JPH0134746Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a hydraulic pressure control device for a frictional engagement device. More specifically, the present invention relates to a hydraulic pressure control device for a friction engagement device of a brake device or a clutch device used in a transmission such as an automatic transmission.

[Prior art]

Automatic transmissions installed in automobiles and other vehicles generally use brake devices and clutch devices formed by frictional engagement devices (Japanese Patent Publication No. 51-10315).
issue).

The frictional engagement device is pressed by a piston, and the piston is slidably fitted into the cylinder. A chamber is formed between the cylinder and the piston, and when hydraulic pressure is supplied to the chamber, the piston is actuated and the frictional engagement device is brought into engagement.

By the way, this type of frictional engagement device is brought into a frictional engagement state in order to establish a predetermined speed change state, and the actuation of the piston to the frictional engagement state quickly closes the clearance. It is generally considered preferable to thereby bring the frictional engagement device into the engaged state to complete the speed change operation, and then maintain the frictional engagement state with a strong pressing force.

In order to achieve this preferable operation, the chamber for actuating the piston is divided into a first chamber and a second chamber.
A system has been proposed in which the hydraulic pressure is divided into two chambers and hydraulic pressure is supplied from the first chamber to the second chamber (unknown prior to the filing of this application).

In this case, the first chamber is formed as a small-volume annular chamber at a radially inner position, and the second chamber is formed as a large-volume annular chamber at a radially outer position. Then, the first chamber and the second chamber
A communication path of small holes is formed between the chambers. Therefore, the hydraulic pressure is first supplied to the first chamber, and the hydraulic pressure supplied to the first chamber is supplied to the second chamber via the communication path.
Therefore, the piston is first quickly operated to close the clearance of the friction engagement device by the hydraulic pressure supplied to the first chamber with a small capacity.
The frictional engagement device is brought into engagement. Thereafter, the hydraulic pressure supplied to the large-capacity second chamber is also applied, and the engaged state is maintained with a strong pressing force.

By the way, the above-mentioned deactivation of the frictional engagement device is
This is done by the following action. That is, first, the working pressure of the first chamber is exhausted, and then the working pressure of the second chamber is exhausted from the first chamber through the communication path, thereby enabling the return operation of the piston. Ru.

However, at this time, since the communication path through which the hydraulic pressure is returned from the second chamber to the first chamber is formed in a small hole, the hydraulic pressure of the second chamber cannot be discharged smoothly. This may cause an inconvenience in that the return operation of the piston is delayed. For example, when the oil temperature is low, the viscosity of the oil is high, so the resistance passing through the communication path of the small holes is large and the return of the oil pressure is slow. Furthermore, even at high rotations, the centrifugal force acts strongly, which may slow the return of hydraulic pressure.

Note that the communication path between the first chamber and the second chamber is designed to delay the supply of hydraulic pressure from the first chamber to the second chamber during operation.
It is necessary to form a small hole to serve as an orifice, which causes the above-mentioned inconvenience when the operation is released.

In addition, there have been conventional pistons equipped with a check ball to eliminate residual pressure in the chamber (for example, Japanese Patent Publication No. 51-10315); however,
This check ball opens due to centrifugal force when the oil pressure in the chamber is removed and the pressure drops below a certain level, allowing the residual oil pressure inside the chamber to be removed to the outside of the chamber.This check ball comes into play when the piston returns. Therefore, even if the piston is provided with a check ball, the above-mentioned problem that the return operation of the piston is delayed occurs.

[Purpose of invention]

Therefore, an object of the present invention is to eliminate the delay in the return operation of the piston by increasing the flow area from the second chamber to the first chamber.

[Structure of the idea]

In order to achieve this purpose, in the hydraulic pressure control device for a frictional engagement device of the present invention, in the hydraulic pressure control device for a frictional engagement device of this type described above, the hydraulic pressure control device is divided by a partition part integral with the cylinder. A drain passage is provided between the first chamber and the second chamber in addition to the communication passage, and a thin plate-shaped valve body is rotatably attached at one end of the drain passage to the opening of the first chamber. A leaf valve supported by the drain passage is provided, and the drain passage is allowed to flow only from the second chamber toward the first chamber.

As a result, when the piston returns when the frictional engagement device is released from operation, the return of the hydraulic pressure from the second chamber to the first chamber is performed through both the drain passage and the communication passage. Therefore, the flow area is increased compared to the case where the supply from the first chamber to the second chamber is performed only through the communication path during operation of the frictional engagement device.

