JPH0714186U - Vane pump - Google Patents

Abstract

(57) [Summary] [Purpose] To eliminate the effect of pump pulsation on the spool valve. Stabilize the flow control. [Structure] The pressure chamber 2 and the discharge passage 3 are connected by parallel passages 4 and 5. The valve hole 6 is intersected with the passage 4 and the valve hole 6
A spool valve 7 for adjusting the opening area of the passage 4 is housed in the. The pressure at the bottom of the vane housing groove 10 of the rotor 9 is introduced into one liquid chamber 8 of the valve hole 6, and the pressure of the discharge passage 3 is introduced into the other liquid chamber 11. Since the pressure at the bottom of the vane housing groove 10 increases in proportion to the pump rotation speed, the total opening area of the passages 4 and 5 decreases as the pump rotation speed increases. Valve hole 6
Communication passage 34 for connecting the other liquid chamber 11 and the discharge passage 3 with each other
An orifice 35 is provided in the. Discharge path 3 due to pump pulsation
The pressure fluctuation of (1) is buffered by the orifice 35 and is not transmitted to the other liquid chamber 11.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a vane pump used as a power source for a power steering device of an automobile.

[0002]

[Prior art]

 For vane pumps used in power steering systems of automobiles, it is desired that the discharge flow rate of hydraulic fluid be reduced as the engine speed is increased in order to improve steering stability during high-speed traveling.

In order to meet this demand, a vane pump such as that disclosed in Japanese Patent Laid-Open No. 4-43 881 has been conventionally devised.

As shown in FIGS. 4 and 5, this vane pump is provided with a pressure chamber 2 into the outer region of the pump body 1 into which the hydraulic fluid discharged from the pump body 1 is introduced. The discharge passage 3 for taking out the liquid to the outside of the pump is communicated by a pair of parallel passages 4 and 5, and one of these passages 4 is crossed with a valve hole 6, and at the same time, the valve hole 6 is moved to the forward / backward position. A spool valve 7 for changing the opening area of the passage 4 is accommodated. Then, the pressure at the bottom of the vane housing groove 10 of the rotor 9 is introduced into one of the liquid chambers 8 of the valve hole 6, while the pressure of the discharge passage 3 is introduced into the other liquid chamber 11, and the passage 4 The opening area is controlled by the pressure difference between the pressure at the bottom of the vane housing groove 10 and the pressure at the discharge passage 3. Here, as shown in FIG. 5, a plurality of pressure introducing grooves 13a, 13b ... That face the bottom of the vane housing groove 10 are formed in the side plate 12 that is in sliding contact with the side surface of the rotor 9, and each adjacent pressure introducing groove is formed. The grooves communicate with each other by the throttle groove 14, and the pressure introducing groove 13a in the suction region is electrically connected to the pressure chamber 2 by a passage (not shown). For this reason, the bottom of each vane housing groove 10 sucks the working liquid from the pressure introducing groove (hereinafter referred to as the suction side pressure introducing groove 13a) in the suction region where the vane 15 projects radially outward, A pump action such as discharging the hydraulic fluid is performed in a pressure introducing groove (hereinafter, referred to as the discharge side pressure introducing groove 13b) in a discharge area into which the vane 15 is pushed, and the discharge side pressure introducing groove 13b of the discharge side increases as the pump rotation speed increases. It is designed to increase pressure. Specifically, one of the liquid chambers 8 of the valve hole 6 communicates with the discharge-side pressure introducing groove 13b through the orifice passage 16, and the bottom of the vane housing groove 10 facing the discharge-side pressure introducing groove 13b. The pressure is introduced so that when the pump rotational speed increases, the spool valve 7 correspondingly reduces the opening area of the passage and reduces the discharge flow rate from the discharge passage 3. The pressure chamber 2 is provided with a flow control valve (not shown) for draining the excess hydraulic fluid when the pressure difference between the pressure chamber 2 and the discharge passage 3 exceeds a set value.

[0005]

[Problems to be solved by the device]

 However, in the above-mentioned conventional vane pump, since the pressure of the discharge passage 3 is directly introduced into the other liquid chamber 11 of the valve hole 6, when pump pulsation occurs, the pressure of the pulsation is discharged from the discharge passage 3. It acts on the spool valve 7 and causes a problem that the flow rate control by the spool valve 7 becomes unstable.

Therefore, the present invention is intended to provide a vane pump capable of realizing stable flow rate control by preventing pump pulsation from affecting the operation of the spool valve.

