear O2 is engaged with the ring gear of the differential gear DIFF separately from the first output gear O1.

For reference, the thick dotted lines in FIGS. 2 and 3 show the power flow at the first stage of the gear stage, and the thin dotted line shows the power flow at the R stage.

The power from the first drive gear DR1 of the second input shaft IN-2 is transmitted to the third-stage driven gear P3 And the first and the second stage synchronizing devices 1 and RS fix the first stage driven gear P1 to the idler shaft IS, the power is transmitted to the first and second driven gears P1, Is transmitted from the transmission gear T2 again to the first transmission gear T1 and is drawn out through the first output gear O1 to the ring gear of the differential DIFF.

When shifting from the one-stage shift stage to the two-stage shift stage as described above, the slip control is performed in the direction of releasing the engine clutch EC while the slip control is performed in the direction of tightening the auxiliary clutch (AC) And the torque from the first and the second stage synchronizing devices 1 and RS are gradually drawn out through the first output shaft OUT-1 through the second-stage driven gear D2 and the second-stage driven gear P2 in a differential (DIFF) So that the output torque is continuously applied to the differential (DIFF) during the process, so that the torque disconnection phenomenon does not occur and the transmission feeling is excellent.

On the other hand, when shifting from the second stage to the third stage, the engine clutch EC is connected to the first output shaft OUT-1 while the three-stage driven gear P3 is connected to the third and fourth stage synchronizer 3 & The auxiliary clutch AC is slip controlled in the direction of releasing, so that the shift to the three stages is completed while exerting the phenomenon of the torque disconnection.

For the sake of reference, the remaining 4th and 5th gear shifts are performed by releasing the synchronizing device of the previous gear range and disengaging the synchronizer of the new target gear range with the engine clutch EC disengaged like a conventional general synchronous meshing mechanism And then engages the engine clutch EC again.

Therefore, in the shift steps of the 4th and 5th steps as described above, the torque disconnection phenomenon of the drive wheels inevitably occurs. However, when the vehicle is running at a high speed, The transmission feeling of the whole vehicle is felt to be greatly improved.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims It will be apparent to those of ordinary skill in the art.

E; engine
IN-1; The first input shaft
IN-2; The second input shaft
EC; Engine clutch
T1; The first transmission gear
O1; The first output gear
OUT-1; The first output shaft
T2; The second transmission gear
IS; Idler shaft
P1; 1 stage driven gear
DR1; The first drive gear
DR; R single drive gear
PR; R-stage driven gear
1 & 1 & R stage sync device
D2; 2 single drive gear
AC; Auxiliary clutch
P2; Two-stage driven gear
P3; Three-stage driven gear
DR2; The second drive gear
P4; 4-speed driven gear
3 &4S; 3 & 4 stage sync device
OUT-2; The second output shaft
P5; 5-speed driven gear
P6; 6-speed driven gear
5 &6S; 5 & 6 stage synchronous device
DIFF; Differential
O2; The second output gear

Claims (5)

A first input shaft IN-1 directly connected to the engine;
A second input shaft IN-2 formed of a hollow shaft concentrically surrounding the first input shaft IN-1;
An engine clutch EC provided so as to intermittently supply power of the engine to the second input shaft IN-2;
A first output shaft T 1 disposed parallel to the first input shaft IN-1 and the second input shaft IN-2 and having a first transmission gear T 1 and a first output shaft O 2, OUT-1);
And a second transmission gear T2 disposed parallel to the first output shaft OUT-1 and meshed with the first transmission gear T1 so as to be always engaged with the first output shaft OUT- (IS);
A first stage driven gear P1 rotatably provided on the idler shaft IS;
A first drive gear DR1 and an R-short-speed drive gear DR provided on the second input shaft IN-2;
An intermediate gear rotatably mounted on the first output shaft OUT-1 to engage both the first drive gear DR1 and the first-stage driven gear P1 so as to transmit the first-stage power;
An R-stage driven gear (PR) rotatably provided on the idler shaft (IS) while being meshed with the R-short driving gear (DR);
Is disposed between the first stage driven gear P1 and the R stage driven gear PR of the idler shaft IS so that the first stage driven gear P1 or the R stage driven gear PR is supported on the idler shaft IS 1 & R stage synchronizers (1 & RS) to allow connection or disconnection;
And a control unit for controlling the vehicle. The method according to claim 1,
A second-stage drive gear (D2) rotatably provided on the first input shaft (IN-1);
An auxiliary clutch AC connected to or disconnected from the first input shaft IN-1 of the second-stage drive gear D2;
A two-stage driven gear (P2) provided on the first output shaft (OUT-1) to engage with the second-stage drive gear (D2) to form a two-speed gear stage;
And a control unit for controlling the vehicle. The method of claim 2,
The intermediate gear is composed of a three-stage driven gear P3 configured to form a three-speed gear stage together with the first drive gear DR1;
A second drive gear DR2 is integrally provided on the second input shaft IN-2;
The first output shaft OUT-1 is provided with a four-stage driven gear P4 meshing with the second drive gear DR2 to form a four-speed gear stage;
The first output shaft (OUT-1) is provided between the third stage driven gear (P3) and the fourth stage driven gear (P4), and the third stage driven gear (P3) or the fourth stage driven gear (P4) A 3 & 4-stage synchronizing device (3 & 4S) connected to or disconnected from the output shaft (OUT-1)
. The method of claim 3,
A second output shaft (OUT-2) provided parallel to the second input shaft (IN-2);
A fifth-stage driven gear (P5) provided on the second output shaft (OUT-2) to engage with the first drive gear DR1 to form a five-speed gear stage;
A six-speed driven gear P6 provided on the second output shaft OUT-2 to mesh with the second drive gear DR2 to form a six-speed gear stage;
Is disposed between the fifth-stage driven gear (P5) and the sixth-stage driven gear (P6) of the second output shaft (OUT-2), and the fifth-stage driven gear (P5) 5 & 6 stage synchronizer (5 & 6S) connected to or disconnected from the output shaft (OUT-2);
And a control unit for controlling the vehicle. The method of claim 4,
The first output gear O1 of the first output shaft OUT-1 meshes with a ring gear of a differential (DIFF);
A second output gear O2 is provided on the second output shaft OUT-2;
The second output gear O2 is engaged with the ring gear of the differential (DIFF) separately from the first output gear O1
.

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