KR102215494B1 - Torque Converter for Motor Vehicle - Google Patents

Abstract

The present invention relates to a torque converter for a vehicle, and relates to a torque converter for a vehicle with improved airtightness of a coupling portion between a piston hub for coupling a piston and a damper hub for coupling a damper.

Description

Torque Converter for Motor Vehicle}

The present invention relates to a torque converter for a vehicle, and relates to a torque converter for a vehicle with improved airtightness of a coupling portion between a piston hub for coupling a piston and a damper hub for coupling a damper.

In general, a torque converter is installed between an engine and a transmission of a vehicle and transmits the driving force of the engine to a transmission using a fluid. Such a torque converter is an impeller that rotates by receiving the driving force of the engine, a turbine that is rotated by the working fluid discharged from the impeller, and a reactor that increases the rate of change of torque by directing the flow of the working fluid flowing back to the impeller in the direction of rotation of the impeller. (Also referred to as a'stator').

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

When describing the torque converter in more detail with reference to the drawings, FIG. 1 shows a half sectional view in the axial direction of a general torque converter, and FIG. 2 shows a coupling portion between a piston hub and a damper hub of a torque converter having a 3-Path flow path A partially enlarged cross-sectional view is shown.

Referring to FIG. 1, the torque converter TC includes a front cover 4 connected to the crankshaft of the engine and rotating, an impeller 6 connected to the front cover 4 and rotating together, and the impeller ( The turbine 8 disposed at a position facing the 6) and a reactor 10 disposed between the impeller 6 and the turbine 8 to change the flow of the working fluid from the turbine 8 and transfer it to the impeller 6 , Or'stator').

A one-way clutch 51 is coupled to the rotational central axis of the reactor 10. The one-way clutch 51 serves to rotate the reactor 10 in only one direction. The reactor 10 that delivers the working fluid to the impeller 6 has the same rotational center as the front cover 4.

Further, the torque converter TC is provided with a lock-up clutch 14 as a means for directly connecting the engine and the transmission, and the lock-up clutch 14 is disposed between the front cover 4 and the turbine 8. This lock-up clutch 14 has a substantially disk shape and includes a piston 16 that can move in the axial direction. A torsion damper 20 is coupled to the lock-up clutch 14. The torsion damper 20 transmits the driving force transmitted through the lock-up clutch 14 to the damper hub 49 to absorb a torsional force acting in the rotation direction of the shaft and attenuate vibration. The lock-up clutch 14 includes a friction plate 33 disposed between the front cover 4 and the piston 16. Therefore, when the piston 16 moves in the direction toward the front cover 4 by the hydraulic pressure of the working fluid, the lock-up clutch 14 causes the friction plate 33 to come into close contact with the front cover 4 and the piston 16. The rotational driving force transmitted from (4) may be transmitted to the friction plate (33).

Referring to FIG. 2, the torque converter TC includes a piston hub 7 supporting a piston 16 and a front cover 4 at the same time, and a damper hub 49 supporting the torsion damper 20. It is equipped. The piston hub (7) is provided adjacent to the damper hub (49), but the piston hub (7) is coupled to a damper hub that is recessed from the impeller side to the front cover side so that the front cover side end (49a) of the damper hub 49 is fitted. A groove 7a is formed. In addition, a hub sealing member 9 for sealing is provided between the coupling portion of the piston hub 7 and the damper hub 49 to maintain airtightness between the piston hub 7 and the damper hub 49. On the other hand, the torque converter (TC), the piston 16 and the pressure plate 17 provided at a predetermined distance apart from the impeller side of the piston 16 to seal the lock-up operation chamber (LC) is formed, the piston (16) and A chamber C is formed between the front cover 4. That is, with the piston 16 interposed therebetween, the lock-up operation chamber LC is formed on the impeller side, and the chamber C is formed on the front cover side. Therefore, whether the lockup operation is determined by the differential pressure between the lockup pressure LUP applied to the lockup operation chamber LC through the working fluid and the inlet pressure IP applied to the chamber C. That is, when the lockup pressure LUP increases, the piston 16 moves toward the front cover to be locked up, and when the chamber C pressure increases, the piston 16 is separated from the front cover and the lockup is released.