[0007]

[Means for Solving the Problems]

 As a means for solving the above-mentioned problems, the present invention has a plurality of pressure chambers into which a discharge working fluid of a pump body is introduced and a discharge passage for taking out the working fluid of the pressure chamber to the outside of the pump. And a spool valve for adjusting the opening area of the intersecting passage, which is defined by the spool valve. The pressure at the bottom of the vane housing groove of the rotor is introduced into one of the liquid chambers of the valve hole, while the pressure of the discharge passage is introduced into the other liquid chamber, and the opening area of the passage is adjusted to the pressure at the bottom of the vane housing groove. In the vane pump that is controlled by the pressure difference between the discharge passage and the pressure in the discharge passage, an orifice is provided in the communication passage that connects the other liquid chamber and the discharge passage.

[0008]

[Action]

 Since the orifice is provided in the communication passage, the pressure fluctuation in the discharge passage is buffered by this orifice and is not transmitted to the other liquid chamber.

[0009]

【Example】

 Next, an embodiment of the present invention will be described with reference to FIGS. The same parts as those of the conventional one shown in FIGS. 4 and 5 are designated by the same reference numerals.

In the drawing, reference numeral 18 denotes a pump casing, and a drive shaft 20 is pivotally supported in a shaft hole 19 formed in the pump casing 18 via a bearing 21. Reference numeral 22 is a cover connected to the pump casing 18, and the pump body 1 is housed in a space surrounded by the cover 22 and the pump casing 18. The pump body 1 is spline-coupled to the drive shaft 20, and has a rotor 9 having a plurality of vane housing grooves 10 in a substantially radial direction, and vanes 15 housed in and out of each vane housing groove 10 of the rotor 9 in a retracted manner. And a cam ring 23 having an approximately elliptical cam surface on the inner circumference and arranged on the outer peripheral area of the rotor 9, and side plates 12 and 24 for closing the side portions of the cam ring 23. When the rotor 9 rotates, Each vane 15 slides into and out of contact with the cam surface of the cam ring 23, thereby performing a pumping action by continuously increasing and decreasing the volume between the adjacent vanes 15, 15. An intake port (not shown) and a discharge port 25 are provided on the side plate 12 at positions corresponding to the suction region and the discharge region in the cam ring 23, respectively, and the discharge port 25 is a pump. It communicates with the pressure chamber 2 in the outer peripheral region of the main body 1. As shown in FIG. 3, suction side pressure introducing grooves 13a and discharge side pressure introducing grooves 13b are alternately arranged at positions facing the bottom of the vane housing groove 10 of the side plates 12 and 24, and are adjacent to each other. The pressure introducing grooves 13a, 13b are electrically connected to each other by the throttle groove 14, and the suction side pressure introducing groove 13a is electrically connected to the pressure chamber 2 through a passage (not shown). Therefore, the pressure of the pressure chamber 2 acts on the base of the vane 15 in the suction region of the cam ring 23, and the pressure of the base of the vane 15 in the discharge region further increased by the pumping action of the base. Works. In addition, 17 is an intake passage formed in the pump casing 18 for introducing the working fluid into the pump body 1, and 3 is a pump casing 18 for taking out the working fluid discharged from the pump body 1 to the outside of the pump. It is a discharge path formed in.

Reference numeral 26 is a valve hole formed in the pump casing 18 so that one end thereof is directly opened to the pressure chamber 2, and the valve hole 26 has a flow control spool 27 and a pressure control spool 27. A spring 28 that biases the chamber 2 is housed. The flow rate control spool 27 recirculates the excess hydraulic fluid in the pressure chamber 2 to the suction passage 17 according to the pressure difference between the pressure chamber 2 and the discharge passage 3, and the discharge passage 3 is provided on the bottom side of the valve hole 26. An inlet hole 29 for introducing the pressure is formed, and a drain hole 30 that is opened and closed by the advancing and retracting operation of the flow rate control spool 27 is formed in the valve hole 26 near the pressure chamber 2.

