KR20140034550A - Device for transmission operation - Google Patents

Abstract

Disclosed is a device for operating a transmission. The device includes a lever plate which moves in linking with a shift lever and has a mount groove, an elastic unit which is inserted into the mount groove and provides supporting force by elastic force, an elastic ring which is supported by the elastic unit and can be expanded and contracted in a radial direction, and a bullet which is supported with the elastic ring by the elastic unit and can be inserted into the elastic ring, wherein the bullet and the elastic ring are pressed in the longitudinal direction of the mount groove and one of the bullet and the elastic ring comes in contact with the inner peripheral surface of the mount groove by being expanded in a radial direction, thereby removing an interval from the mount groove.

Description

Gear shifting mechanism {DEVICE FOR TRANSMISSION OPERATION}

The present invention relates to a shift operation mechanism capable of imparting a sense of theft in a shift lever operation of a driver.

In general, a vehicle transmission is classified into a manual transmission, an automatic transmission, and a continuously variable transmission according to a shifting method, and is a device capable of converting torque and rotation of an engine according to driving conditions.

Such a transmission performs a shift by operating the shift lever, but if the shift lever's operability is not good, the shift operation of the driver may not be properly transmitted to the transmission, and the merchandise of the vehicle may be deteriorated due to an uncomfortable shift feeling.

Figure 1 is a perspective view showing a shift operation mechanism, Figure 2 is a view showing the installation groove of the shift operation mechanism of Figure 1, the conventional transmission mechanism in order to give a shift feeling when operating the shift lever 10, the elastic portion ( 20), using the uneven groove (G) gave a sense of theft. Specifically, the bullet structure has an elasticity in which an installation groove 32 is formed in the lever plate 30 which moves integrally with the shift lever, and a bullet 10 is provided in the installation groove 32 and supports the bullet 10. Part 20 was seated. On the other hand, the uneven groove (G) is provided so as to face the bullet 10, while the lever plate 30 is moved while the bullet 10 moves in the uneven groove (G) was given the sense of theft.

However, as can be seen in Figure 2, the shift mechanism has a gap between the inner diameter of the installation groove 32 formed in the lever plate 30 and the outer diameter of the bullet 10 due to the accumulation of gaps in the assembly, which is a play when operating the shift lever Due to the occurrence, the shifting feeling was reduced, which gave the driver a feeling of shifting smoothness.

Therefore, in the shift lever operating mechanism, there is a need for a technology capable of providing a smooth shift feeling to the driver by removing the gap between the bullet hole 10 and the installation hole 32 formed in the lever plate 30.

It should be understood that the foregoing description of the background art is merely for the purpose of promoting an understanding of the background of the present invention and is not to be construed as an admission that the prior art is known to those skilled in the art.

The present invention has been proposed to solve this problem, in the shift operation mechanism for imparting a sense of theft, by removing the gap between the installation groove formed in the lever plate and the bullet inserted into the installation groove provides a smooth shift feeling to the driver. There is a purpose.

A shift manipulation mechanism according to the present invention for achieving the above object is a lever plate which moves in conjunction with a shift lever and an installation groove is formed; An elastic part inserted into the installation groove and providing a support force by an elastic force; An elastic ring supported by the elastic part and formed of a deformable structure capable of expanding and contracting in a radial direction; And a bullet that is supported by the elastic part together with the elastic ring and formed to fit with the elastic ring, wherein the bullet and the elastic ring are pressurized with each other along a longitudinal direction of the installation groove, thereby either Is radially expanded so as to be in contact with the inner circumferential surface of the installation groove so as to eliminate the gap with the installation groove.

The bullet is formed so that the elastic ring can be inserted, the insertion groove is formed in the portion that the elastic ring is inserted, the outer diameter of the elastic ring is formed larger than the outer diameter of the insertion groove, the bullet and the elastic ring when the bullet is pressed against each other the radius of the bullet It may be formed to expand in the direction.

The insertion groove formed in the bullet may be formed to taper to a portion into which the elastic ring is fitted.

The bullet hole may be formed with a groove in the longitudinal direction along the outer circumferential surface of the portion in which the elastic ring is fitted.

The elastic ring may be a structure in which elastic deformation is possible as a C ring cut in a predetermined portion.

The elastic ring may have an extension extending to taper toward the bullet.

The bullet may extend through the elastic ring and the elastic part, and a stepped protrusion may be formed on the outer circumferential surface of the exposed portion so as to contact the inner circumferential surface of the installation groove.

