KR20130040003A - Torque converter for vehicle - Google Patents

Abstract

PURPOSE: A torque converter of a vehicle is provided to increase ride comfort by attenuating the vibration of the frequencies of various domains. CONSTITUTION: An impeller is combined with the front cover for rotating integrally. A turbine is arranged at a position facing the impeller. A stator switches the flow of oil coming from the turbine into an impeller side. A lockup clutch comprises a piston(11). The piston directly connects the front cover to the turbine. A torsional damper(15) is combined with the lockup clutch for absorbing vibration and impact in a rotational direction. The torsional damper comprises a compressed coil spring(17). The compressed coil springs are supported by a retaining plate(19). A hinge pin(23) fixes the retaining plate.

Description

Technical Field [0001] The present invention relates to a torque converter for a vehicle,

The present invention relates to a torque converter for a vehicle having a torsional damper capable of attenuating vibrations of various frequencies.

In general, the torque converter is installed between the engine of the vehicle and the transmission to transmit the driving force of the engine to the transmission using a fluid. Such a torque converter includes an impeller rotating under the driving force of the engine, a turbine rotated by the oil discharged from the impeller, and a reactor for increasing the rate of torque change by directing the flow of oil flowing back to the impeller in the direction of rotation of the impeller Quot; stator ").

The torque converter is equipped with a lock-up clutch (also called a "damper clutch"), which is a means of directly connecting the engine to the transmission, as power transmission efficiency may be degraded if the load acting on the engine is increased. The lockup clutch is disposed between the front cover and the turbine directly connected to the engine so that the rotational power of the engine can be transmitted directly to the transmission through the turbine.

This lockup clutch includes a piston that is axially movable on the turbine shaft. The piston is engaged with a friction material which is in friction contact with the front cover. The piston is fitted with a torsional damper capable of absorbing shock and vibration acting in the direction of rotation of the shaft when the friction material is engaged with the front cover.

The above-mentioned torsional dampers are provided with springs which can absorb torsional torque when the lockup clutch is operated so that the driving force of the engine can be directly transmitted to the transmission through the turbine and the spline hub.

These springs absorb vibrations and shocks in the rotational direction, but attenuate vibrations having a specific range of frequencies, and have limitations in attenuating vibrations having various ranges of frequencies. .

Therefore, the present invention has been proposed to solve the above problems, and an object of the present invention is to attenuate the vibration of the frequency range of various areas when the lock-up clutch is operated to increase the ride comfort of the vehicle when the torque converter is mounted on the vehicle. It is to provide a torque converter that improves the marketability.

In addition, another object of the present invention is to provide a torque converter that maximizes the maximum angle of the damper to maximize vibration and shock absorption in the rotational direction.

In addition, another object of the present invention is to replace the existing mechanical stopper to provide a torque converter that can absorb shock even when the stopper operation.

In order to achieve the object of the present invention as described above, the present invention is a front cover, an impeller coupled to the front cover to rotate together, a turbine disposed in a position facing the impeller, located between the impeller and the turbine Stator for changing the flow of oil from the turbine to the impeller side, Lockup clutch with a piston directly connecting the front cover and the turbine, Torsional damper coupled to the lockup clutch to absorb the shock and vibration acting in the rotational direction Including,

The torsional damper may include a retaining plate coupled to the piston, compression coil springs disposed on the retaining plate and acting elastically in the circumferential direction, and springs disposed at both ends of the compression coil springs to support the compression coil springs. Seats, a driven plate acting against the compression coil springs and coupled to the turbine,

The retaining plate is formed of a plurality and hinged to the piston by a hinge pin, rotates integrally with the piston and at the same time rotates around the hinge pin, the piston has a plurality of stopper springs consisting of a leaf spring Coupled, the stopper spring provides a vehicle torque converter disposed on one side of the retaining plate.

It is preferable that a gap retaining member is provided on an outer circumference of the hinge pin to maintain a gap between the piston and the retaining plate.

The hinge pins are preferably arranged on the same circumference.

The retaining plate preferably includes a coupling portion to which the hinge pin is coupled, and a spring receiving portion extending from the coupling portion and on which the compression coil spring is disposed.

The retaining plate is composed of four members and is preferably arranged symmetrically with each other.

The stopper spring may include a fixing part fixed to the piston by a coupling means, a first elastic part extending in an axial direction from the fixing part, and a band bending at the first elastic part to contact a side surface of the retaining plate. It is preferable to include 2 elastic parts.

As described above, the present invention attenuates the vibration having a specific range of frequencies by the compression coil spring provided to the torsional damper, and at the same time, the stopper spring operates and has a frequency range that is different from the vibration having the frequency range absorbed by the compression coil spring. Attenuation of vibrations has the effect of attenuating vibrations having frequencies in various ranges, thereby improving the marketability.

