VANE PUMP

Abstract

A vane pump can effectively utilize the total quantity of a working fluid delivered from a vane section. The pump can be used for fluid pressure operated equipment requiring a high flow rate, does not create torque loss due to a throttle valve, and can prevent the occurrence of cavitation caused by a shortage of suction. The vane pump pressurizes and delivers a working fluid through a vane section. A returning working fluid flowing through a return port is throttled and accelerated by a throttle valve, and a working fluid sent from a suction port is attracted by the accelerated returning working fluid so that the returning working fluid and the working fluid sent from a tank are sent into the vane section.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1( a) is a sectional view showing one example of a vane pump in accordance with the present invention, illustrated as being cut in the shaft center, and FIG. 1(b) is a sectional view taken along the line A-A of FIG. 1(a);

FIG. 2 is a fluid pressure circuit diagram showing fluid pressure-operated equipment using the vane pump shown in FIG. 1;

FIG. 3 is a sectional view showing another example of a vane pump in accordance with the present invention;

FIG. 4 is a fluid pressure circuit diagram showing fluid pressure-operated equipment using the vane pump shown in FIG. 3;

FIG. 5( a) is a sectional view showing one example of a vane pump that is background art to the present invention, showed in section through the shaft center, and FIG. 5(b) is a sectional view taken along the line B-B of FIG. 5(a); and

FIG. 6 is a sectional view of the essential portion of a vane pump, showing another example of a vane pump that is background art to the present invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Embodiments (examples) of the present invention will now be described with reference to the accompanying drawings.

FIG. 1( a) is a sectional view showing one example of a vane pump in accordance with the present invention, showing by being cut in the shaft center, and FIG. 1(b) is a sectional view taken along the line A-A of FIG. 1(a).

The vane pump 10 shown in FIG. 1 is used for supplying a working fluid to an active stabilizer, etc. for an automobile, etc. The vane pump 10 includes a suction port 3 for drawing the working fluid to be sent to a vane section 7 from a tank (not shown), a delivery port 2 for delivering the working fluid pressurized in the vane section 7, and additionally a return port 1 for receiving the working fluid that has been delivered from the delivery port 2, after its use and upon its return. This is a first feature of the vane pump 10.

Also, in the vane pump 10, the returning working fluid flowing in through the return port 1 is throttled by a throttle valve 4 provided in a return passage 1a and is accelerated. The working fluid sent from the suction port 3 is attracted by the accelerated returning working fluid so that the returning working fluid and the working fluid sent from the tank are sent into the vane section 7 by conduits 3a and 3b. This is a second feature of the vane pump 10.

In addition, the vane pump 10 includes a rotor 7a, vanes 7b capable of moving in and out with respect to the rotor 7a, a cam ring 7c that includes an inner peripheral surface with which the vanes 7b that project from the rotor 7a come into contact, a cover 8a and a side plate 8b that confine both sides of the rotor 7a, etc., and a body 8 that houses these elements, which provide the pumping function and thereby allow the vane pump 10 to function as a vane pump.

The rotor 7a, the vanes 7b, and the cam ring 7c collectively form the vane section 7. The pumping function of the vane section 7 is the same as that of an ordinary vane pump like the vane pump 20 shown in FIG. 5, which is background art, and detailed explanation thereof is thus omitted.

The return port 1, the delivery port 2, the suction port 3, the throttle valve 4, and the like, which are features of the vane pump 10, are explained in more detail below.

First, the vane pump 10 does not include a flow control valve of the type that has been provided conventionally at the delivery port 2. All of the high-pressure working fluid QO delivered from the vane section 7 is supplied from the delivery port 2 to the fluid pressure-operated equipment (not shown), which is connected to the delivery port 2 via a delivery passage (not shown).

This point can be confirmed by the fact that in FIG. 1(b), the delivery port 2 does not communicate with the suction port 3, and the reflux path 14 that is provided in the vane pump 20 shown in FIG. 5, which is the background art, is absent.

Therefore, the vane pump 10 uses the working fluid efficiently so that the vane pump 10 can be used for fluid pressure-operated equipment that requires a high flow-rate of working fluid, such as an active stabilizer.

Also, the flow control valve is absent from the vane pump 10 described above. Accordingly, a throttle valve for throttling the working fluid QO delivered from the delivery port 2, which has been explained above in the context of the background art, is also absent, so that the loss of driving torque in the vane pump 10 is thereby eliminated.

The return port 1 communicates with the conduit 3a in which the suction port 3 is open via the throttle valve 4 provided in the return passage 1a. The conduit 3a communicates with the conduit 3b which is provided on the cover 8a for sending the working fluid into the vane section 7.