The bullet is formed to be fitted inside the elastic ring, the elastic ring is formed to extend toward the bullet and tapered toward the outer circumferential surface of the bullet so that the elastic ring expands in the radial direction when the bullet and the elastic ring are pressed against each other. Can be.

The shift operation mechanism having the structure as described above is provided with a bullet, an elastic portion and an elastic ring in the installation groove formed in the lever plate, so that any one of the bullet and the elastic ring is expanded to contact the inner peripheral surface of the installation groove when the shift lever is operated. Formation eliminates the gap between the bullet and the mounting groove, providing a comfortable shift to the driver.

1 is a perspective view showing a shift operation mechanism.
Figure 2 is a view showing the installation groove of the shift operation mechanism shown in FIG.
3 is a perspective view showing a shift operating mechanism according to a first embodiment of the present invention;
Figure 4 is a view showing a bullet, an elastic ring, the elastic portion of the shift operation mechanism shown in FIG.
5 is a view showing that the elastic ring is fitted to the bullet of the shift control mechanism shown in FIG.
6 is a view showing that the bullet of the shift control mechanism according to the second embodiment of the present invention is fitted into the elastic ring.

Hereinafter, with reference to the accompanying drawings looks at with respect to the shift operating mechanism according to a preferred embodiment of the present invention.

Figure 3 is a perspective view showing a shift operating mechanism 1000 according to an embodiment of the present invention, Figure 4 is a bullet 400 inserted into the installation groove 120 of the shift operating mechanism shown in Figure 3, an elastic ring ( 300), a view showing the elastic portion 200, the present invention moves in conjunction with the shift lever and the lever plate 100 is formed with an installation groove 120; An elastic part 200 inserted into the installation groove 120 and providing a support force by an elastic force; An elastic ring 300 supported by the elastic part 200 and formed of a deformable structure capable of expanding and contracting in a radial direction; And a bullet 400 supported by the elastic part 200 together with the elastic ring 300 and formed to fit with the elastic ring 300. The bullet 400 and the elastic ring 300 are included. Is pressed by each other along the longitudinal direction of the installation groove 120, any one of the two is formed so as to remove the gap with the installation groove 120 by contacting the inner circumferential surface of the installation groove 120 is radially expanded It features.

As can be seen in Figure 3, the shift operation mechanism 1000 is provided with a lever plate 100 to move in conjunction with the shift lever, the bullet 400 and the inside of the installation groove 120 formed in the lever plate 100 Supporting elastic portion 200 is provided. Here, when the lever plate 100 moves according to the shift lever operation, the bullet 400 is provided inside the shift lever housing and provides a sense of theft to the driver while riding over the uneven portion G in which mountains and valleys are continuously repeated.

However, an assembling gap is generated between the installation groove 120 and the bullet 400 formed in the lever plate 100 to transmit an uncomfortable shift feeling to the driver due to the clearance between the installation groove 120 and the bullet 400 during the shift operation. Can be.

In order to solve this problem, the shift operation mechanism 1000 of the present invention is provided with a bullet 400 and an elastic ring 300 inside the installation groove 120 formed in the lever plate 100 moving in conjunction with the shift lever. To be supported by the elastic portion 200.

Here, the elastic ring 300 is formed in a deformable structure to be expanded and contracted in the radial direction, bullet 400 is elastic with the bullet 400 is formed by the deformable structure to the portion fitted with the elastic ring 300 When the ring 300 is fitted to each other, one of the two is in contact with the installation groove 120.

Specifically, in the present invention, the lever plate 100 is moved by the shift lever operation so that the bullet 400 passes over the uneven portion G, and the elastic ring 300 and the bullet 400 are elastic portions ( By being supported by the 200, the bullet 400 and the elastic ring 300 are pressed to each other along the longitudinal direction of the installation groove 120.

At this time, as the bullet 400 is pressed together with the elastic ring 300, the elastic ring 300 is fitted in the direction supported by the elastic part 200, so that the elastic ring 300 of the bullet 400 is fitted. It may be deformed to open in the radial direction to be in contact with the inner circumferential surface of the installation groove 120.

On the other hand, the bullet 400 and the elastic ring 300 is pressed by each other by the bullet 400 is inserted into the inner ring of the elastic ring 300, the elastic ring 300 is expanded in the radial direction to install the groove ( 120 may be in contact with the inner circumferential surface.