In the conventional 3-Path type torque converter as described above, the working fluid for supplying the inlet pressure (IP) is sequentially passed through the flow path formed in the damper hub 49 and the piston hub 7, the dotted arrow in FIG. As shown in the figure, due to the coupling structure of the damper hub 49 and the piston hub 7, the working fluid discharged from the damper hub 49 may leak between the pressure plate 17 and the torsion damper 20, There is a problem that operability and responsiveness deteriorate.

The present invention has been conceived to solve the above problems, and an object of the present invention is to improve the coupling structure between the piston hub and the damper hub, and to arrange the hub sealing member at an optimal position to provide a working fluid between the pressure plate and the torsion damper. It is to provide a torque converter for a vehicle in which the inlet pressure of the torque converter by the working fluid flows only between the piston and the front cover by preventing the leakage of the vehicle.

A torque converter for a vehicle according to an embodiment of the present invention includes a front cover, an impeller coupled to the front cover and rotating in association with the front cover, a turbine disposed opposite the impeller in an axial direction, and the impeller And a lock-up clutch having a reactor positioned between the turbine and changing the flow of the working fluid flowing out of the turbine to the impeller side, and a lock-up clutch having a piston directly connecting the front cover and the turbine, and coupled to the lock-up clutch in a rotational direction. In the vehicle torque converter comprising a damper that absorbs the shock and vibration acting and transmits the driving force to the transmission, wherein when the front cover side is defined as one axial side and the impeller side is the other axial side, the vehicle torque converter, A pressure plate disposed a predetermined distance apart from the other side of the piston so that a lock-up operation chamber is formed on the other side of the piston to seal the other side of the piston; A piston hub to which an inner surface of the front cover, a radially inner end of the piston, and a radially inner end of the pressure plate are coupled to support the front cover, the piston and the pressure plate; And a damper hub that connects the torsion damper and a transmission, and has one side coupled to the other side of the piston hub. Including, the piston hub, a first flow path formed so that a torque converter inlet pressure (TC inlet pressure) is supplied to the chamber formed between the front cover and the piston, the lockup pressure (LUP) is supplied to the lockup operation chamber The damper hub includes: a damper flow passage communicating with the first flow passage to transmit a torque converter inlet pressure to the first flow passage; And a sealing member is provided between the piston hub and the damper hub so that the inlet pressure does not leak into the space between the pressure plate and the torsion damper.

In addition, the piston hub has a cylindrical end formed on the other side such that a damper hub coupling groove into which one end of the damper hub is inserted is formed, and the damper hub is radially outer circumference of the damper hub so that the cylindrical end is inserted A piston hub receiving groove formed along the other side and recessed to the other side is formed, and the sealing member is disposed between an outer surface of the cylindrical end and an inner surface of the piston hub receiving groove.

In addition, the sealing member is inserted into the piston hub sealing groove which is recessed radially inward from the outer surface of the cylindrical end.

In another embodiment, the sealing member is inserted into a damper hub sealing groove recessed radially outward from an inner surface of the piston hub receiving groove.

Further, the radially inner end of the output plate of the torsion damper is non-rotatably coupled to the outer surface of the cylindrical damper hub formed extending from the outer side in the radial direction of the damper hub to one side so that the piston hub receiving groove is formed.

In addition, a basic sealing member for sealing is further provided between the damper hub coupling groove of the piston hub and one end of the damper hub.

The vehicle torque converter of the present invention having the above configuration has an effect of improving the operability and responsiveness of the lock-up clutch by unifying the inlet pressure flow path of the torque converter by the working fluid to facilitate pressure formation of the lock-up clutch. Furthermore, since the lock-up clutch can be easily controlled, fuel efficiency of a vehicle to which the torque converter of the present invention is applied is improved.

1 is a half sectional view in the axial direction of a typical torque converter
2 is a partially enlarged cross-sectional view of a coupling portion between a piston hub and a damper hub of a torque converter having a 3-Path flow path structure.
3 is an exploded perspective view of a torque converter according to an embodiment of the present invention
4 is a half sectional view in the axial direction of a torque converter according to an embodiment of the present invention
5 is a half sectional view in the axial direction showing an operating state of the torque converter of FIG. 4
6 is an exploded perspective view of a turbine part and a front cover part according to an embodiment of the present invention
7 is an enlarged partial cross-sectional view showing the periphery of a piston hub and a damper hub of a torque converter according to an embodiment of the present invention

Hereinafter, an embodiment of the present invention as described above will be described in detail with reference to the drawings. 3 is an exploded perspective view of the torque converter 1000 according to an embodiment of the present invention.