[Effect of idea]

As mentioned above, the present invention increases the flow area from the second chamber to the first chamber when the piston returns, so it can be used when the oil temperature is low and the oil is highly viscous, or when the oil is at high rotation. Even when a strong centrifugal force acts, the hydraulic pressure is returned relatively smoothly from the second chamber to the first chamber. As a result, the piston returns smoothly and there is no delay.

Also, connect the drain passage from the second chamber to the first chamber.
As a means of allowing distribution only to chambers of
Although it is conceivable to provide a check ball, in this case, rotational centrifugal force acts on the check ball, which has the disadvantage that there are restrictions on how the check ball can be arranged. On the other hand, in the case of the leaf valve of the present invention, rotational centrifugal force does not have much influence, so there are fewer restrictions on the arrangement.

Note that when the frictional engagement device is activated, the hydraulic pressure is supplied from the first chamber to the second chamber only through the communication path, as in the past.
Preferable frictional engagement operation can be performed as before.

〔Example〕

Hereinafter, embodiments of the present invention will be described based on the drawings.

1 and 2 show an embodiment of a hydraulic pressure control device for a frictional engagement device according to the present invention. This embodiment shows a case where the frictional engagement device is a clutch device.

A piston 12 is slidably fitted into the cylinder 10. The cylinder 10 is the clutch drum 11
and a shaft end portion 41 of the rotating shaft 40 are connected to each other. The cylinder 10 is provided with a partition part 14, and a first chamber 16 and a second chamber 18 are formed between the cylinder 10 and the piston 12, separated by the partition part 14. The first chamber 16 is located radially inward and is formed into a small volume annular chamber. The second chamber 18 is located radially outward and is formed into a large volume annular chamber.

A communication passage 20 is provided in the partition part 14 of the cylinder 10.
(shown in the lower half of Figure 1)
The first chamber 16 and the second chamber 18 are in communication with each other. The communication path 20 is formed in a small hole. The partition portion 14 is also provided with a drain passage 22 (shown in the upper half of FIG. 1). This drain passage 22 is also provided between the second chamber 18 and the first chamber 16.

As best shown in FIG. 2, a leaf valve 2 is provided at the opening of the first chamber 16 of the drain passage 22.
4 are provided. This leaf valve 24 has a structure in which a thin plate-shaped valve body is rotatably supported at one end thereof, and thereby the drain passage 22 is connected to the second
Flow is allowed only in the direction from the first chamber 18 to the first chamber 16. Therefore, from the first chamber 16 to the second chamber 18
Traffic in this direction is becoming blocked.

The support point 25 of the leaf valve 24 is preferably located to the right of the drain passage 22 as viewed in FIG. Leaf valve 24 when opened
This is to prevent the free end of the piston 12 from coming into contact with the piston 12. Moreover, the leaf valve 24 is chamfered and attached.

The rotating shaft 40 is provided with a supply oil passage 42 for hydraulic pressure. The working oil pressure of the supply oil passage 42 is guided to the first chamber 16 via the supply oil passage 44.

A spring seat 46 is fixedly attached to the tip portion 40a of the rotating shaft 40. A return spring 4 formed of a coil spring is provided between this spring seat 46 and a spring seat 56 seated on the piston 12.
8 is interposed. This return spring 4
8 always urges the piston 12 in the left direction as seen in FIG. Therefore, when hydraulic pressure is not supplied to the first chamber 16 and the second chamber 18, the piston 12 is in a position in contact with the side wall 10a of the cylinder 10 as shown in FIG. 12 is in the returned state.

In addition, in FIG. 1, the seal rings 26 and 28 attached to the piston 12 and the seal ring 30 attached to the partition portion 14 ensure an oil-tight state of the first chamber 16 and the second chamber 18. , prevents hydraulic pressure from leaking to other areas.

The friction engagement device 32 is formed by a large number of friction materials 34 and disk plates 36 arranged alternately. That is, it is formed in a multi-plate format. As is well known, each friction member 34 is attached to the hub 52 of another rotation transmitting member 50 at its inner peripheral portion by claw coupling, so that the friction member 34 is integral with the hub 52 in the rotational direction but movable in the axial direction. Similarly, each disk plate 3
6 is attached at its outer peripheral portion to the outer peripheral wall portion 10b of the cylinder 10 by a claw connection so as to be integral in the rotational direction but movable in the axial direction.

The frictional engagement device 32 is connected to the outer peripheral wall 1 of the cylinder 10.
It is stopped by a snap spring 54 attached to 0b to prevent it from slipping out. Also,
A disk spring 38 is disposed on the side of the frictional engagement device 32 that comes into contact with the piston 12.

