KR20200012420A - Device for connecting damper and clutch of vehicle - Google Patents

Abstract

The present invention relates to a device for connecting a damper and a clutch of a vehicle, wherein coupling torque is increased by installing a spring corresponding to all spring cover parts of a connector cover, and the same surface contact force acts around the entire circumference by an elastic washer and a cover washer on both sides of the connector cover, thereby improving the operational stability of the connector cover.

Description

Device for connecting damper and clutch of vehicle

The present invention relates to a damper and a clutch connecting device of a vehicle, and more particularly, a damper and a clutch connection of a vehicle for transmitting engine power transmitted to a damper by connecting a damper connected to an engine output shaft and a clutch connected to a transmission input shaft. Relates to a device.

The clutch cuts the power input to the transmission during the shifting operation of the transmission to ensure smooth shifting and protects the gears of the transmission.

The damper is provided with a torsion spring therein to absorb relative rotational fluctuations between the input side and the output side, thereby protecting them by absorbing the impact due to the difference in rotational speed between the engine and the transmission.

As shown in FIG. 1, the damper 100 is provided with a ring gear for starting at an outer circumference thereof and has a connection device 300 therein. The clutch 200 is a dual clutch applied to the DCT, and a spline hole for connection with the connection device 300 is formed at one side of the connection plate 210. The spline hole is a spline tooth 211 is formed on the inner peripheral surface of the hole.

The damper 100 is also referred to as an external damper corresponding to another damper provided in the clutch 200. The damper 100 is provided with a drive plate (not shown) that is elastically supported in a rotational direction by a pair of torsion springs, and the connection device 300 is mounted on the drive plate.

The connection device 300, as shown in Figures 2 to 4. And a connector 310 having a ring shape, the connector 310 being riveted to the drive plate (fixing hole 312; see FIG. 2), and a spline tooth 311 formed on an outer circumferential surface thereof so that the clutch 200 is formed. Inserted into the spline hole formed in the connecting plate 210 of the). That is, the damper 100 and the clutch 200 are connected to each other in a spline structure so that the rotational force is transmitted.

On the other hand, since there is a backlash between the spline teeth 311 of the connector 310 and the spline teeth 211 of the clutch 200 connecting plate 210, the damper 100 side and the clutch 200 side in the power transmission process. If a difference occurs in the rotational speed of the teeth on both sides collision and noise and spline teeth 211,311 damage occurs.

In order to prevent this, the connector cover 320 that is elastically supported by the spring 330 is installed. The connector cover 320 is installed in the circumferential direction in a small amount on the connector 310, the spring 330 is supported by one end of the rivet 340 fixed to the connector 310, the other end is the connector cover 320 It is to push the projection 320a formed on the outer periphery. Spring seats 331 and 332 are provided at both ends of the spring 330, so that the contact state between the rivet 340 and the protrusion 320a is firm, so that the operation of the spring 330 is performed smoothly.

The connector cover 320 is formed with a spring cover part 321 to cover one side of the spring 330 installed in the connector 310, the spring cover part 321 is bent downward after extending radially outward. Tooth contact 322 is formed.

In addition, the connector cover 320 is constrained in the axial direction by the rectangular rivet 350 to the connector 310. The square rivet 350 has a lower end fixed to the connector 310, and the head restrains the axial movement of the connector cover 320 as the head has a rectangular flat plate shape.

In addition, an elastic washer 360 is interposed between the connector 310 and the connector cover 320 to reduce the axial flow of the connector cover 320 so that the circumferential operation of the connector cover 320 is made stable. have.

When the damper 100 and the clutch 200 are splined together, the tooth contact portion 322 of the connector cover 320 is supported on one side of the spline tooth 211 on the clutch 200 side, and thus the opposite of the support surface. The spline teeth 311 of the connector 310 and the spline teeth 211 of the connecting plate 210 are brought into close contact with each other in the direction to prevent tooth collision due to backlash.

The conventional connection device 300 as described above has the following problems.