As the figure illustrates, a returning working fluid QR is throttled and accelerated by the throttle valve 4, and passes through the conduit 3a near the suction port 3 in this state. A negative pressure is therefore produced near the suction port 3, and thus the working fluid is pulled from the tank.

Both of the working fluid QT that is drawn from the tank and the returning working fluid QR are sent into the vane section 7 after passing through the conduits 3a and 3b.

Therefore, in the vane pump 10, even in the case of high-speed rotation, in addition to the returning working fluid QR that has been delivered and returned, the working fluid QT drawn from the tank is sent into the pump 10 as necessary. A negative pressure is thus avoided on the suction side, which prevents cavitation in the fluid.

Accordingly, the vane pump 10 can effectively utilize the total quantity of the working fluid delivered from the vane section 7, can be used for fluid pressure-operated equipment that requires a high flow rate, does not create a torque loss due to the throttle valve, and can prevent the occurrence of cavitation caused by a shortage of suction.

In the vane pump 10, with respect to the conduit 3a, the returning working fluid QR that has passed through the throttle valve 4 from the return port 1 and which has been accelerated, and the drawn working fluid QT attracted by the returning working fluid QR pass through the straight line shaped conduit 3a, so that the working fluids are accelerated more efficiently and are supplied to the vane section 7 with a low loss caused by flow path resistance.

Also, the return port 1, the throttle valve 4, the suction port 3, and the conduits 3a and 3b are located in the same pump 10 and close to each other, so that efficiency is improved accordingly.

Further, the tank (not shown) need not necessarily be provided close to the pump 10, so that the arrangement of the vane pump 10 can be considered without much regard to the position of the tank, and hence the degree of design freedom becomes high.

FIG. 2 is a fluid pressure circuit diagram showing fluid pressure operated equipment using the vane pump shown in FIG. 1. In FIG. 2, the same symbols are applied to the elements already explained above, and duplicated explanation is omitted.

This fluid pressure circuit diagram shows an active stabilizer ST for preventing rolling, etc. of an automobile. The active stabilizer ST includes the vane pump 10, which is driven by an automotive engine ENG, a tank T connected to the suction port 3 of the vane pump 10, a pressure control valve PV provided in parallel in a conduit leading from the delivery port 2 to the return port 1 of the vane pump 10, a check valve GV, a directional selecting valve DV, and a single rod type fluid pressure cylinder CY connected to the output side of the directional selecting valve DV

As one example, either one of the cylinder side and the rod side of the fluid pressure cylinder CY is connected to the stabilizer and the other thereof is connected to a link arranged so as to project from the stabilizer so that the rolling of a vehicle body is controlled by the fluid pressure cylinder CY, which thereby provides the function of the active stabilizer ST.

When the vane pump 10 is used as a part of the active stabilizer ST, the vane pump 10 can supply a high flow rate of working fluid as required, and can fully perform the function of the active stabilizer ST without producing cavitation.

In the case where the vane pump 10 is used to circulatingly supply the working fluid to the fluid pressure cylinder CY of a single rod type, as in this example, an excess and a deficiency of the circulating working fluid take place between the case where the cylinder CY extends and the case where the cylinder CY contracts. When the working fluid is in short supply, the necessary working fluid is drawn from the tank T via the suction port 3, and when the working fluid is in excess, the excess working fluid is returned to the tank T via the suction port 3. The vane pump 10 in accordance with the present invention is thus suitable in this respect as well.

Also, in the case where the vane pump 10 in accordance with the present invention is used, the total quantity of the working fluid QO delivered from the delivery port 2 becomes, in principle, the same as that of the returning working fluid QR. However, depending on the type of fluid pressure-operated equipment, in some cases it is better to utilize some of the working fluid QO for other applications in the equipment. The working fluid used for such an objective can be returned to the tank T by another circuit such as a drain circuit.]

Therefore, in such a case, the total quantity of the working fluid QO delivered is sometimes not the same as that of the returning working fluid QR. However, the working fluid is nevertheless utilized effectively on the fluid-pressure operated equipment side.

FIG. 3 is a sectional view showing another example of the vane pump in accordance with the present invention. This sectional view is a sectional view of the same portion of the vane pump of another example as that shown in FIG. 1(b). FIG. 4 is a fluid pressure circuit diagram showing fluid pressure operated equipment using the vane pump shown in FIG. 3.

This vane pump 10A differs from the vane pump 10 shown in FIG. 1 in that a throttle valve 4A is not of a fixed type, but is instead a variable throttle valve 4A configured so that the opening amount of the throttle increases as the flow rate of the returning working fluid QR increases.

Also, the vane pump 10A differs from the vane pump 10 in that both of a return port 1A and a delivery port 2A have a construction corresponding to the variable throttle valve 4A, because of a space occupied by the throttle valve 4A in the body 8b.

