JPS58187592A - Vane pump operable to both rotary directions - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention provides two connection ports that can be used as suction or discharge connection ports depending on the direction of rotation of the pump rotor, and the narrowest connection between the pump chamber wall belonging to the pump stator and the pump rotor. The present invention relates to a vane pump which can be operated in both directions of rotation, having a gap in which one sickle-shaped end portion of the pump chamber remains on each side of said gap.

In known vane pumps of the type mentioned above, during suction operation, after the rotor vane has crossed the control edge of the pump's discharge connection port, a gaseous conveying medium is placed in the sickle-shaped end section of the pump chamber between said control edge and the narrowest gap. remains,
It has the disadvantage that it is compressed and pumped through the narrowest gap to the suction side of the pump. This residual medium reduces the suction efficiency of the pump.

On the other hand, the advantage of the vane pump according to the invention with the features recited in claim 1 is that by arranging the passage with the opening on the pump side as close to the narrowest possible gap as possible, The residual medium passing through the narrow gap and reaching the suction side is minimized, increasing the efficiency of the vane pump.

By the way, advantageous embodiments of the vane pump described in claim 1 can be obtained by means described in claim 2 and subsequent claims.

Embodiments of the invention will now be described in detail with reference to the drawings.

The vane pump shown in the sectional view of FIG. 1 has a pump stator l○. The pump stator 10 is composed of a stator ring 12 and two stator end plates 14 and 16 fixed to both end faces of the stator ring 120. The pump stator 10 therefore has a cylindrical pump chamber 18 in which the pump rotor 20 is arranged. The pump rotor 20 has two stator end plates 14, 16
It is a cylindrical component seated on a pump shaft 22 which is supported on the pump shaft 22. The pump shaft 22 is eccentrically arranged with respect to the pump chamber 18 so that the outer peripheral surface of the rotor is located close to the inner peripheral surface of the stator ring 12. As a result, the narrowest linear gap 24 is formed between the pump rotor 20 and the chamber wall formed by the inner peripheral surface of the stator ring 12. Furthermore, in this embodiment, pump row,
0 is provided with sliding slits 26 of Φ radial directions.

One rotor vane 28 is slidably arranged in each of these sliding slits 26 .

The rotor vanes 28, like the pump rotor 2o, extend from one stator end plate 14 to the other stator end plate 16 (FIG. 2). Furthermore, two slit-shaped openings are formed in the stator end plate 14, forming connection ports 30 and 32 of the vane pump. When the pump rotor 2o rotates in the direction of the arrow 34, medium is sucked in through the opening of the suction connection port 32 and is discharged through the connection port 3o, which opens to the outside of the pump. However, when the pump rotor 2o is rotated in the direction opposite to the arrow 34, the connection port 30 acts as a suction connection port and the connection port 32 acts as a discharge connection port. As can be seen in particular from FIG. 3, both connection ports 30 and 32 have kidney-shaped grooves forming passages 36, 38 extending from connection ports 3o and 32, respectively, towards the narrowest gap 24. is provided. Both of these passages 3
6 and 38 are one of the stator end plates 14 and 16 on both sides.
The pump chamber end portions 40.42 of the sickle-shaped pump chamber end are located on both sides of the narrowest gap 24 and extend between this gap 24 and the connecting port 30.32. ing. Both channels 36, 38 therefore open to the outside of the vane pump via the connecting ports 30 and 32.

Now, assume that the vane pump is being operated and the pump rotor is being rotated in the direction of arrow 34 in FIG. In this case, the residual medium remaining in the sickle-shaped pump chamber end section 40 after the rotor vane 28 has passed the control edge 31 of the connecting port 30 is connected to the channel 36 during the continued rotation of the pump rotor 20. ,t? -) 30 and can be discharged to the outside. Therefore, the passage 36 is connected to the connecting port 3
It forms part of 0. The closer the passage 36 is towards the narrowest gap 24, the more the sickle-shaped pump chamber end portion 4o
Less residual medium is pumped through the narrowest gap 24 remaining in the vane pump into the suction side of the vane pump, ie into the connection port 32.

When the R-Nbonzo is operated in the direction of rotation opposite to arrow 34, passage 38 improves the efficiency of the pump. This is because the residual medium in the pump chamber end section 42 is reduced via this channel 38. In this case, the passage 38
forms part of the connection port 32. In arranging the passages 36 and 38, there is a space between the passage 36 and the connecting port 32 (including the passage 38) on the opposite side from the narrowest gap 24, with the axis of rotation (axis 22 of the pump rotor 20) as the center.
At least two adjacent rotor vanes 2 of the pump rotor
An angle β of the same magnitude as the angle formed between 8 is formed.