The fastening torque of the connector 310 and the connecting plate 210 is determined by the elastic force of the spring 330.

On the other hand, fixing holes 312 for fixing the connector 310 to the drive plate of the damper 100 by rivets (not shown) are formed at regular intervals in the circumferential direction of the connector 310 (total eight places).

The spring cover part 321 of the connector cover 320 is positioned in each section between the fixing holes 312, and the connector cover 320 is connected to the connector cover 320 as well as the spring cover part 321 in a section between the fixing holes 312. The square rivets 320 for mounting on the 310 are also disposed. Square rivet 320 is installed in a total of four places are installed one by one in the interval between the fixing hole 312.

However, in the case of the section between the fixing hole 312 where both the square rivet 320 and the spring cover portion 321 are disposed, the circumferential direction of the spring cover portion 321 is determined by the circumferential length occupied by the head of the square rivet 320. The length is inevitably reduced, and thus the spring 330 may not be installed at the lower portion of the reduced spring cover portion 321. That is, only half of the spring cover 321 is actually installed with the spring 330, and the other half of the spring cover 321 serves only as a connecting part for forming the tooth contact portion 322. .

Therefore, the spring reaction force acting on the connector cover 320 is not sufficient, and there is a problem that the tightening torque of the damper 100 and the clutch 200 decreases.

In addition, in the conventional connector 300, the connector cover 320 has only one side of the connector 310 in contact with the elastic washer 360 so as to be in contact with each other. There was a problem that the operation stability is lowered. Although some sections of the other side of the connector cover 320 are in contact with the head of the square rivet 350, the range is very small compared to the entire circumferential section and thus did not help improve the circumferential operation stability of the connector cover 320.

Republic of Korea Patent Publication No. 2011-0069687 (Published June 23, 2011)

Accordingly, the present invention has been made to solve the above problems, the object of the present invention is to provide a damper and clutch connection device of the vehicle to increase the tightening torque of the damper and the clutch, the operation stability of the connector cover can be improved. have.

The present invention for achieving the above object, the spline teeth form is fixed to the drive plate of the damper and coupled to the spline teeth formed on the coupling plate of the clutch on the outer peripheral surface, and the circumferential flow in the connector via the rivet Spring cover parts are formed to be mounted to each other, and the spring cover parts are formed at equal intervals in the circumferential direction. A plurality of springs to be applied, an elastic washer installed between the connector and the connector cover and being in surface contact with the circumferential circumference of one side of the connector cover, and installed on the other side of the connector cover via the rivet. A cover that is in surface contact with the other side of the connector cover over the entire circumference It includes.

In the connector, a plurality of fixing holes used to fix the connector to the drive plate are formed at equal intervals in the circumferential direction, and the spring cover part and the rivet are disposed in all the areas between the fixing holes, and inside the spring cover part. The spring is installed.

A plurality of protruding pieces are formed on the outer circumference of the cover washer, a rivet hole is formed in the protruding piece, the rivet is inserted into the rivet hole, and the cover washer is fixed to the connector. Axial position is limited.

The spline teeth of the connector may include a first chamfer and a second chamfer having opposite inclination angles at both edges of the lateral end coupled with the spline teeth of the clutch connecting plate.

The first chamber is formed with an inclined surface that is relatively gentle compared to the second chamber, and the second chamber is formed with an inclined surface that is relatively rapid compared to the first chamber.

According to the present invention as described above, the size of the connector cover mounting rivet head can be reduced to form the circumferential length of all the spring cover portion to a size sufficient to accommodate the spring so that the spring can be installed inside all the spring cover portions do.

Accordingly, the number of springs is increased so that the spring force applied to the connector cover is greatly increased, thereby increasing the tightening torque of the connector of the damper and the connection plate of the clutch. This allows the damper and clutch to maintain a more solid connection and improves noise and tooth durability degradation caused by spline interdental backlash.

In addition, the cover washer is provided on one side of the connector cover corresponding to the elastic washer, so that both sides of the connector cover are in surface contact over the entire circumferential range. Therefore, not only the axial flow of the connector cover is further suppressed, but also the surface contact force acting on both sides of the connector cover is the same, thereby improving the operational stability of the connector cover.

