JP2004060740A - Hydraulic circuit of hydraulic multi-plate clutch - Google Patents

Abstract

Provided is a hydraulic circuit for a hydraulic multi-plate clutch capable of fluidly communicating a relatively rotating clutch drum-side oil passage and a case-side oil passage with a simple configuration.
An outer periphery of a hollow shaft and a concave groove are sealed in a liquid-tight manner by a seal ring, and an inner periphery of the hollow shaft and a torque converter output shaft are sealed in a liquid-tight manner by a bush. An oil chamber 103 is formed in the oil chamber 105, and an upstream side of the drum-side oil passage 101 and a downstream side of the case-side oil passage 102 are opened in the oil chamber 103 so that a single seal ring is formed around the outer periphery of the hollow shaft 106. The drum-side oil passage 101 and the case-side oil passage 102 communicate with each other with a simple configuration in which the arrangement 109 is provided.
[Selection diagram] Fig. 1

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a hydraulic circuit of a hydraulic multi-plate clutch for supplying a hydraulic pressure to a hydraulic chamber.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, as a hydraulic multi-plate clutch used for an automatic transmission or the like, for example, the one shown in FIG. 3 is known. Here, FIG. 3 is a cross-sectional view of a main part showing a forward / reverse switching device of an automatic transmission equipped with a belt-type continuously variable transmission as a main transmission.
[0003]
In FIG. 3, reference numeral 151 denotes a center support case interposed between a starting device such as a torque converter (not shown) and the forward / reverse switching device 150. The center support case 151 is provided on the case 152 of the forward / reverse switching device 150. It is fixed. Inside the case 152, a torque converter output shaft 153 extending from the starting device side is exposed through the center support case 151, and the continuously variable transmission 154 is coaxial with the torque converter output shaft 153. A pulley input shaft 155 extending from the side faces. In the illustrated example, a planetary gear train 160 is provided on the pulley input shaft 155, a forward clutch (hydraulic multi-plate clutch) 161 is provided on the torque converter output shaft 153, and further, a peripheral portion of the planetary gear train 160 is provided. A reverse brake 162 is provided to constitute a main part of the forward / reverse switching device 150.
[0004]
In this forward / reverse switching device 150, the clutch drum 170 of the forward clutch 161 is formed integrally with the torque converter output shaft 153. A clutch piston 171 is slidably supported inside the clutch drum 170, and a gap surrounded by the clutch drum 170 and the clutch piston 171 is configured as a hydraulic chamber 172.
[0005]
The clutch drum 170 is provided with a groove 175 for bearing along the outer periphery of the torque converter output shaft 153. The groove 175 has an oil passage 176 communicating with the hydraulic chamber 172. I have.
[0006]
On the other hand, a hollow shaft 180 inserted into the concave groove 175 is formed to protrude from the center support case 151, and an annular groove 181 facing the oil passage 176 is provided around the outer periphery of the hollow shaft 180. Seal grooves 182 are provided on both sides of the annular groove 181, and the annular groove 181 is fluid-tightly connected to the oil passage 176 by seal rings 183 held in the respective seal grooves 182.
[0007]
Further, an oil passage 185 communicating with a hydraulic control valve unit (not shown) is provided inside the hollow shaft 180, and the oil passage 185 is opened in the annular groove 181, so that the hydraulic control valve unit and the hydraulic chamber 176 are connected to each other. Is formed.
[0008]
[Problems to be solved by the invention]
However, in the hydraulic circuit of the hydraulic multi-plate clutch having the above-described configuration, the oil passage on the clutch drum side and the oil passage on the hollow shaft side are made liquid-tight via two seal rings disposed on the outer periphery of the hollow shaft. Because of the communication configuration, it is necessary to cut and form an annular groove and two seal grooves on the hollow shaft, which may cause a reduction in workability and an increase in the length of the hollow shaft.