According to the present invention having the structure as described above, when the bullet 400 and the elastic ring 300 are pressed to each other, the bullet 400 and the elastic ring 300 are fitted to each other, and one of the two is deformed in a radial direction to install the groove 120. By removing the gap between the bullet 400 and the installation groove 120 by being in contact with the inner circumferential surface of the) to completely eliminate the uncomfortable shifting feeling caused by the play during the shifting and to provide an excellent shifting feeling to the driver.

Referring to the embodiment of the present invention as shown in detail, Figure 5 is a view showing that the elastic ring 300 is fitted to the bullet 400 of the shift control mechanism 1000 shown in FIG. Bullet 400 is formed so that the elastic ring 300 is fitted, the insertion groove 420 is formed in the portion in which the elastic ring 300 is fitted, the outer diameter of the elastic ring 300 of the insertion groove 420 Make it larger than the outer diameter.

Thus, when the bullet 400 and the elastic ring 300 is pressed against each other, the bullet 400 may be expanded in the radial direction by the elastic ring 300 is inserted.

This structure is a structure in which the bullet 400 is in direct contact with the inner circumferential surface of the installation groove 120, the bullet 400 is formed so that the elastic ring 300 is fitted in the direction supported by the elastic portion 200 bullet The insertion groove 420 is formed in the portion 400 to which the elastic ring 300 is fitted. However, since the outer diameter of the insertion groove 420 is smaller than the outer diameter of the elastic ring 300, when the elastic ring 300 is fitted to the bullet 400, the bullet 400 is installed by the elastic ring 300. It may be to open toward the inner circumferential surface of 120.

Here, as the bullet 400 is inserted into the elastic ring 300 into the insertion groove 420, a portion into which the elastic ring 300 of the bullet 400 is fitted is opened toward the inner circumferential surface of the installation groove 120, The insertion groove 420 may be formed in a shape advantageous to deformation by performing a rounding process in the direction in which the elastic ring 300 is fitted.

In addition, the insertion groove 420 formed in the bullet 400 may be formed to taper to a portion into which the elastic ring 300 is fitted.

As can be seen in Figure 5, the insertion groove 420 formed in the bullet 400 is formed to taper to the portion that the elastic ring 300 is inserted into the elastic ring 300 by the insertion groove 420 formed in the bullet 400 The inclined surface can be guided to be inserted smoothly, and the durability can be increased by preventing excessive friction between the elastic ring 300 and the insertion groove 420 of the bullet 400.

On the other hand, as shown in Figure 4, the bullet 400 may be formed in the groove 440 in the longitudinal direction along the outer circumferential surface of the portion in which the elastic ring 300 is fitted.

Bullet 400 of the present invention is formed so that the elastic ring 300 can be fitted, the portion that the elastic ring 300 of the bullet 400 is fitted by being pressed together in the longitudinal direction of the installation groove 120 It is formed to open toward the inner circumferential surface of the installation groove (120).

Further, the bullet 400 is formed toward the inner circumferential surface of the installation groove 120 by the elastic ring 300 by forming a groove 440 in the longitudinal direction along the outer circumferential surface of the portion where the elastic ring 300 is fitted at regular intervals. It can be formed into an advantageous structure that can be expanded.

Here, the groove 440 in the longitudinal direction formed in the bullet 400 will be preferable to form a more favorable condition for deformation by the rounding treatment in the direction in which the elastic ring 300 is fitted.

On the other hand, the elastic ring 300 is a structure that can be elastically deformed as a C ring cut part. According to the present invention, the bullet 400 and the elastic ring 300 are pressurized to each other so that the bullet 400 and the elastic ring 300 are fitted to each other. At this time, the elastic ring 300 is deformed so that the bullet 400 is expanded in the radial direction by being fitted to the bullet 400 or the bullet 400 is inserted into the elastic ring 300 by the elastic ring 300 It is formed to expand in the radial direction.

That is, when the elastic ring 300 of the present invention is fitted to the bullet 400, the elastic ring 300 is contracted so that the elastic ring 300 is smoothly fitted to the bullet 400, and the bullet 400 excessively. It can prevent it from expanding. In addition, when the bullet 400 is fitted into the elastic ring 300, it is preferable to apply a C ring that is easy to expand and contract by applying a structure capable of elastic deformation in which the elastic ring 300 should be expanded. will be.

On the other hand, as shown in Figure 5, the elastic ring 300 is preferably such that the extension portion 320 is formed to be tapered toward the bullet 400.

In the present invention, the elastic ring 300 is fitted to the bullet 400 by the bullet 400 and the elastic ring 300 is pressed to each other along the longitudinal direction of the installation groove 120 during the shift operation, the elastic ring 300 The elastic ring 300 may be smoothly fitted to the bullet 400 by forming an extension part 320 extended to taper toward the bullet 400.

