KR100848071B1 - Clutch assembly for automatic transmission - Google Patents

Abstract

A multi-plate clutch for an automatic transmission is provided to reduce the total volume of the automatic transmission through designing the multi-plate clutch to have a compact structure. A multi-plate clutch for an automatic transmission comprises a first clutch(A) and a second clutch(B). The first clutch includes a first retainer(54) integrally coupled to a first shaft, a first clutch plate(58) integrally coupled to the first retainer, a first clutch disk(61) to transfer rotational power to a first hub(60), a first piston(59) to intermittently couple the clutch disk and the first clutch plate, and a first spring(62) capable of applying elastic force on the first piston. The second clutch includes a second hub(70) integrally coupled to the first shaft and a second clutch disk(68) integrally coupled to the second hub.

Description

Multi-plate clutch for automatic transmission {Clutch assembly for automatic transmission}

1 is a cross-sectional view showing the configuration of a multi-plate multi-clutch according to the prior art,

2 is a cross-sectional view showing the configuration of a multi-plate multiple clutch according to an embodiment of the present invention,

3 is a cross-sectional view showing a state when the clutch of FIG. 2 operates.

<Description of the symbols for the main parts of the drawings>

50 to 53: 1st to 4th axis 54 to 57: 1st to 4th retainer

58: first clutch plate 59: first piston

60: first hub 61: first clutch disc

62: first spring 63: first hydraulic hole

64: first fixing plate 65: lower rotating plate

66: first balancing chamber 67: second clutch plate

68: second clutch disc 69: second piston

70: second hub 71: third hub

72: second spring 73: second hydraulic hole

74: second fixing plate 75: second balancing chamber

76: inlet 77: straight path

78: outlet 79: third clutch disc

80: third clutch plate 81: third piston

82: third spring 83: third fixing plate

84: fourth clutch disc 85: fourth clutch plate

The present invention relates to a connection structure of a multi-plate clutch for an automatic transmission, and more particularly, to connect a multi-plate clutch for an automatic transmission to improve operational efficiency and spatial efficiency by arrangement by changing the existing clutch configuration and arrangement. It's about structure.

In general, an automatic transmission of a vehicle is composed of a torque converter, a transmission gear mechanism connected to the torque converter, and a hydraulic control circuit for selectively operating a gear of the transmission gear mechanism in accordance with the driving state of the vehicle.

Here, a plurality of friction members are used to control each gear of the transmission gear mechanism, and the friction members generally include underdrive clutches, reverse and overdrive clutches, low-reverse brakes, and second brakes. The friction member is operated by the hydraulic pressure generated by the oil pump.

1 is a cross-sectional view when the clutch of the multi-plate clutch of the automatic transmission according to the prior art, Figure 2 is a cross-sectional view of the clutch action of the multi-plate clutch of the automatic transmission according to the prior art.

The multi-plate clutch of the automatic transmission according to the prior art includes a shaft (2, 23) to which rotational power is transmitted, a clutch retainer (6, 13) coupled to the shaft (2, 23) to receive rotational power, and the clutch The clutch plates 7 and 14 connected to the retainers 6 and 13 to rotate and regulate rotational power, and are connected to the clutch plates 7 and 14 to transmit rotational power to the clutch hubs 8 and 15. Clutch pistons 17 and 26 for clamping the clutch discs 9 and 16, the clutch plates 7 and 14 by hydraulic pressure, and the clutch piston 17 and 12 when the hydraulic pressure of the clutch pistons 17 and 26 is released. 26 and return springs 12 and 27 in place.

The clutch retainers 6 and 13 and the clutch hubs 8 and 15 are formed with lubricating oil holes through which lubricating oil can flow for heat dissipation of the clutch plates 7 and 14 and the clutch disks 9 and 16, respectively.

At this time, the two clutches A and B are arranged side by side in the radial direction, and the retainer 13 of the second clutch 5 also serves as a balancing chamber configuration of the first clutch 4. In addition, the first and second clutches 4 and 5 are connected to the first shaft 2.

Here, the retainer 38 of the third clutch 36 also serves as the hub of the fourth clutch 35.

As shown in FIG. 2, the clutch pistons 17 and 26 are moved toward the clutch plates 7 and 14 and the clutch discs 9 and 16 by hydraulic pressure. By rotating the clutch plates 7 and 14 and the clutch discs 9 and 16, rotational power transmitted through the shafts 2 and 23 and the clutch retainers 6 and 13 is transmitted to the clutch hubs 8 and 15. To be.

Here, the power of the first shaft 2 is transmitted to the hub of the third clutch 36 through the retainer 6.