In addition, the present invention reduces the assembling load acting when assembling the spline teeth of the connecting plate by the two-side chamfer structure of the coupling direction side edge of the spline teeth of the connector. That is, the spline coupling of the damper and the clutch can still be easily achieved by being able to offset the increase in the assembly load by increasing the tightening torque of the connecting device according to the present invention.

1 is an exploded perspective view of a connection portion of the damper and the clutch.
Figure 2 is a plan view of a damper and clutch connection device according to the prior art.
Figure 3 is an exploded perspective view of the connecting device according to the prior art.
Figure 4 is a cross-sectional view of the spring installation of the connecting device according to the prior art.
5 is a plan view of a damper and clutch connection device according to the present invention.
6 is an exploded perspective view of the connection device according to the present invention.
7 is a cross-sectional view of the spring installation of the connecting device according to the present invention.
FIG. 8A is a partially enlarged perspective view of a connector which is a main component of the connecting device, and FIGS. 8A and 8C are cross-sectional views taken along line AA of the connector, showing a state in which the connector of the damper and the connecting plate of the clutch are coupled to each other. (B) is a sectional view of the spline teeth according to the prior art, and (c) is a sectional view of the spline teeth according to the present invention.

As the present invention allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the written description. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. The thickness of the lines or the size of the components shown in the accompanying drawings may be exaggerated for clarity and convenience of description.

In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary depending on the intention or precedent of a user or an operator. Therefore, definitions of these terms should be made based on the contents throughout the specification.

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

Figure 5 is a plan view of a damper and clutch connection device according to the invention, Figure 6 is an exploded perspective view of the connection device according to the invention, Figure 7 is a cross-sectional view of the spring installation of the connection device according to the present invention and Like parts have been given the same reference numerals.

5 to 7, the damper and clutch connection device of the vehicle according to the present invention is a connector 310, connector cover 320, spring 330, elastic washer 360, cover washer 370 And a rivet 340 supporting one end of the spring 330, and a rivet 380 for mounting the elastic washer 360, the connector cover 320, and the cover washer 370 to the connector 310.

Connector 310 is a ring-shaped component is formed on the outer circumferential surface of the spline teeth 311 which is coupled to the spline teeth 211 of the coupling plate 210 of the clutch 200. In addition, the connector 310 has a fixing hole 312 is formed at a predetermined interval in the circumferential direction, the drive plate provided inside the damper 100 via a rivet (not shown) inserted through the fixing hole 312 It is fixed to (not shown).

On the outer circumferential surface of the connector 310, there is a blank area (a space missing one tooth 311) in which the spline teeth 311 are not formed at regular intervals, and the tooth contact portion of the connector cover 320 will be described later in this blank area. 322 is located.

The connector cover 320 is a ring-shaped component mounted on one side of the connector 310 via a plurality of rivets 380. However, the rivet 380 may not restrain the connector cover 320 completely, but may flow in a small amount in the circumferential direction and prevent the rivet 380 from deviating in the axial direction.

The rivet 380 has a smaller round head shape in the circumferential area of the connector cover 320 than the conventional square rivet 350.

The connector cover 320 is formed with a spring cover part 321 at regular intervals, and a portion of the end portion of each spring cover part 321 extends downwards and is bent downward to form a tooth contact portion 322.

The tooth contact portion 322 is in contact with and supported by the spline teeth 211 of the connection plate 210 when the connector 310 and the connection plate 210 are splined. Accordingly, the spline teeth 311 of the connector 310 and the spline teeth 211 of the connecting plate 210 are brought into close contact with each other in the opposite direction of the supporting surface, so that tooth collision due to backlash is prevented. That is, when the connector cover 320 is pushed by the spring 330, the tooth contact portion 322 pushes the spline teeth 211 of the connecting plate 210 toward the spline teeth 311 of the connector 310, and thus, To remove the gap.