In addition, the present invention can increase the maximum angle of the damper by increasing the operating section of the compression coil spring and the operating section of the stopper spring can increase the vibration and shock absorption effect in the rotation direction.

In addition, the present invention has the effect of increasing the shock absorption while replacing the mechanical stopper.

1 is a half sectional view of a torque converter for explaining an embodiment of the present invention.
Figure 2 is a view showing a state in which the retaining plate is coupled to the piston for explaining an embodiment of the present invention.
3 is an exploded perspective view illustrating the main part of FIG. 2 in an exploded manner.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

1 is a cross-sectional view for explaining an embodiment of the present invention, showing a torque converter.

The torque converter according to the embodiment of the present invention has a front cover (1) connected to the crankshaft on the engine side to rotate, a position facing the impeller (3) and the impeller (3) connected to and rotated together with the front cover (1). And a stator 7 positioned between the impeller 3 and the turbine 5 to change the flow of oil coming out of the turbine 5 and transfer it to the impeller 3 side. The stator 7 delivering oil to the impeller 3 side has the same center of rotation as the front cover 1. And the lockup clutch 9, which is used as a means for directly connecting the engine and the transmission, is disposed between the front cover 1 and the turbine 5.

The lockup clutch 9 is formed in a substantially disk shape and has a piston 11 that can move in the axial direction.

And the piston 11 is coupled to the friction material 13 in friction contact with the front cover (1).

In addition, the lockup clutch 9 is coupled with a torsional damper 15 that absorbs the torsional force acting in the rotational direction of the shaft and attenuates vibration when the friction material 13 is in close contact with the front cover 1. do.

The torsional damper 15 is provided with compression coil springs 17 which absorb shock and vibration acting in the circumferential direction. These compression coil springs 17 are preferably arranged in the circumferential direction (rotation direction).

These compression coil springs 17 are supported by a retaining plate 19 coupled to the piston 11 described above (shown in FIG. 2). And the compression coil springs 17 are elastically supported by the driven plate 21 coupled to the turbine 5. That is, the compression coil springs 17 are elastically supported between the retaining plate 19 and the driven plate 21 to absorb vibrations and shocks in the rotational direction (circumferential direction).

The retaining plates 19 of the embodiment of the present invention are arranged in four in the same shape and are coupled to the piston 11 by hinge pins 23, respectively. However, although the retaining plate 19 in the embodiment of the present invention has been described by showing an example consisting of four members is not limited to the number and can be appropriately adjusted according to the design needs.

The hinge pins 23 holding the retaining plate 19 are preferably arranged on the same circumference (shown in Figs. 2 and 3).

The retaining plate 19 includes a coupling portion 19a to which the hinge pin 23 is coupled, and a spring receiving portion 19b extending from the coupling portion 19a and on which the compression coil spring 17 is disposed.

The engaging portion 19a of the retaining plate 19 is provided with a hole into which the hinge pin 23 is fitted. It is preferable that the diameter of the hole provided in the engaging portion 19a of the retaining plate 19 is made larger than the diameter of the hinge pin 23. The gap holding member 25 is disposed on the outer circumference of the hinge pin 23 to maintain the gap between the retaining plate 19 and the piston 11.

The space keeping member 25 is disposed such that the retaining plate 19 and the piston 11 have clearance in the axial direction.

In addition, a groove is provided in the circumferential direction of the spring receiving portion 19b of the retaining plate 19 so that the compression coil spring 17 may be disposed in the circumferential direction.

The retaining plate 19 can rotate about the hinge pin 23 (indicated by the arrow in FIG. 2). That is, the retaining plate 19 may rotate integrally with the piston 11, and may rotate a predetermined angle about the hinge pin 23. The retaining plate 19 may rotate to a degree with a slight flow around the hinge pin 23.

A plurality of stopper springs 27 are coupled to the piston. The stopper spring 27 is preferably made of a leaf spring.

The stopper spring 27 may be disposed at a position that can be in contact with one side of each retaining plate 19.

The stopper spring 27 includes a fixing portion 27a fixed to the piston 11, a first elastic portion 27b extending from the fixing portion 27a, and a second elastic portion extending from the first elastic portion 27b. (27c).

A coupling hole is provided in the fixing portion 27a of the stopper spring 27, and the stopper spring 27 is coupled to the piston 11 by a coupling means such as a rivet. The first elastic portion 17b of the stopper spring 27 extends bent in the axial direction from the fixing portion 27a and consists of a plate-like elastic body. The second elastic portion 17c of the stopper spring 27 is disposed at a position which is bent and extended from the first elastic portion 17b to be in contact with one side of the retaining plate 19, of course, of the stopper spring 27. It is preferable that the 2nd elastic part 17c also consists of a plate-shaped elastic body.