On the contrary, as shown in FIG. 1, when the hydraulic pressure of the clutch pistons 17 and 26 is released, the clutch pistons 17 and 26 are returned to their positions by the restoring force of the return springs 12 and 27 to transmit power. Is blocked.

However, since the clutch must be compactly designed to reduce the size of the entire transmission, it is required to reduce the size as much as possible to maintain the vehicle or secure space.

The present invention has been made in view of the above, and the first and second clutches are connected to different first and second shafts, respectively, and the operating flow path of the second clutch has a first shaft provided with the first clutch. Multi-plate for automatic transmission that is connected through the hub connected to the first shaft, power is transmitted to the retainer connected to the second shaft during operation of the second clutch, thereby improving the space efficiency and operational efficiency by changing the layout. The purpose is to provide a connection structure for the clutch.

The present invention for achieving the above object in the connection structure of the multi-plate clutch for automatic transmission,

A first retainer integrally rotatably coupled to the first shaft; A first clutch plate integrally rotatably coupled to the first retainer; A first clutch disc connected to and spaced apart from the first clutch plate to transmit rotational power to the first hub; A first piston for controlling the first clutch disc and the first clutch plate; A first clutch configured to impart an elastic force to the first piston;

A second hub rotatably coupled to the first shaft; A second clutch disc rotatably coupled to the second hub; A second clutch plate connected to and spaced apart from the second clutch disc to transmit rotational power to the second retainer; A second retainer installed below the first retainer and rotatably coupled to the second shaft; A second piston for controlling the second clutch disc and the second clutch plate; And a second spring configured to impart an elastic force to the second piston.

In a preferred embodiment, the first piston is supplied with hydraulic pressure through the first hydraulic hole when the first clutch is operated to press the first clutch plate, and the first clutch plate is contacted with the first clutch disc to remove the first clutch plate by friction. It is characterized by transmitting power to one hub.

In a more preferred embodiment, the second piston is supplied with hydraulic pressure through a second hydraulic hole formed in the second shaft during the operation of the second clutch to press the second clutch plate, the second clutch plate and the second clutch disk It is characterized in that the contact to transmit power to the second retainer by friction.

The hydraulic pressure supplied to the second hydraulic hole may be connected to the second hydraulic hole through the first shaft separately from the one supplied to the first hydraulic hole.

In addition, the lower end of the first hub is connected to the third shaft is characterized in that for transmitting power during the first clutch operation.

In addition, the first retainer is characterized in that it further comprises a third hub rotatably coupled integrally.

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

A preferred embodiment of the present invention relates to a multi-plate multiple clutch applied to an automatic transmission.

In general, a clutch is a power transmission mechanism that transmits power by friction. That is, when the drive shaft (input shaft) rotates, the retainer and the plurality of clutch plates installed to interlock with the drive shaft generate friction while contacting the clutch disk by the operation of the piston by hydraulic pressure to transfer power to the hub of the driven shaft (output shaft). do.

At this time, the hydraulic pressure is formed by the oil pump during the clutch operation, is supplied to the piston through the hydraulic inlet to move the piston toward the clutch plate to press.

2 is a cross-sectional view showing the configuration of a multi-plate multiple clutch according to an embodiment of the present invention.

The multi-plate multiple clutch according to the preferred embodiment of the present invention includes a shaft to which rotational power is transmitted, a clutch retainer coupled to the shaft to receive rotational power, and a clutch plate connected to the clutch retainer to rotate while intermittent rotational power. It is configured to include.

In addition, the clutch disk for transmitting rotational power to the hub while being spaced apart from the clutch plate, a clutch piston for controlling the clutch plate by hydraulic pressure, and a return spring for repositioning the clutch piston when the hydraulic pressure of the clutch piston is released. do.

The shaft includes a first shaft 50 to the fourth shaft 53. In this case, the first shaft 50 is an input shaft, and the second shaft 51 to the fourth shaft 53 are output shafts.

The clutch retainer is rotatably installed on an upper portion of the shaft to receive rotational power through the shaft, and includes first to fourth retainers 54 to 57.

A first retainer 54 is connected to the first shaft 50, and a plurality of first clutch plates 58 are installed in parallel at an upper end of the first retainer 54, and the first retainer 54 is connected to the first shaft 50 by the first piston 59. It is installed to move from side to side.

At this time, the third hub 71 is rotatably coupled to the upper end of the first retainer 54 integrally.

A first clutch disc 61 is inserted between the first clutch plate 58, and the first clutch plate 58 is pressed by the first piston 59 to be in contact with the first clutch disc 61. Torque is transmitted.

A first hub 60 is installed below the first clutch disc 61, and a lower end of the first hub 60 is connected to the third shaft 52.