Numerals 4 and 5 are a pair of passages that connect the pressure chamber 2 and the discharge passage 3. The passages 4 and 5 are arranged in parallel with each other in the pump casing 18, and the orifices 31, 32 are provided. A valve hole 6 is provided at a position downstream of the orifice 31 in one of the passages 4, and the spool hole 7 for changing the opening area of the passage 4 in accordance with the forward / backward position is provided in the valve hole 6 and the spool valve 7. A spring 33 for urging the valve 7 is housed. Then, one liquid chamber 8 of the valve hole 6 defined by the spool valve 7 is connected to the discharge side pressure introduction groove 13b of the side plate 12 by the orifice passage 16, and the other liquid chamber 11 is discharged by the communication passage 34. Conducted to 3. Therefore, the spool valve 7 controls the opening area of the passage 4 according to the pressure difference between the pressure in the vane housing groove 10 facing the discharge-side pressure introduction groove 13b and the pressure in the discharge passage 3. The communication passage 34 connecting the other liquid chamber 11 and the discharge passage 3 is provided with an orifice 35, which is an essential part of the present invention. It does not act on the chamber 11.

With the above-described configuration, the spool valve 7 fully opens the passage 4 to maximize the total opening area of the passages 4 and 5 while the pump rotation speed is low. From this state, until the pump speed reaches the set value, the flow rate control spool 27 does not open the drain hole 30, so that the discharge flow rate from the discharge passage 3 increases in proportion to the pump speed. When the value exceeds the set value, the flow rate control spool 27 opens the drain hole 30 in response to the pressure difference between the pressure chamber 2 and the discharge passage 3, whereby the discharge flow rate from the discharge passage 3 is maintained substantially constant. .

Further, the pump rotation speed further increases, and the pressure at the bottom of the vane housing groove 10 increases due to the pumping action of the base of the vane 15, and the differential pressure between the bottom of the vane housing groove 10 and the discharge passage 3 is set. When the pressure exceeds a certain value, the spool valve 7 reduces the opening area of the one passage 4 according to the pressure difference, and when the pressure exceeds a certain value, the passage 4 is completely closed. Therefore, the discharge flow rate from the discharge passage 3 decreases in inverse proportion to the increase in the pump rotation speed, and then is maintained constant again.

Here, in this vane pump, since the orifice 35 is provided in the communication passage 34 that connects the other liquid chamber 11 of the valve hole 6 and the discharge passage 3, the pump pulsation occurs in the discharge passage 3. Also, the pressure fluctuation due to the pulsation is buffered by the orifice 35 and is not transmitted to the other liquid chamber 11. Therefore, the spool valve 7 does not fluctuate irregularly due to the influence of pump pulsation, and the discharge flow rate from the discharge passage 3 is always controlled to a desired value.

The embodiment of the present invention is not limited to the one described above, and, for example, the number of passages that connect the pressure chamber 2 and the discharge passage 3 may be three or more.

[0017]

[Effect of device]

 As described above, according to the present invention, an orifice is provided in the communication passage that connects the other liquid chamber and the discharge passage, and this orifice prevents temporary pressure fluctuation on the discharge passage side from being transmitted to the other liquid chamber. Even if the pump pulsation occurs, the pulsation does not affect the operation of the spool valve, and it is possible to always realize stable flow rate control.

[Brief description of drawings]

FIG. 1 is a sectional view taken along the line AA of FIG. 3 showing an embodiment of the present invention.

FIG. 2 is a sectional view showing the same embodiment.

FIG. 3 is a view on arrow B of FIG. 2 showing the same embodiment.

FIG. 4 is a sectional view showing a conventional technique.

FIG. 5 is a view on arrow C of FIG. 4 showing the same technique.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Pump body, 2 ... Pressure chamber, 3 ... Discharge path, 4, 5 ... Passage, 6 ... Valve hole, 7 ... Spool valve, 8, 11 ... Liquid chamber, 9 ... Rotor 10 ... Vane accommodating groove 34 ... Communication passage , 35 ... Orifice.

Claims (1)

[Scope of utility model registration request] 1. A pressure chamber into which a discharge working fluid of a pump main body is introduced and a discharge passage for taking out the working fluid of the pressure chamber to the outside of the pump are communicated with each other through a plurality of parallel passages. Of at least one of the valve holes, and a spool valve for adjusting the opening area of the intersecting passage is housed in the valve hole, and the spool valve is formed in one of the liquid chambers of the valve hole defined by the spool valve. , The pressure at the bottom of the vane housing groove of the rotor is introduced, while the pressure at the discharge passage is introduced to the other liquid chamber, and the opening area of the passage is set to the differential pressure between the pressure at the bottom of the vane housing groove and the pressure at the discharge passage. A vane pump controlled by means of a vane pump, characterized in that an orifice is provided in a communication passage that connects the other liquid chamber and the discharge passage.