[0009]
In addition, the oil passage on the hollow shaft side requires oil passages in at least two directions: an oil hole extending along the axial direction of the hollow shaft and an oil hole opened in the annular groove perpendicular to the oil hole. Also, there is a possibility that the workability may be reduced.
[0010]
The present invention has been made in view of the above circumstances, and provides a hydraulic circuit of a hydraulic multi-plate clutch capable of fluidly communicating a relatively rotating clutch drum-side oil passage and a case-side oil passage with a simple configuration. The purpose is to provide.
[0011]
[Means for Solving the Problems]
In order to solve the above-mentioned problem, the invention according to claim 1 inserts a hollow shaft protruding from a case member into a groove for bearing provided around a clutch drum along a shaft portion. A hydraulic circuit of a hydraulic multi-plate clutch in which a drum-side oil passage formed in the clutch drum communicates with a case-side oil passage formed in the case member, wherein the concave groove and the outer periphery of the hollow shaft are connected to each other. With a first seal member, and the shaft portion and the inner periphery of the hollow shaft are liquid-tightly sealed with a second seal member to form an oil chamber in the groove. The drum-side oil passage and the case-side oil passage are opened in the oil chamber.
[0012]
According to a second aspect of the present invention, in the first aspect of the invention, the case-side oil passage is opened into the oil chamber at an end of the hollow shaft.
[0013]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. 1 and 2 relate to an embodiment of the present invention, FIG. 1 is a cross-sectional view of a main part of a forward / reverse switching device, and FIG. 2 is a skeleton diagram showing a schematic configuration of an automatic transmission in a developed state.
[0014]
First, a schematic configuration of an automatic transmission 1 having a built-in belt-type continuously variable transmission will be described with reference to FIG. As shown in the figure, the automatic transmission 1 includes a forward / reverse switching device 3 and a starting device 4 on an input side of a continuously variable transmission 2 and a main part thereof. An input side of the starting device 4 includes an engine. 10 are connected in series.
[0015]
The starting device 4 is accommodated in a main body case 20, and a drive plate 21 connected to the crankshaft 11 of the engine 10 is provided inside the main body case 20. A torque converter case 23 of a torque converter 22 is fixed to the drive plate 21, and a pump impeller 24 is connected to the torque converter case 23. A turbine runner 25 is connected to the pump impeller 24 via a fluid, and a torque converter output shaft 26 as a shaft connected to the turbine runner 25 extends toward the forward / reverse switching device 3.
[0016]
Further, a lock-up clutch 27 facing the torque converter case 23 is connected to the turbine runner 25. When the lock-up clutch 27 is engaged with the torque converter case 23, a lock-up state is established in which the driving force of the engine 10 is transmitted directly to the torque converter output shaft 26 via the turbine runner 25 without passing through the torque converter 22.
[0017]
A stator 28 for rectifying the fluid of the torque converter 22 is provided between the pump impeller 24 and the turbine runner 25, and the stator 28 is supported on a stator shaft 30 via a one-way clutch 29. Here, the stator shaft 30 is formed of a hollow member extending from a center support case 31 as a case member fixedly provided on the torque converter output side of the main body case 20 and internally supports the torque converter output shaft 26 therethrough. .
[0018]
An oil pan 32 is attached to a lower portion of the torque converter output side of the main body case 20, and an oil pump 33 is provided in the oil pan 32 integrally with the hydraulic control valve unit 34. A pump input shaft 35 extends from the oil pump 33, and the pump impeller 24 of the torque converter 22 is connected to the pump input shaft 35 via a chain system 36. Since FIG. 2 is a development view, the oil pan 32 is displayed in the upper part of the figure.
[0019]
The forward / reverse switching device 3 mediates power transmission between a torque converter output shaft 26 extending from the turbine runner 25 of the torque converter 22 and a pulley input shaft 51 extending from the primary pulley 50 of the continuously variable transmission 2. The main part includes a planetary gear train 41, a forward clutch 42, and a reverse brake 43 in a main body case 40 connected to the main body case 20 that houses the starting device 4.