The first piston 59 is elastically supported by the first spring 62 inside the first retainer 54, and the first retainer 54 and the first piston 59 are disposed below the first piston 59. A first hydraulic hole 63 through which the hydraulic pressure formed by the oil pump is supplied is formed between the left surfaces of the upper and lower surfaces.

At this time, the right end of the first spring 62 is fixed by the first fixing plate 64. When the hydraulic pressure is supplied through the first hydraulic hole 63, the first piston 59 moves to the right and the hydraulic pressure is released. The first spring 62 returns to the original position.

In addition, the lower rotating plate 65 integrally coupled to the first piston 59, the first fixing plate 64, and the first shaft 50 forms a first balancing chamber 66.

The right end of the first shaft 50 is installed so that the left end of the second shaft 51 is overlapped upward, and the second retainer 55 is positioned below the first hub 60, and the second retainer ( The lower end of 55 is rotatably coupled with the second shaft 51.

In addition, a second clutch plate 67 is disposed in parallel at an upper end of the second retainer 55, and a second clutch disc 68 is inserted at regular intervals between the second clutch plate 67. The second clutch plate 67 is pressed from the second piston 69 and comes into contact with the second clutch disk 68 to substantially transmit the rotational force. At this time, the second hub 70 is connected to the first shaft 50 at the lower portion of the second clutch disk 68.

The second piston 69 is elastically supported by the second spring 72 inside the second retainer 55, and the second retainer 55 and the second piston 69 are disposed below the second piston 69. The second hydraulic hole 73 is supplied between the right side of the) is supplied with the hydraulic pressure formed by the oil pump.

At this time, the left end of the second spring 72 is fixed by the second fixing plate 74, and when hydraulic pressure is supplied through the second hydraulic hole 73, the second piston 69 moves to the left side and the hydraulic pressure is released. The original spring is returned to the original position by the second spring 72.

In addition, the second piston 69, the second fixing plate 74, and the second shaft 51 form a second balancing chamber 75.

The hydraulic pressure flow channel supplied through the second hydraulic hole 73 has an inlet 76 formed to be inclined to the left side on the first shaft 50, a straight channel 77 formed inside the first shaft, and a straight channel ( The outlet 78 is formed from the end of the 77 to the hydraulic hole (73).

The third hub 71 on the lower right side connected to the first retainer 54 receives power from the first retainer, and a third clutch disc 79 is installed on the upper right end of the third hub 71. .

The third clutch plate 80 is installed in parallel on the upper end of the third retainer 56, and the third clutch plate 80 is pressed from the third piston 81 to be in contact with the third clutch disk 79. Substantially rotational force is transmitted.

The third piston 81 is elastically supported by the third spring 82 inside the third retainer 56, and the third retainer 56 and the third piston 81 are disposed below the third piston 81. A hydraulic hole through which the hydraulic pressure formed by the oil pump is supplied is formed between the right surfaces of

At this time, the left end of the third spring 82 is fixed by the third fixing plate 83, and when the hydraulic pressure is supplied through the hydraulic hole, the third piston 81 moves to the left side, and when the hydraulic pressure is released, the third spring 82 To return to the original position.

The lower end of the third retainer 56 is connected to the fourth shaft 53, and the third retainer 56 serves as the fourth hub of the fourth clutch D at the same time, and the third retainer 56 The fourth clutch disk 84 is installed at the upper end.

The fourth clutch plate 85 is installed at the lower end of the fourth retainer 57, and the fourth clutch D is operated by the contact between the fourth clutch plate 85 and the fourth clutch disk 84.

Referring to the operating state of the automatic transmission clutch according to the present invention by such a configuration as follows.

3 is a cross-sectional view showing a state when the clutch of FIG. 2 operates. Here, the same reference numerals as in the above-described drawings indicate the same members having the same function.

1) When the first clutch is operating

As the rotational power is transmitted to the first shaft 50, the first shaft 50 rotates, the first retainer 54 rotates together with the first shaft 50, and is connected to the upper end of the first retainer 54. Power is transmitted to the third hub 71. At this time, the first clutch plate 58 of the first retainer 54 is rotated.

In this case, when the first clutch A is operated, that is, the hydraulic pressure is supplied through the first hydraulic hole 63 so that the first piston 59 moves to the right side so that the first clutch plate 58 at the left end thereof is moved. When pressurized, the first clutch plate 58 contacts the first clutch disc 61 and the first hub 60 rotates to transmit power to the third shaft 52 connected to the first hub 60.