The spring 330 is installed between the connector 310 and the connector cover 320, and the spring 330 is installed at positions corresponding to all the spring cover portions 321 formed in the connector cover 320. That is, the spring 330 is installed inside all the spring cover parts 321.

Both ends of the spring 330 are provided with spring seats (331, 332) for stabilizing the end support state of the spring. One end of the spring 330 is supported by the rivet 340 is fixed to the connector 310, the other end is supported by the connector cover 320. More specifically, it is supported by the protrusion 320a protruding radially outward from the outer circumferential surface of the connector cover 320. The spring 330 is covered by the spring cover part 321 to prevent the spring 330 from being separated from the installation position on the connector 310.

The elastic washer 360 is a ring-shaped part interposed between the connector 310 and the connector cover 320 and has elasticity in the axial direction by the bent shape of the cross section. Therefore, the connector cover 320 may be pushed in the opposite direction with respect to the connector 310. The elastic washer 360 is in surface contact with the entire circumferential direction of one side of the connector cover 320 (refer to FIG. 6).

The cover washer 370, which is a ring-shaped component, is provided on the other side of the connector cover 320 (upper surface in FIG. 6) corresponding to the elastic washer 360.

The cover washer 370 has a flat cross section and does not have elasticity in the axial direction. Protruding pieces 371 are formed at regular intervals along the outer circumference, and rivet holes 372 are formed in each of the protruding pieces 371. The rivet hole 380 for mounting the connector cover 320 is inserted through the rivet hole 372 to be riveted to the connector 310. That is, the cover washer 370 is mounted to the connector 310 in a state in which the cover washer 370 cannot be axially separated by the same rivet 380 as the connector cover 320. The rivet 380 is inserted into the groove between the protrusions formed on the outer circumference of the elastic washer 360 in the same manner as the elastic washer 360. Both the elastic washer 360 and the cover washer 370 are mounted in a state where the flow in the circumferential direction is impossible by the rivet 380.

The cover washer 370 is limited in the axial position by the head of the rivet 380. On the other hand, one side of the cover washer 370 is circumferential because the elastic washer 360 acts on the cover washer. It is in close contact with the other side of the connector cover 320 over the whole.

Therefore, both sides of the connector cover 320 are brought into front contact with the elastic washer 360 and the cover washer 370, respectively, and the same surface contact force (surface pressure) acts on both sides of the connector cover 320, thereby providing a connector cover 320. Circumferential operation stability of the) is effective. That is, it is stably rotated in the state which is parallel with respect to the connector 310 exactly.

On the other hand, as described above, the rivet 380 for mounting the connector cover 320 is a rivet having a conventional circular head shape, compared to the square rivet 350 used in the conventional connector cover mounting of the connector cover 320. The range of the circumference is small. Conventionally, a square rivet is required to press a wider area of the connector cover 320 with rivets, but in the present invention, the cover washer 370 presses the entire circumference of the connector cover 320, so that it may be replaced with a general rivet.

As the circumferential area occupied by the rivet 380 is reduced as described above, all the spring cover parts 321 actually cover the spring 330 while installing the rivet 380 in the area between all the fixing holes 312 in the connector 310. It may be formed to have an acceptable circumferential length.

Accordingly, the number of springs 330 that provide the elastic force to the connector cover 320 is doubled, so that the spline teeth 311 of the connector 310 and the spline teeth of the connection plate 210 by the connector cover 320 are increased. The adhesion of the damper 100 and the clutch 200 is increased by greatly improving the adhesion of the 211.

Therefore, not only the connection state between the damper 100 and the clutch 200 is firm, but also the engine power can be transmitted to the transmission more stably.

On the other hand, when the tightening torque is increased as described above, the assembly of the damper 100 and the clutch 200 may be somewhat difficult. In other words, the force required to couple the spline teeth 311 of the connector 310 to the spline teeth 211 of the connection plate 210 is increased.

To solve this problem, the spline teeth 311 of the connector 310 may be formed as shown in FIGS. 8A and 8C.