[0020]
The continuously variable transmission 2 has a primary pulley 50, a secondary pulley 52 opposed to the primary pulley 50, and a belt 53 connecting the two pulleys 50 and 52, and supports the secondary pulley 52. A pulley output shaft 54 is connected to a differential device 63 mounted on a drive shaft 62 for a front wheel or a rear wheel via a reduction gear group 61 of a final reduction device 60.
[0021]
The primary pulley 50 includes a fixed sheave 50a integrally formed on a pulley input shaft 51 and a movable sheave 50b movable on the pulley input shaft 51 in the axial direction. A room 55 is provided. The secondary pulley 52 includes a fixed sheave 52a integrally formed on the pulley output shaft 54, and a movable sheave 52b movable in the axial direction on the pulley output shaft 54, and includes a movable sheave 52b. A secondary hydraulic chamber 56 is also provided.
[0022]
The primary hydraulic pressure is supplied to the primary hydraulic chamber 55, whereby the variable sheave 50b is variably operated to variably control the groove width between the two sheaves 50a, 50b. On the other hand, the secondary hydraulic pressure is supplied to the secondary hydraulic chamber 56, whereby the movable sheave 52b is variably operated to variably control the groove width between the sheaves 52a, 52b. In this case, in the continuously variable transmission 2, tension required for torque transmission is applied to the secondary pulley 52 by the secondary hydraulic pressure supplied to the secondary hydraulic chamber 56, and the primary hydraulic pressure supplied to the primary hydraulic chamber 55 The gear ratio is set. The primary hydraulic pressure and the secondary hydraulic pressure are set by a transmission control device (not shown) based on the engine operating state and the like, and are controlled through the hydraulic control valve unit 34.
[0023]
Next, a detailed configuration of the forward / reverse switching device 3 will be described with reference to FIG. As shown in the drawing, a torque converter output shaft 26 extending from the starting device 4 side faces the inside of the main body case 40, and is disposed on the same axis as the torque converter output shaft 26 in the continuously variable transmission 2 side. And a pulley input shaft 51 extended from the front.
[0024]
A planetary gear train 41 is provided on the pulley input shaft 51, and a forward clutch 42 is provided on the torque converter output shaft 26. Further, a reverse brake 43 is disposed adjacent to the forward clutch 42 around the planetary gear train 41.
[0025]
The planetary gear train 41 includes a sun gear 70 fixed to the pulley input shaft 51, a plurality of sets of pinions 71, 71 meshing with the sun gear 70, a planetary carrier 72 supporting the pinions 71, 71, and a pinion 71, 71. The ring gear 73 meshes with the sun gear 70 via the sun gear 70 to form a main part.
[0026]
The forward clutch 42 is constituted by a hydraulic multi-plate clutch, and includes a clutch drum 76 connected to the torque converter output shaft 26 and the planetary carrier 72, and a clutch fixed to the pulley input shaft 51 via the sun gear 70. And a hub 77.
[0027]
The outer periphery of the clutch hub 77 is opposed to the inner periphery of the clutch drum 76, and a plurality of drive plates 78 spline-fitted to the clutch drum 76 and a plurality of driven plates spline-fitted to the clutch hub 77 are interposed therebetween. The clutch portion 80 is configured by alternately arranging the plates 79.
[0028]
Further, inside the clutch drum 76, a piston 81 for pressing the clutch unit 80 is disposed closer to the starting device 4 than the clutch unit 80, and a gap surrounded by the piston 81 and the clutch drum 76 is It is configured as a chamber 82.
[0029]
Then, the operating oil pressure from the oil pressure control valve unit 34 is supplied to the oil pressure chamber 82 through an oil pressure circuit 100 described later, and when the piston 81 presses the clutch portion 80, the drive plate 78 and the driven plate 79 are engaged, and the forward clutch 42 is realized, and the output from the torque converter output shaft 26 is transmitted to the pulley input shaft 51.