As shown in FIG. 4, it is also possible to provide only one exhaust hole as a passage 136 in the stator end plate 114 instead of the passages 36, 38. In this case too, the pump-side opening of the exhaust hole functioning as the passage 136 is located in the area of the sickle-shaped end portion 4o of the pump chamber of the vane pump and opens to the outside of the pump. Furthermore, in the embodiment shown in FIG. 4, both connection ports 130 and 132 are designed as holes.

In this case, the center of the hole lies in the area of the sickle-shaped pump chamber wall formed by the stator ring.

The connection port configured in this manner is easy to manufacture.Furthermore, as can be seen from FIG.
The passage near 132 can be omitted. Connection, 1-) When 132 is used as a discharge connection port, i.e. when non-zero rotor 20 rotates in the direction opposite to arrow 34 in FIG. whereas it will be reduced via the closer connection port 132. However, in this case as well, the angle β about the axis of rotation of the pump rotor from the unomitted passage 136 to the control edge of the connecting port 132 is at least as large as the angle between two adjacent rotor vanes 28 .

The vane pump of the present invention provides low monitoring operation when both the pump stator and the pump rotor are made from synthetic carzene.

[Brief explanation of drawings]

FIG. 1 is a cross-sectional view of the vane pump of the present invention taken along line II in FIG. 2, and FIG. 2 is a longitudinal cross-sectional view of the vane pump shown in FIG. 1 taken along line ■-■ in FIG. Front view, Figure 3 is the 1st
A cross-sectional view taken along the line ■-■ in Figure 2 of the vane pump shown in the figure, Figure 2 shows that one stator end plate belonging to the pump stator has a structure different from the stator end plate in Figure 1. FIG. 4 is a cross-sectional view corresponding to FIG. 3 of a vane pump having the same structure. 10... Pump stator, 12... Stator ring, 14... Stator end plate, 16... Stator end plate,
18... Pump chamber, 20... Pump rotor, 22...
... Pump shaft, 24 ... Gap, 26 ... Sliding slit, 28 ... Rotor vane, 30 ... Connection hose), 31 ... Control edge, 32 ... Connection port, 34
...arrow, 36...passage, 38...passage, 40.
・Pump chamber end portion, 42... Pump chamber end portion, 1
14... Stator end plate, 130... Connection port, 13
2... Connection port, 136... Passage.

Claims (1)

[Claims] 1. Two connection boats that can be used as suction or discharge connection ports depending on the direction of rotation of the pump rotor, and the narrowest gap between the pump rotor and the pump chamber wall belonging to the pump rotor. In a vane pump operable in both directions of rotation, in which one sickle-shaped pump chamber end portion is left on each side of the gap, at least one pump chamber end portion (4C) or 42), in which a passageway (36, 38 or 136) is arranged in the region of 42), which passageway (36, 38 or 136) depressurizes the end portion of the pump chamber; Vane pump that can be operated. 2 It has a pump chamber formed by a stator ring and stator end plates arranged on both end faces of this stator ring, and the passage (136) is a sickle-shaped end portion of the pump chamber (4o aQ is 42). 2. A vane pump as claimed in claim 1, wherein the vane pump is formed with at least one hole leading from the pump to the outside of the pump. 3. It has a pump chamber formed by a stator ring and a stator end plate (a) on the end face of both H of this stator ring, and the passage (36, 38) is provided at least in the stator end plate. It is formed by one groove, which connects the pump connection port (30 or 3
2) The vane pump according to claim 1, which is connected to the vane pump according to claim 1. Between the passageway (36, 38 or 136) and the connecting boat (32) opposite the narrowest gap, the pump rotor (
angular deviation (β) that is at least as large as the angle formed between two adjacent rotor vanes (28) of 20);
The vane pump according to claim 2 or 3, wherein the vane pump is formed with: 5. At least one of the stator end plates (14, 16) (14) in which the passage (136) belongs to the pump rotor (10).
5. Vane pump according to claim 1, wherein the vane pump is formed as at least one hole. 6. Vane pump according to claim 5, wherein the connecting ports (130, 132) are formed as holes with their centers in the area of the pump chamber wall. 7. The stator end plate (14) does not have a passage (136) L near the connection port (130), and another connection port (132) is provided in the narrowest gap (24) with said connection port) ( 130), the vane pump according to claim 5 or 6, wherein the vane pump is provided closer than the vane pump. 8. Pump according to claim 1, wherein both stator i-plates (14, l 6 ) belonging to the pump stator (10) are made of synthetic carzene. 9. According to one of claims 11 to 8, the stator ring (12) arranged between the two stator end plates (14, 16) is made of synthetic carzene. vane pump. 10. Vane pump according to any one of claims 1 to 9, wherein the pump rotor (20, 28) consists of synthetic carzene.