The frictional engagement device 32 is pressed by the piston 12, and when a frictional force is generated between the disk plate 36 and the friction material 34, the frictional engagement device 32 enters a frictional engagement state and brings the rotation shaft 42 and the rotation transmission member 50 into a rotation transmission state. do. Then, by returning the piston 12, the frictional engagement state of the frictional engagement device 32 is released, and the rotating shaft 40 and the rotation transmission member 50 are disconnected.

Next, the effect will be explained.

First, the first chamber 16 and the second chamber 1
The flow of hydraulic pressure between the 8 parts is carried out as follows.
When hydraulic pressure is supplied from the first chamber 16 to the second chamber 18, the drain passage 22 is blocked by the leaf valve 24, so that it is carried out only through the communication passage 20. Conversely, when the working pressure is returned from the second chamber 18 to the first chamber 16, the leaf valve 24 is also in the flowing state, so this is done through both the drain passage 22 and the communication passage 20.

Therefore, when the frictional engagement device 32 is in the frictional engagement state, the hydraulic pressure is applied to the supply oil passages 42 and 44.
When supplied to the first chamber 16 from
The hydraulic pressure supplied to the first chamber 16 is supplied to the second chamber through the communication passage 20. The piston 12 is actuated by the hydraulic pressure supplied to both chambers 16 and 18, and the friction engagement device 3
2 is pressed into a frictionally engaged state.

Note that at this time, the piston 12 is operated by the hydraulic pressure supplied to the first chamber 16 because the hydraulic pressure is first supplied to the first chamber 16 . Since the first chamber 16 has a small capacity, a large stroke operation is quickly performed with a small amount of hydraulic pressure, and this operation closes the clearance of the friction engagement device 32, resulting in a friction engagement state that achieves a gear shift state. do. Next, when the second chamber 18 is filled with the working oil pressure supplied through the communication passage 20, the piston 12 is also pressurized with the working oil pressure by the second chamber 18, causing a strong push. Frictional engagement device 32 with pressure
This state of frictional engagement is maintained with a strong pressing force, so that the frictional engagement device 32 is in a perfect state of frictional engagement without slipping.

The timing of transition of the frictional engagement device 32 from the frictional engagement state that achieves the speed change state to the complete frictional engagement state is determined by the size of the communication path 20. The communication path 20 is generally a small hole, and the transition timing is suitable. This also helps to reduce the shift shock.

When the frictional engagement state of the frictional engagement device 32 is released, the working oil pressure of the supply oil passage 42 is set to a discharge pressure state. Then, the hydraulic pressure in the second chamber 18 passes through the first chamber 16 to the supply oil passages 44, 4.
2 will be eliminated. At this time, the second chamber 18
Since the flow from the pump to the second chamber 16 is carried out through both the communication passage 20 and the drain passage 22, the hydraulic pressure in the second chamber 18 is quickly removed.

Therefore, even when the oil temperature is low and the oil is highly viscous, or when centrifugal force is strong at high rotations,
Compared to the case of only the conventional communication passage 20, the hydraulic pressure in the second chamber 18 is removed relatively quickly.

As a result, the return operation of the piston 12 is quickly performed, and there is no delay as in the conventional case.

Although the present invention has been described above with reference to specific embodiments illustrated, the present invention is not limited to these embodiments, and various other embodiments are possible within the scope of the present invention.

For example, the communication passage 20 and the drain passage 22
is the partition part 1 of the cylinder 10 in the above-mentioned embodiment.
4, but it can also be provided on the piston 12.

[Brief explanation of the drawing]

FIG. 1 and FIG. 2 show an embodiment of the hydraulic pressure control device for a frictional engagement device according to the present invention.
The figure is a sectional view, and FIG. 2 is an enlarged sectional view showing a drain passage portion. Explanation of symbols, 10... Cylinder, 12... Piston, 16... First chamber, 18... Second chamber, 20... Communication passage, 22... Drain passage, 24...
Leaf valve, 32...Frictional engagement device.

Claims (1)

[Claims for Utility Model Registration] A first chamber in which a piston that operates a frictional engagement device is slidably fitted into a cylinder, and a hydraulic pressure is supplied between the piston and the cylinder to operate the piston. A second chamber is defined by a partition portion integral with the cylinder, and a communication path is provided in the partition portion or the piston to communicate the first chamber and the second chamber. In a hydraulic pressure control device for a friction engagement device in which hydraulic pressure supplied to one chamber is supplied to a second chamber via a communication path, the partition portion or the piston is connected to the first chamber separately from the communication path. A drain passage communicating with the second chamber is provided, and the opening of the first chamber of the drain passage has a thin plate shape that allows hydraulic pressure to flow only from the second chamber to the first chamber. 1. A hydraulic pressure control device for a frictional engagement device, comprising a leaf valve rotatably supporting a valve body at one end thereof.