The spline teeth 311 of the conventional connector is composed of a single chamfer 311a made of one inclined surface, as shown in Fig. 8 (b), the spline teeth 311 of the connector according to the present invention has both corners of the coupling direction It is composed of two chamfers having different inclination angles, that is, the first chamfer 311b and the second chamfer 311c.

As shown in FIG. 8, the first chamber 311b is formed of a relatively inclined surface relative to the second chamber 311c, and the second chamber 311c is inclined relatively to the first chamber 311c. Consists of severe slopes.

The first chamfer 311b is in contact with the teeth 211 of the connecting plate 210 at the initial stage of the coupling torque does not significantly act, the second chamfer 311c is connected to the connecting plate (2) Contact teeth 211 of 210.

Therefore, in the initial stage of engagement, the lateral flow of the connector 310 teeth 311 with respect to the connection plate 210 teeth 211 is induced largely by the gentle inclined surface of the first chamber 311b, so that the teeth of the connector 310 are increased. 311 is easily inserted between the teeth 211 of the connection plate 210, and the teeth 311 of the connector 310 is connected to the connection plate 210 by the steep inclined surface of the second chamfer 311c during the coupling period. It is more easily inserted between the teeth 211 without receiving a large resistance.

As described above, the first and second chambers 311b and 311c are continuously formed so that the inclination of the spline teeth 311 of the connector 310 increases along the joining direction, so that the assembly position can be easily adjusted, and the assembly load is increased. It is reduced to facilitate the assembly of the damper 100 and the clutch 200 more easily.

As described above, the present invention has been described with reference to the embodiments illustrated in the drawings, but this is merely exemplary, and various modifications and equivalent embodiments of the present invention may be obtained by those skilled in the art. I understand that it is possible. Therefore, the true technical protection scope of the present invention will be defined by the claims below.

100: damper 200: clutch
210: connecting plate 211: spline teeth
300: connector 310: connector
311: spline tooth 312: fixing hole
320: connector cover 320a: protrusion
321: spring cover 322: tooth contact
330: spring 331,332: spring seat
340: rivet 350: square rivet
360: elastic washer 370: cover washer
371: protrusion 372: rivet hole
380 rivet

Claims (5)

A connector having a spline tooth shape fixed to the damper plate of the damper and coupled to a spline tooth shape formed on the connection plate of the clutch on an outer circumferential surface thereof;
A connector cover which is mounted to the connector to enable circumferential flow through the rivets, spring cover parts are formed at equal intervals in the circumferential direction, and the toothed contact parts protrude and extend from each spring cover part;
A plurality of springs installed between the spring cover part of the connector cover and the connector to apply elastic force to the spring cover in the circumferential direction;
An elastic washer installed between the connector and the connector cover and being in surface contact with one side of the connector cover over the entire circumferential direction;
A cover washer installed on the other side of the connector cover via the rivet and in surface contact with the other side of the connector cover over the entire circumferential direction.
Damper and clutch connection device of the vehicle comprising a. The method according to claim 1,
In the connector, a plurality of fixing holes used to fix the connector to the drive plate are formed at equal intervals in the circumferential direction, and the spring cover part and the rivet are disposed in every area between the fixing holes, and inside the spring cover part. The damper and clutch connecting device of the vehicle, characterized in that the spring is installed. The method according to claim 1,
A plurality of protruding pieces are formed on the outer circumference of the cover washer, a rivet hole is formed in the protruding piece, the rivet is inserted into the rivet hole, and the cover washer is fixed to the connector. A damper and clutch connection device of a vehicle, characterized in that the axial position is limited. The method according to claim 1,
The spline teeth of the connector is a damper and clutch connecting device of the vehicle, characterized in that the first and second chamfers having different inclination angles at both ends of the direction end coupled to the spline teeth of the clutch connecting plate. The method according to claim 4,
And the first chamber is formed with a slope that is relatively gentle compared to the second chamber, and the second chamber is formed with a slope that is relatively rapid compared to the first chamber.

Images