JPS6321840B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a variable displacement rotary vane pump useful as an oil pump for automatic transmissions, a compressor for air conditioners, and the like.

This kind of rotary vane pump has a cam ring,
A rotor eccentrically placed inside this cam ring,
A plurality of vanes are provided on the rotor so as to be movable in a radial direction and are in sliding contact with the inner circumferential surface of the cam ring, and the volume of a pump chamber between adjacent vanes is changed by relative rotation of the cam ring and the rotor to perform a pumping action. Let's do it. In such a rotary vane pump, by displacing the cam ring and changing the eccentricity of the cam ring and the rotor, the volume change rate of each pump chamber during the relative rotation changes, thereby changing the discharge amount. It can be.

However, in conventional variable displacement rotary vane pumps, when changing the amount of eccentricity mentioned above, for example,
As disclosed in Japanese Patent No. 53-6724, in most cases this is accomplished using a separate actuator that responds to the displacement control pressure. Therefore, an actuator as a separate unit is required, which increases the size, making it difficult to secure installation space, and also tends to be expensive due to the increased number of parts.

Therefore, as shown in Japanese Unexamined Patent Publication No. 17696/1984, the cam ring itself is configured as a rotating piston, and by rotating and displacing this in response to the displacement control pressure, the amount of eccentricity between the cam ring and the rotor can be varied. A variable displacement rotary vane pump was proposed earlier.

However, in this rotary vane pump, the displacement control pressure is applied directly to the cam ring, so the cam ring needs to be thicker to withstand the control pressure, and the pump has a larger diameter around the entire circumference. However, in terms of miniaturization, it is not much different from the method using the separate actuator described above.

In the present invention, the cam ring itself is not configured as a piston, but a piston that responds to the displacement control pressure is separately provided, and if the piston displaces the cam ring and changes the eccentricity, the cam ring does not receive the displacement control pressure directly. It is no longer necessary to increase the wall thickness of the piston, and therefore the pump can be avoided from having a large diameter all around it, and only the part where the piston is installed, which is separately provided above, bulges out, making the pump more compact. From the viewpoint that this objective can be fully achieved, the present invention aims to provide a variable displacement rotary vane pump characterized by the above-mentioned configuration.

In addition, in the present invention, the piston is slidable in the direction of displacement of the cam ring, one end of the piston is pivotally supported by the housing, and the remaining portion is brought into contact with the cam ring, so that the displacement of the cam ring is caused by the rocking of the piston. The configuration is configured to perform the following. With this configuration, by changing the contact point of the piston with respect to the cam ring and appropriately selecting the lever ratio, the pump can be adapted to various uses, and the pump can be made with one small piston without increasing the size of the pump. It is possible to displace the cam ring even with only one piston, and there is no need for a plurality of pistons, so the pump can be downsized without becoming complicated or increasing cost.

Hereinafter, the present invention will be explained in detail with reference to illustrated embodiments.

The drawing shows an embodiment of the present invention, in which 1 shows a pump housing and 2 shows a pump cover that closes openings at both ends of the pump housing, and these pump covers 2 are attached to the pump housing 1 by bolt and nut means 3. These define a space 4 in which the following components are housed.

That is, a cam ring 5 is disposed within the space 4, this cam ring is rotatably supported at one point on its outer circumference by a pivot pin 6, and this pivot pin is installed between the pump covers 2. Further, the width of the cam ring 5 is made equal to the width of the pump housing 1, thereby bringing both end surfaces of the cam ring 5 into close contact with the corresponding pump cover 2.

A rotor 7 is disposed within the cam ring 5, and a pump drive shaft 8 is coaxially and integrally connected to the rotor. axis 8
is rotatably supported by both pump covers 2, and has one end protruding from the corresponding pump cover 2, so that pump drive energy can be input from this end, and the rotor 7 is rotationally driven in the direction of the arrow in the figure via the shaft 8. do what you can. Further, the width of the rotor 7 is made equal to the width of the pump housing 1, so that both end surfaces of the rotor 7 are brought into close contact with the corresponding pump cover 2.

A plurality of vanes 9 (nine in the illustrated example) are provided on the rotor 7 so as to be able to move forward and backward in the radial direction, and each of these vanes is urged outward in the radial direction by a ring 10 in an annular recess 7a formed on both end surfaces of the rotor 7. At the same time, the width of each vane 9 is made equal to the width of the pump housing 1 so that both sides of each vane 9 are brought into close contact with the corresponding pump cover 2, thereby reducing the distance between adjacent vanes 9. Pump room 1
Set 1.

A piston 12 is further disposed within the space 4 on one side in the direction of rotation of the cam ring 5 about the pivot pin 6.
A piston ring 13 is provided around the circumference of the piston.
is connected to the wall of the cavity 4 to form the pressure chamber 14.
Define. The piston 12 has one end rotatably supported by a pivot pin 15 horizontally suspended between the pump covers 2 to form a rotating piston, and the other end abuts against the outer circumferential projection 5a of the cam ring 5.