As shown, the torque converter 1000 according to an embodiment of the present invention includes a front cover assembly 400 including a front cover 4 (refer to FIG. 4) connected to the crankshaft of the engine to rotate, and a front cover. (4) A turbine comprising an impeller assembly 600 including an impeller 6 (see FIG. 4) that is connected to and rotates together, and a turbine 8 (see FIG. 4) disposed at a position facing the impeller 6 A reactor including an assembly 800 and a reactor 10 (refer to FIG. 4) positioned between the impeller 6 and the turbine 8 to change the flow of the working fluid from the turbine 8 and transfer it to the impeller 6 It may be configured as an assembly 100. A detailed configuration of the torque converter 1000 according to an embodiment of the present invention including the above configuration will be described in more detail with reference to the drawings.

3 is an axial cross-sectional view of the torque converter 1000 according to an embodiment of the present invention. As shown, the torque converter 1000 according to an embodiment of the present invention includes a front cover 4 connected to the crankshaft of the engine and rotating, and an impeller 6 connected to the front cover 4 and rotating together. Wow, the turbine 8 disposed in a position facing the impeller 6, and located between the impeller 6 and the turbine 8, change the flow of the working fluid from the turbine 8 and transmit it to the impeller 6 It includes a reactor (10). A one-way clutch 51 is coupled to the rotational central axis of the reactor 10. The one-way clutch 51 serves to rotate the reactor 10 in only one direction. The reactor 10 that delivers the working fluid to the impeller 6 has the same rotational center as the front cover 4.

In addition, the torque converter 1000 is provided with a lock-up clutch 140 as a means for directly connecting the engine and the transmission, and the lock-up clutch 140 is disposed between the front cover 4 and the turbine 8. This lock-up clutch 140 has a substantially disk shape and includes a piston 160 that can move in the axial direction. A torsion damper 200 is coupled to the lock-up clutch 140. The torsion damper 200 transmits the driving force transmitted through the lock-up clutch 140 to the damper hub 49 to absorb a torsional force acting in the rotation direction of the shaft and attenuate vibration. The lock-up clutch 140 includes a friction plate 330 disposed between the front cover 4 and the piston 160, and the friction plate 330 has friction materials 350 coupled to both sides thereof. Therefore, when the piston 160 moves in the direction toward the front cover 4 by the hydraulic pressure of the working fluid, the lock-up clutch 140 is in close contact with the front cover 4 and the piston 160, and the front cover ( The rotational driving force transmitted from 4) may be transmitted to the friction plate 330.

In addition, a chamber C is formed between the piston 160 and the front cover 4 through which the inlet pressure of the torque converter by the working fluid is introduced.

In addition, a pressure plate 61 is installed to form a lock-up operation chamber LC that pressurizes the lock-up pressure inside the piston 160 to operate the lock-up clutch 140. At this time, the piston 160 and the pressure plate 61 are sealed. Accordingly, the chamber C is formed on the left side of the drawing of the lock-up operation chamber LC.

In addition, a piston hub 70 that simultaneously supports the pressure plate 61, the piston 160 and the front cover 4 is provided. The piston hub 70 has a first flow path 71 that communicates with the chamber C and allows a torque converter inlet pressure through the working fluid to act on the chamber C, and a lock-up operation chamber LC. ) And communicating with the working fluid to allow the lock-up pressure through the working fluid to act on the lock-up operation chamber LC, respectively. The first flow path 71 and the second flow path 72 formed on the piston hub 70 are formed to be spaced apart from each other so as not to communicate with each other. On the damper hub 49 provided adjacent to the piston hub 70, a damper flow path that communicates with the first flow path 71 so that the torque converter inlet pressure through the working fluid can act on the chamber C. 49c) can be formed.

The operation of the vehicle torque converter 1000 according to an embodiment of the present invention having the above configuration will be described in detail with reference to the drawings. 4 is a half sectional view showing an operating state of the torque converter 1000 of FIG. 3. As shown, in the vehicle torque converter 1000, when the lockup clutch 140 is not operated, the driving force of the engine is applied to the front cover 4, the impeller 6, the turbine 8, and the torsion damper 200. The driving force is transmitted to the transmission. In this process, the inside spring 45 of the torsion damper 200 may absorb vibration and shock in the rotation direction. When the lockup clutch 140 operates, the piston 160 moves toward the front cover 4 as the lockup pressure through the working fluid is transmitted to the lockup operation chamber LC. Then, the friction materials 350 provided on both sides of the friction plate 330 are in close contact with the inner side of the front cover 4 and one side of the piston 160 so that the driving force of the front cover 4 is transmitted to the friction plate 330. Further, the driving force transmitted to the friction plate 330 is transmitted to the torsion damper 200 and transmitted to the transmission through the damper hub 49.