[0030]
On the other hand, the reverse brake 43 is constituted by a hydraulic multi-plate brake, and has a brake drum 85 formed in the main body case 40 and a brake hub 86 fixed to the ring gear 73.
[0031]
The inner periphery of the brake drum 85 is opposed to the outer periphery of a brake hub 86, between which a plurality of driven plates 87 that are spline fitted to the brake drum 85 and a plurality of driven plates 87 that are spline fitted to the brake hub 86. The drive unit 88 and the drive plate 88 are alternately arranged to form a brake unit 89.
[0032]
Further, inside the brake drum 85, a piston 90 for pressing the brake portion 89 is disposed closer to the primary pulley 50 than the brake portion 89, and a gap surrounded by the piston 90 and the brake drum 85 forms a hydraulic chamber. 91.
[0033]
When hydraulic pressure from the hydraulic control valve unit 34 is supplied to the hydraulic chamber 91 and the piston 90 presses the brake part 89, the driven plate 87 and the drive plate 88 are engaged, and the reverse brake 43 is fastened. The output from the torque converter output shaft 26 is reversed by the planetary gear train 41 and transmitted to the pulley input shaft 51.
[0034]
Next, the hydraulic circuit 100 that supplies the operating hydraulic pressure from the hydraulic control valve unit 34 to the hydraulic chamber 82 of the forward clutch 42 will be described.
[0035]
The hydraulic circuit 100 includes a drum-side oil passage 101 formed in the clutch drum 76 and having a downstream side communicating with the hydraulic chamber 82, and a hydraulic control valve unit 34 formed in the center support case 31 and having an upstream side via the main body case 40 and the like. An oil chamber 103 formed between the clutch drum 76 and the center support case 31 is provided between the upstream side of the drum side oil path 101 and the downstream side of the case side oil path 102. The communication is performed to form a main part.
[0036]
More specifically, as shown in FIG. 1, a clutch drum 76 is formed integrally with the torque converter output shaft 26, and a concave groove for bearing is formed on the clutch drum 76 along the outer periphery of the torque converter output shaft 26. 105 is provided around.
[0037]
On the other hand, the hollow shaft 106 protrudes from the center support case 31. The hollow shaft 106 is inserted into the groove 105 along the outer circumference of the torque converter output shaft 26, and the end of the hollow shaft 106 is in contact with the bottom of the groove 105 via the thrust bearing 107.
[0038]
A seal groove 108 is provided on the outer periphery of the hollow shaft 106, and the seal groove 108 holds a seal ring 109 as a first seal member. The outer periphery of the hollow shaft 106 and the concave groove 105 are sealed in a liquid-tight manner by the seal ring 109.
[0039]
A bush 110 serving as a second seal member is provided on the inner periphery of the hollow shaft 106, and the inner periphery of the hollow shaft 106 and the torque converter output shaft 26 are liquid-tightly sealed by the bush 110.
[0040]
The interior of the concave groove 105 sealed by the seal ring 109 and the bush 110 is formed as an oil chamber 103, and the upstream of the drum-side oil passage 101 and the downstream of the case-side oil passage 102 are formed through the oil chamber 103. Is communicated. That is, the upstream side of the drum side oil passage 101 is opened on the outer peripheral surface of the concave groove 105 and communicates with the oil chamber 103, and the downstream side of the case side oil passage 102 is opened at the end of the hollow shaft 106. It communicates with the inside of the oil chamber 103. Here, a groove (not shown) is formed in the washer 107a on the side of the hollow shaft 106 constituting the thrust bearing 107, whereby the flow of hydraulic oil between the case-side oil passage 102 and the oil chamber 103 is ensured. I have.