In order to maintain this collision, an arm 5b extending radially outward is integrally provided on the cam ring 5, and
A return spring 16 is compressed between the arm and the pump housing 1 to urge the cam ring 5 to rotate in the counterclockwise direction in the figure. In addition, cam ring 5
It is assumed that at the rotational position shown in the figure, the center O ₁ is offset from the center O ₂ of the rotor 7, and the cam ring 5 is eccentric with respect to the rotor 7.

The pump cover 2 also has a pump suction port 2a.
, a pump discharge port 2b, and a capacity control pressure input port 2c.

The operation of the pump of the present invention having the above-mentioned structure will be explained next.

In the steady state shown, when the rotor 7 is rotationally driven in the direction of the arrow, the pump chamber 11 increases in volume while moving from diagonally lower right to upper left in the diagram due to the eccentricity between the cam ring 5 and rotor 7. During this time, fluid is sucked from port 2a. Then, while the rotor 7 is being driven to rotate, the pump chamber 11 moves from diagonally upward to the left to downwardly to the right in the figure, causing a volume reduction and discharging suction fluid from the port 2b. By repeating this action, fluid is continuously sucked and discharged, and a predetermined pumping action is obtained.

By the way, in the illustrated steady state, since the amount of eccentricity between the cam ring 5 and the rotor 7 is maximum, the rate of change in volume of the pump chamber 11 is also maximum, and the pump discharge amount (capacity) is maximum.

If the pump capacity becomes too large, port 2c
Excessive volume control pressure is supplied to the pressure chamber 14 from
5 in the direction of the hour hand in the figure against the return spring 16. As a result, the cam ring 5 is rotated in the same direction around the pivot pin 6 via the protrusion 5a, and as a result, the center _O1 of the cam ring 5 approaches the center _O2 of the rotor 7, and the amount of eccentricity between the two is reduced. . Thus, the rate of change in volume of the pump chamber 11 becomes smaller, and the pump capacity is reduced accordingly and controlled to a predetermined value.

Thereafter, when the pump capacity becomes insufficient, the capacity control pressure in the pressure chamber 14 is reduced by the amount of the insufficient capacity, and the cam ring 5 and piston 12 are thereby rotated back by the return spring 16. As a result, the center O ₁ of the cam ring 5 is the center O ₂ of the rotor 7.
As the eccentricity between the two increases, the pump capacity is increased to compensate for the shortage and is controlled to a predetermined value.

Thus, in the variable displacement rotary vane pump of the present invention, the piston 12 that responds to the displacement control pressure is placed in the same housing cavity 4 as the cam ring 5, as described above.
The piston 12 is slidably fitted in the displacement direction of the cam ring, and one end of the piston 12 is pivotally supported on the housing.
The predetermined portion of the remaining portion is brought into contact with the cam ring 5, and the cam ring 5 is displaced by the rocking of the piston 12 to change the amount of eccentricity between the cam ring 5 and the rotor 7, thereby making it possible to change the pump capacity. It is not subject to capacity control pressure, and there is no need to increase its wall thickness. Therefore, it is possible to avoid increasing the diameter of the pump over the entire circumference, and it is only necessary to expand the piston 12 at a minimum.
The objective of downsizing the pump is also fully achievable. In addition, by changing the contact point of the piston 12 with respect to the cam ring 5 and appropriately selecting the lever ratio, the pump can be adapted to various uses, and there is only one small piston 12 without increasing the size of the pump. However, since the cam ring 5 can be displaced and a plurality of pistons 12 are not required, the pump can be downsized without becoming complicated or increasing in cost.

[Brief explanation of drawings]

The drawing is a partially cutaway front view of the variable displacement rotary vane pump of the present invention. 1...Pump housing, 2...Pump cover, 2a...Suction port, 2b...Discharge port,
2c... Capacity control pressure inlet port, 5... Cam ring, 5a... Cam ring outer peripheral projection, 5b... Cam ring arm, 6... Pivot pin, 7... Rotor,
7a...Annular recess, 8...Pump drive shaft, 9...
Vane, 10...Ring, 11...Pump chamber, 1
2... Piston, 13... Piston ring, 14
...Pressure chamber, 15...Pivot pin, 16...Return spring.

Claims (1)

[Claims] 1 A cam ring in a housing, a rotor eccentrically arranged in the cam ring, and a plurality of vanes provided on the rotor so as to be movable in a radial direction and in sliding contact with the inner circumferential surface of the cam ring, the cam ring and the rotor In a variable displacement rotary vane pump, the volume of the pump chamber between adjacent vanes is changed by the relative rotation of the vanes to perform a pumping action, and the displacement of the cam ring allows the displacement to be changed by changing the amount of eccentricity. A piston is disposed in the same hollow space in the housing as the cam ring, and is fitted to be slidable in the direction of displacement of the cam ring.One end of the piston is pivotally supported in the housing, and the remaining predetermined portion is brought into contact with the cam ring. A variable capacity rotary vane pump characterized in that a cam ring is displaced by the rocking motion of the rotary vane pump.