2) When operating the first clutch and the second clutch

When the second hub 70 connected to the first shaft 50 is rotated by receiving power and the second clutch B is operated, that is, the hydraulic pressure is supplied through the second hydraulic hole 73 so that the second hub 70 is rotated. When the piston 69 moves to the left to press the second clutch plate 67 at the right end, the second clutch disc 67 rotates together with the second hub 70 and the second clutch disc 68. Rotating while contacting, the second retainer 55 connected to the upper portion of the second clutch plate 67 is rotated, and eventually power is transmitted to the second shaft (51).

At this time, the second hydraulic hole (73) through the inlet (76) formed on the left side of the first shaft (50)-> the straight passage (77) of the first shaft-> the outlet (78) formed at the right end of the first shaft The hydraulic pressure will be supplied.

3) When operating the first clutch and the third clutch

As the first shaft 50 moves, power is transmitted to the third hub 71, the third clutch disc 79 coupled with the third hub 71 rotates, and the third clutch C is rotated. When it is activated, that is, when the hydraulic pressure is supplied through the third hydraulic hole to move the third piston 81 to the left to press the third clutch plate 80 at the right end, the third clutch plate 80 is connected to the third. The third retainer 56 connected to the upper portion of the third clutch plate 80 rotates while being in contact with the clutch disk 79.

4) During the first, third and fourth clutch operation

Since the third retainer 56 serves as the fourth hub at the same time, the fourth clutch disk 84 rotates as the third retainer 56 rotates, and the fourth clutch D operates. That is, when the fourth piston D receives the hydraulic pressure to press the fourth clutch plate 85, the fourth clutch plate 85 contacts the fourth clutch disk 84 to transmit power, and the fourth clutch plate. The fourth retainer 57 rotates together with 85.

According to the operation state as described above, the first clutch A and the second clutch B are installed on each of the first shaft 50 and the second shaft 51, and the operating flow path of the second clutch B is the first passage. The clutch A is connected through the first shaft 50 provided with the clutch A, and when the second clutch is operated, the power is received from the second hub 70 connected to the first shaft 50 to receive the power through the second retainer 55. By transmitting power to the two shafts 51, the operational efficiency and the space efficiency due to the arrangement can be improved.

While the invention has been shown and described with respect to certain preferred embodiments thereof, the invention is not limited to these embodiments, and has been claimed by those of ordinary skill in the art to which the invention pertains. It includes all the various forms of embodiments that can be carried out without departing from the spirit.

As described above, according to the connection structure of the multi-plate clutch for an automatic transmission according to the present invention, the first clutch and the second clutch are installed on each of the first and second shafts, the second clutch operating flow path is the first clutch Is connected through the first shaft is installed, the power is transmitted from the second hub connected to the first shaft when the second clutch is operated, power is transmitted to the second shaft through the second retainer, thereby operating efficiency and space efficiency by arrangement To improve it.

Claims (6)

In the multi-plate clutch for automatic transmission, A first retainer 54 rotatably coupled to the first shaft 50; A first clutch plate 58 rotatably coupled to the first retainer; A first clutch disc 61 which transmits rotational power to the first hub 60 while being connected to and spaced from the first clutch plate; A first piston 59 for controlling the first clutch disc and the first clutch plate; And A first clutch A comprising: a first spring 62 to impart an elastic force to the first piston; A second hub 70 rotatably coupled to the first shaft 50; A second clutch disc 68 rotatably coupled to the second hub; A second clutch plate 67 which transmits rotational power to the second retainer 55 while being connected to and spaced from the second clutch disk; A second retainer installed below the first retainer and rotatably coupled to the second shaft 51 integrally; A second piston (69) for controlling the second clutch disc and the second clutch plate; And And a second clutch (B) composed of a second spring (72) for imparting an elastic force to the second piston. The method according to claim 1, When the first piston is operated, the first piston receives hydraulic pressure through the first hydraulic hole 63 to pressurize the first clutch plate, and the first clutch plate contacts the first clutch disk to friction with the first hub. Multi-plate clutch for automatic transmission, characterized in that to transmit power to. The method according to claim 2, When the second piston is operated, the second piston receives hydraulic pressure through the second hydraulic hole 73 formed in the second shaft to press the second clutch plate, and the second clutch plate contacts the second clutch disk to friction. A multi-plate clutch for an automatic transmission, characterized by transmitting power to the second retainer. The method according to claim 3, The hydraulic pressure supplied to the second hydraulic hole is a multi-plate clutch for an automatic transmission, characterized in that connected to the second hydraulic hole through the first shaft separately from the supply to the first hydraulic hole. The method according to claim 4, The lower end of the first hub is connected to the third shaft 52, the multi-plate clutch for an automatic transmission, characterized in that for transmitting power during the operation of the first clutch. The method according to any one of claims 1 to 5, The first retainer is a multi-plate clutch for an automatic transmission, characterized in that it further comprises a third hub (71) rotatably coupled integrally.

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