That is, it is preferable that the first elastic portion 17b and the second elastic portion 17c are bent to each other to have a structure capable of absorbing the impact when the retaining plate 19 is rotated by flow.

The present invention made as described above is described as follows the operation of the embodiment.

First, an example will be described in which the lockup clutch 9 of the torque converter is operated so that the driving force of the engine is directly connected to the transmission without passing through the impeller 3.

When the piston 11 is moved toward the front cover 1 by hydraulic pressure and the lockup clutch 9 is operated, the retaining plate 19 rotates together with the piston 11 to rotate the compression coil spring 17 in the rotational direction. Press to compress. At this time, the compression coil spring 17 absorbs vibration and shock in the rotational direction generated during the operation of the lockup clutch 9. In this case, the compression coil spring 17 may absorb vibrations having a frequency in a specific region.

At this time, the retaining plate 19 also presses the first elastic portion 27b of the stopper spring 27 while rotating a predetermined section (for example, the degree of flow) around the hinge pin 23.

Then, the first elastic portion 27b and the second elastic portion 27c may compress each other to absorb the shock transmitted by the retaining plate 19. In this process, the stopper spring 27 absorbs a vibration having a frequency of a specific area band that is absorbed by the compression coil spring 17 and a vibration having a frequency of another area band.

That is, in the embodiment of the present invention, when the vibration is absorbed by the compression coil spring 17 and the stopper spring 27, it is possible to absorb vibrations having frequencies of various ranges.

The driving force of the compression coil spring 17 is transmitted to the driven plate 21, and the driven plate 21 transmits the driving force to the spline hub 29 transmitting the driving force to the turbine shaft or the transmission. Therefore, the driving force of the engine is directly connected to the transmission.

This embodiment of the present invention has a damper angle including the angle that the compression coil spring 17 is moved while the retaining plate 19 is rotated about the hinge pin 23, the damper angle including the angle of rotation of the damper The maximum angle can be increased to further improve shock and vibration absorption.

In addition, the embodiment of the present invention replaces a conventional mechanical stopper, so that the shock generated by the mechanical stopper is absorbed by the stopper spring 27, thereby further improving the shock absorbing function.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And it goes without saying that the invention belongs to the scope of the invention.

1.front cover,
3. impeller,
5. turbine,
7. Stator,
9. lockup clutch,
11.piston,
13. friction material,
15. torsional dampers,
17. compression coil spring,
19. Retaining plate, 19a. Coupling, 19b. Spring Receptacle,
21. driven plate,
23. Hinge pins,
25. Spacing members,
27. Stopper springs, 27a. Fixing part, 27b. First elastic portion, 27c. Second elastic part,
29. Spline Hub

Claims (6)

A front cover, an impeller coupled to the front cover to rotate together, a turbine disposed at a position facing the impeller, a stator positioned between the impeller and the turbine to change the flow of oil from the turbine to the impeller side, the front A lock-up clutch having a piston directly connecting the cover and the turbine, a tonic damper coupled to the lock-up clutch to absorb shock and vibration acting in a rotational direction,
The local damper
Retaining plate coupled to the piston, compression coil springs disposed on the retaining plate and acting elastically in the circumferential direction, spring sheets disposed on both ends of the compression coil springs to support the compression coil springs, the compression A driven plate acting against the coil springs and coupled to the turbine,
The retaining plate
Is made of a plurality is hinged to the piston by a hinge pin, rotates integrally with the piston and at the same time rotates around the hinge pin,
The piston is coupled to a plurality of stopper spring made of a leaf spring, the stopper spring is disposed on one side of the retaining plate vehicle torque converter. The method according to claim 1,
The outer periphery of the hinge pin is a vehicle torque converter provided with a spacing member for maintaining the spacing of the piston and the retaining plate. The method according to claim 1,
The hinge pin is a vehicle torque converter disposed on the same circumference. The method according to claim 1,
The retaining plate
A coupling part to which the hinge pins are coupled;
And a spring receiving part extending from the coupling part and in which the compression coil spring is disposed. The method according to claim 1,
The retaining plate
Automotive torque converter consisting of four members arranged symmetrically to each other. The method according to claim 1,
The stopper spring is
Fixed part fixed to the piston by a coupling means,
A first elastic portion bent in the axial direction and extending from the fixing portion,
A second elastic portion that is bent at the first elastic portion to contact a side surface of the retaining plate
Vehicle torque converter comprising a.

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