[0041]
According to such an embodiment, the outer periphery of the hollow shaft 106 and the concave groove 105 are liquid-tightly sealed with the seal ring 109, and the inner periphery of the hollow shaft 106 and the torque converter output shaft 26 are liquid-tightly sealed with the bush 110. The oil chamber 103 is formed in the concave groove 105 and the upstream side of the drum-side oil passage 101 and the downstream side of the case-side oil passage 102 are opened in the oil chamber 103 so that the outer periphery of the hollow shaft 106 is formed. The drum side oil passage 101 and the case side oil passage 102 can be communicated with a simple configuration in which a single seal ring 109 is disposed.
[0042]
Therefore, the outer peripheral shape of the hollow shaft 106 can be simplified, thereby facilitating the processing and shortening the axial length of the hollow shaft 106.
[0043]
At this time, the seal between the inner periphery of the hollow shaft 106 and the torque converter output shaft 26 is also used by the bush 110 disposed therebetween, thereby simplifying the seal structure of the oil chamber 103 and reducing the cost. Can be.
[0044]
In addition, if the downstream side of the case-side oil passage 102 is opened to the end of the hollow shaft 106, an oil passage directed in the radial direction becomes unnecessary, and the shaft length of the hollow shaft 106 can be further reduced by the opening space. Further, the shape of the case-side oil passage 102 can be simplified.
[0045]
In this case, when the forward clutch 42 is engaged, a thrust force is generated on the clutch drum 76 by operating hydraulic pressure supplied from the end of the hollow shaft 106, and the clutch drum 76 is pressed against the pulley input shaft 51 side. Since the clutch drum 76 rotates integrally with the pulley input shaft 51 when the clutch 42 is engaged, the driving force is not lost between them.
[0046]
In the above-described embodiment, a seal ring or the like may be provided between the inner circumference of the hollow shaft 106 and the torque converter output shaft 26 to improve the sealing property therebetween.
[0047]
Also in this case, it is not necessary to dispose a plurality of seal rings or the like on the same peripheral surface (the outer periphery of the hollow shaft 106), so that the hollow shaft 106 can be prevented from being lengthened.
[0048]
In addition, since the seal ring and the like provided between the inner periphery of the hollow shaft 106 and the torque converter output shaft 26 need only be smaller in diameter than the seal ring provided on the outer periphery of the hollow shaft 106, Friction can be reduced as compared with a case where two seal rings are provided on the outer periphery of the, and an advantageous configuration can be obtained from the viewpoint of improving fuel efficiency and the like.
[0049]
【The invention's effect】
As described above, according to the present invention, the oil passage on the clutch drum side and the oil passage on the case side that rotate relative to each other can be connected in a liquid-tight manner with a simple configuration.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a main part of a forward / reverse switching device. FIG. 2 is a skeleton diagram showing an expanded schematic configuration of an automatic transmission. FIG. 3 is a cross-sectional view of a main part of a conventional forward / reverse switching device.
26… Torque converter output shaft (shaft)
31… Center support case (case member)
42… Forward clutch (hydraulic multi-plate clutch)
76 ... clutch drum 100 ... hydraulic circuit 101 ... drum side oil passage 102 ... case side oil passage 103 ... oil chamber 105 ... concave groove 106 ... hollow shaft 109 ... seal ring 110 ... bush

Claims (2)

A hollow shaft protruding from the case member is inserted into a bearing groove provided around the clutch drum along the shaft portion, and a drum-side oil passage formed in the clutch drum and the hollow shaft formed between the hollow shaft and the hollow shaft are formed therebetween. A hydraulic circuit of a hydraulic multi-plate clutch communicating with a case-side oil passage formed in a case member,
The concave groove and the outer periphery of the hollow shaft are liquid-tightly sealed by a first seal member, and the shaft portion and the inner periphery of the hollow shaft are liquid-tightly sealed by a second seal member. Forming an oil chamber in the groove,
A hydraulic circuit for a hydraulic multi-plate clutch, wherein the drum-side oil passage and the case-side oil passage are opened in the oil chamber. 2. The hydraulic circuit for a hydraulic multi-plate clutch according to claim 1, wherein the case-side oil passage is opened into the oil chamber at an end of the hollow shaft.

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