Further, in the torque converter 1000, the piston 160 and the pressure plate 61 are sealed to form a lock-up operation chamber LC, and a chamber SC is formed on the left side of the lock-up operation chamber LC. First and second flow paths 71 and 72 are formed on the piston hub 70 so that the torque converter inlet pressure IP and the lockup pressure LUP act on the chamber C and the lockup operation chamber LC, respectively. As the chamber and the flow path of the above structure are formed on the torque converter 1000, the differential pressure between the lock-up pressure (LUP) applied to the lock-up operation chamber (LC) and the torque converter inlet pressure (IP) applied to the chamber (C) The lockup operation is determined by.

That is, whether or not the lock-up clutch 140 is operated is determined by pressing the lock-up pressure in the lock-up operation chamber LC by using the lock-up operation chamber LC and the chamber C. Accordingly, in the torque converter 1000 according to the present invention, the design freedom in the axial direction of the lock-up clutch 140 is reduced, thereby improving design freedom. In addition, it is possible to eliminate the clutch drum, a plurality of friction plates, snap rings, etc. configured in the conventional lock-up clutch. In addition, the lock-up clutch 140 can be manufactured by press molding in its shape, thereby simplifying the manufacturing process.

In addition, it is easy to apply the operation flow path of the lock-up clutch 140 by configuring the piston hub from which the conventional pilot hub was formed separately as a pilot hub integral type. Therefore, the torque converter according to the present invention has a simple configuration and a reduced welding process, thereby facilitating manufacturing.

6 is an exploded perspective view of the turbine assembly 800 and the front cover assembly 400 according to an embodiment of the present invention. As shown, the front cover assembly 400 includes a piston 16 and a piston hub 70 supporting the front cover 4 at the same time, and the turbine assembly 800 includes a torsion damper 200. It includes a damper hub 49 for supporting. At this time, the torque converter 1000 according to an embodiment of the present invention allows the torque converter inlet pressure transmitted through the damper flow path 49c (refer to FIG. 4) to be transmitted only to the chamber C. A sealing member 300 is provided between the coupling portion of the piston hub 70 and the damper hub 49 to facilitate formation of the return pressure and maintain airtightness. Hereinafter, the coupling structure of the piston hub 70 and the damper hub 49 and the arrangement of the sealing member 300 according to an embodiment of the present invention will be described in detail with reference to the drawings.

7 is an enlarged partial cross-sectional view showing the periphery of a piston hub and a damper hub of a torque converter according to an embodiment of the present invention.

As shown, one outer peripheral surface of the damper hub 49 may be coupled to the other inner peripheral surface of the piston hub 70 made of a ring shape. At this time, a space may be formed between the damper flow path 49a formed in the damper hub 49 and the first flow path 71 formed in the piston hub 70, and the torque converter inlet pressure supplied from the damper flow path 49a Combination of the piston hub 70 and the damper hub 49 based on the space formed between the damper flow path 49a and the first flow path 71 so that (TC inlet pressure) is completely transmitted to the first flow path 71 Sealing members 300 and 310 may be provided on the part.

More specifically, the piston hub 70 has a damper hub coupling groove 75 recessed from the impeller side to the front cover side so that the front cover side end of the damper hub 49 is fitted. In addition, a basic sealing member 310 for sealing is provided between the damper hub coupling groove 75 of the piston hub 70 and the end of the damper hub 49, and between the piston hub 70 and the damper hub 49 Keep the confidentiality of

Additionally, on the damper hub 49, a piston hub receiving groove 49b formed along the radially outer circumference of the damper hub 49 so that the impeller-side cylindrical end 73 of the piston hub 70 is inserted and recessed toward the impeller is added. Is formed. In this case, a sealing member 300 may be provided between the impeller-side cylindrical end 73 of the piston hub 70 and the piston hub receiving groove 49b of the damper hub 49. The sealing member 300 may be formed in a ring shape made of an elastic material. Through the sealing member 300, the torque converter inlet pressure (TC inlet pressure) is prevented from leaking between the pressure plate 61 and the torsion damper 200, thereby facilitating the formation of the return pressure of the lock-up clutch and helping to maintain airtightness. have.