On the other hand, as shown in Figure 4, the bullet 400 extends through the elastic ring 300 and the elastic portion 200, the stepped 340 is protruded on the outer peripheral surface of the exposed portion through the installation groove It may be formed in contact with the inner peripheral surface of the (120).

As such, the bullet 400 forms a step 340 in a portion extending through the elastic ring 300 and the elastic portion 200, so that the bullet 400 swings in the direction of the inner circumferential surface of the installation groove 120 during the shift operation. It can be applied as a stable structure without this. Therefore, the bullet 400 during the shift operation may smoothly fall over the uneven portion G without stopping, thereby providing a smoother shift feeling to the driver.

6 is a view showing that the bullet 400 of the shift control mechanism illustrated in FIG. 3 is fitted into the elastic ring 300, so that the bullet 400 may be fitted into the elastic ring 300. The elastic ring 300 is formed to extend toward the bullet 400 and to taper toward the outer circumferential surface of the bullet 400, so that the elastic ring 300 is pressed when the bullet 400 and the elastic ring 300 are pressed to each other. It may be formed to expand in the radial direction.

This structure is a structure in which the elastic ring 300 is in direct contact with the inner circumferential surface of the installation groove 120 to remove the gap. When the bullet 400 and the elastic ring 300 are pressed together, the bullet 400 is elastic ring ( The elastic ring 300 is formed to expand in the radial direction by being fitted into the inside of the 300.

Here, the bullet 400 may be formed to be easily inserted into the elastic ring 300 by being formed so that the portion fitted to the elastic ring 300 is tapered toward the elastic ring 300.

In addition, the elastic ring 300 extends toward the bullet 400 and is formed to taper toward the outer circumferential surface of the bullet 400, thereby inducing the bullet 400 to be smoothly inserted into the elastic ring 300.

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.

100: lever plate 200: elastic portion
300: elastic ring 400: bullet

Claims (8)

A lever plate 100 moving in conjunction with a shift lever and having an installation groove 120 formed therein;
An elastic part 200 inserted into the installation groove 120 and providing a support force by an elastic force;
An elastic ring 300 supported by the elastic part 200 and formed of a deformable structure capable of expanding and contracting in a radial direction; And
And a bullet 400 supported by the elastic part 200 together with the elastic ring 300 and formed to fit with the elastic ring 200.
Since the bullet 400 and the elastic ring 300 are pressed to each other along the longitudinal direction of the installation groove 120, any one of the two is expanded in the radial direction to contact the inner peripheral surface of the installation groove 120, the installation groove Shifting mechanism, characterized in that formed to remove the gap with the 120. The method according to claim 1,
The bullet 400 is formed so that the elastic ring 300 is fitted, the insertion groove 420 is formed in the portion in which the elastic ring 300 is fitted, the outer diameter of the elastic ring 300 is inserted groove 420 When the bullet 400 and the elastic ring 300 is pressed against each other by being formed larger than the outer diameter of the shifting mechanism, characterized in that the bullet 400 is formed to expand in the radial direction. The method according to claim 2,
The insertion groove 420 formed in the bullet 400 is shifting operation mechanism, characterized in that formed to taper to the portion to which the elastic ring 300 is fitted. The method according to claim 1,
The bullet 400 is a shift operation mechanism characterized in that the groove in the longitudinal direction along the outer circumferential surface of the portion to which the elastic ring 300 is fitted to form a predetermined interval. The method according to claim 1,
The elastic ring 300 is a shift operation mechanism, characterized in that the structure is capable of elastic deformation as a C ring cut part. The method according to claim 1,
The elastic ring 300 is a shift operation mechanism, characterized in that the extension portion 320 is formed to be extended to taper toward the bullet (400). The method according to claim 1,
The bullet 400 extends through the elastic ring 300 and the elastic part 200, and a stepped protrusion is formed on the outer circumferential surface of the exposed portion so as to contact the inner circumferential surface of the installation groove 120. Gear shifting mechanism. The method according to claim 1,
The bullet 400 is formed to be fitted inside the elastic ring 300, the elastic ring 300 is formed to extend toward the bullet 400 and to taper toward the outer peripheral surface of the bullet 400 bullet 400 When the elastic ring 300 and the pressure is pressed against each other, the shifting mechanism, characterized in that the elastic ring 300 is formed to expand in the radial direction.

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