The variable throttle valve 4A includes a valve element 4a, which slides when acted upon by the returning working fluid QR, a valve housing portion 4g, one side of which is open, and which slidably houses the valve element 4a, a lid 4i that closes the open side of the valve housing portion 4g, a spring 4h held between the lid 4i and the valve element 4a to urge the valve element 4a to the closed side of the valve housing portion 4g with respect to the lid 4i, and a communication path 4j that allows the conduit 3a and the valve housing portion 4g to communicate with each other.

The valve element 4a is, as a whole, of a spool shape, one end of which has a small diameter. The valve element 4a includes a small-diameter convex portion 4b that has the small diameter, a spool portion 4c that is continuous with the small-diameter convex portion 4b and which has a fluid-tight outside diameter with respect to the inside diameter of the valve housing portion 4g, and a spring receiving portion 4d that is continuous with the spool portion 4c and which has a diameter smaller than the spool portion 4c so that the spring 4h fits on the outer periphery thereof.

The valve housing portion 4g allows the return port 1A and the conduit 3a to communicate with each other when the valve element 4a is absent. When the returning working fluid QR is absent and thus the valve element 4a is still urged by the spring 4h, however, the small-diameter convex portion 4b comes into contact with the closed side. When this is the case, the return port 1A and the conduit 3a are not allowed to communicate with each other by the spool portion 4c, or at least the degree of communication is kept low.

The communication path 4j allows the conduit 3a and a portion in which the spring receiving portion 4d of the valve element 4a is located under the valve housing portion 4g to communicate with each other. Therefore, the returning working fluid QR acts on the small-diameter convex portion 4b side of the valve element 4a via the communication path 4j, and the working fluid in the conduit 3a acts on the spring receiving portion 4d side, so that a balance is maintained with the urging force of the spring 4h.

According to the variable throttle valve 4A configured as described above, even if the returning working fluid QR flows in from the return port 1A, in the case where the flow rate thereof is low, the valve element 4a moves slightly downward in FIG. 3 so as to be in balance with the spring 4h, which causes the returning working fluid QR to be supplied to the conduit 3a in a more throttled state. The more throttled working fluid QR draws the working fluid QT from the suction port 3 at a higher speed.

On the other hand, if the flow rate of the returning working fluid QR from the return port 1A increases, the valve element 4a balances in a more opened state, so that the returning working fluid QR is supplied to the conduit 3a in a more un-throttled state.

Thus, the throttle opening amount of the variable throttle valve 4A increases as the flow rate of the returning working fluid QR increases.

In the vane pump 10A with the variable throttle valve 4A as described above, when the flow rate of the returning working fluid QR is low, the throttle valve 4A is throttled, so that the flow velocity of the returning working fluid QR increases. On the other hand, as the flow rate thereof increases, the throttle valve 4A is opened, so that the pressure of the returning working fluid QR on the return port 1A side can be prevented from rising excessively.

An active stabilizer ST′ shown in FIG. 4 differs from the active stabilizer ST shown in FIG. 2 in that the vane pump 10A has the variable throttle valve 4A explained above with reference to FIG. 3.

Therefore, in this active stabilizer ST′, the effect of the above-described vane pump 10 is achieved, and also, as described above, the pressure of the returning working fluid QR on the return port 1A side can be prevented from rising excessively by the vane pump 10A, so that the pressure control valve PV used in the active stabilizer ST′ can be prevented from malfunctioning.

The vane pumps 10 and 10A explained above are merely examples of the invention described in the claims. The present invention's scope is not limited to these examples.

The fluid pressure may include pressure in cases in which, for example, water or a high molecular weight working fluid is used as the working fluid, and oil pressure when a hydraulic oil is used as the working fluid.

The vane pump in accordance with the present invention can be used suitably in industrial fields that require a high flow rate of a working fluid, such as an automotive active stabilizer.

Claims

1. A vane pump for pressurizing and delivering a working fluid by a vane section, comprising a suction port for drawing the working fluid to be sent from a tank to the vane section; and a delivery port for delivering the working fluid having been pressurized by the vane section, and additionally comprising a return port for receiving the working fluid that has been delivered from the delivery port, being used, and returned, wherein the returning working fluid flowing in through the return port is accelerated by being throttled, and the working fluid sent from the suction port is attracted by the accelerated returning working fluid so that the returning working fluid and the working fluid sent from the tank are sent into the vane section.

2. The vane pump according to claim 1, wherein a throttle valve for throttling the returning working fluid flowing in through the return port is a variable throttle valve in which the opening amount of throttle increases as the flow rate of the returning working fluid increases.