The sealing member 300 may be inserted into the piston hub sealing groove 73a that is recessed radially inward from the outer surface of the cylindrical end 73. As another example, the sealing member 300 may be inserted into a damper hub sealing groove (not shown) that is recessed radially outward from the inner surface of the piston hub receiving groove 49b.

In addition, the end of the output plate 210 of the torsion damper 200 is of the cylindrical damper hub 49c formed extending from the radial outer side of the damper hub 49 toward the front cover to form the piston hub receiving groove 49b. It may be non-rotatably coupled to the outer surface. Through this, the total length in the axial direction of the torque converter can be reduced, and the damper hub 49 has an effect of stably supporting the torsion damper 200.

The technical idea should not be interpreted as limited to the above-described embodiment of the present invention. As well as a variety of application ranges, various modifications may be made at the level of those skilled in the art without departing from the gist of the present invention claimed in the claims. Therefore, these improvements and changes will fall within the scope of protection of the present invention as long as it is apparent to those skilled in the art.

1000: torque converter
100: reactor assembly
400: front cover assembly
600: impeller assembly
800: turbine assembly
4: front cover 6: impeller
8 turbine 10 reactor
49: damper hub 49a: damper flow path
51: one-way clutch 61: pressure plate
300: sealing member
70: piston hub 71: first flow path
72: second euro
140: lock-up clutch
160: piston
200: torsion damper
LC: Lock-up operation chamber
C: chamber

Claims (6)

A front cover, an impeller coupled to the front cover and rotating in association with the front cover, a turbine that is spaced apart from the impeller in an axial direction and disposed to face each other, and an operation that is located between the impeller and the turbine to flow out of the turbine A lock-up clutch having a reactor that changes the flow of fluid to the impeller side, a lock-up clutch having a piston that directly connects the front cover and the turbine, and absorbs shock and vibration acting in the rotational direction by being coupled to the lock-up clutch to transmit driving force to the transmission. In the vehicle torque converter comprising a damper that,
When defining the front cover side as one side in the axial direction and the impeller side as the other side in the axial direction,
The vehicle torque converter,
A pressure plate disposed a predetermined distance apart from the other side of the piston so that a lock-up operation chamber is formed on the other side of the piston to seal the other side of the piston;
A piston hub to which an inner surface of the front cover, a radially inner end of the piston, and a radially inner end of the pressure plate are coupled to support the front cover, the piston and the pressure plate; And
A damper hub connecting the torsion damper and the transmission, and having one side coupled to the other side of the piston hub; Including,
The piston hub includes a first flow path formed to supply a torque converter inlet pressure (TC inlet pressure) to a chamber formed between the front cover and the piston, and a second flow path formed to supply a lockup pressure (LUP) to the lockup operation chamber. Including,
The damper hub may include: a damper passage communicating with the first passage to transmit a torque converter inlet pressure to the first passage; Including,
A sealing member is provided between the piston hub and the damper hub so that the inlet pressure does not leak into the space between the pressure plate and the torsion damper,
The piston hub has a cylindrical end formed on the other side such that a damper hub coupling groove into which one end of the damper hub is inserted is formed,
The damper hub is formed along a radially outer periphery of the damper hub so that the cylindrical end is inserted, and a piston hub receiving groove recessed to the other side is formed,
The sealing member is disposed between an outer surface of the cylindrical end and an inner surface of the piston hub receiving groove.
delete The method of claim 1,
The sealing member,
A torque converter for a vehicle, which is inserted into a piston hub sealing groove that is recessed radially inward from an outer surface of the cylindrical end.
The method of claim 1,
The sealing member,
A torque converter for a vehicle, which is inserted into a damper hub sealing groove recessed radially outward from an inner surface of the piston hub receiving groove.
The method of claim 1,
The radially inner end of the output plate of the torsion damper,
A torque converter for a vehicle that is non-rotatably coupled to an outer surface of a cylindrical damper hub extending from a radially outer side of the damper hub to one side so that the piston hub receiving groove is formed.
The method of claim 1,
A torque converter for a vehicle, further comprising a basic sealing member for sealing between the damper hub coupling groove of the piston hub and one end of the damper hub.

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