This application is based on and claims priority under 35 U.S.C. sctn. 119 with respect to Japanese Application No. 2003-105286 filed on Apr. 9, 2003, the entire content of which is incorporated herein by reference.
1. Field of the Invention
The present invention relates to a vane pump suitable for use as hydraulic pressure supply to a power steering device and in particularly, to an improvement in a vane guide arrangement for smoothening radial movements of vanes around at each of ejection ports.
2. Discussion of the Related Art
Heretofore, as a vane pump used as hydraulic oil supply to a power steering device, there has been known one described in U.S. Pat. No. 6,203,303 B1 to H. Fujiwara et al. In this known vane pump, a rotor with plural slits formed to extend radially therein is rotatably provided in a cam ring contained in a pump housing, and a plurality of vanes are slidably received respectively in the slits. A pair of side wall members are provided to close the axial opposite end portions of the cam ring. Plural arc backpressure grooves communicating with innermost end portions of the slits and plural arc communication grooves connecting the backpressure grooves one after another are engraved at an inside end surface of each side wall member on which the rotor rotationally slides, and are supplied with the pump ejection pressure. Further, a recess (or cutout) portion which does not contact the side surface of each vane is formed on at least one of rotor sliding surfaces of the side wall members.
In the vane pump of the aforementioned prior art technology, the contact length of the side surface of each vane with the inside end surface of the side plate 1 is shortened by providing the recess portion 6. As a result, sliding resistance is decreased between the inside end surface of the side plate 1 and the side surface of each vane as well as between each vane and the rotor slit receiving the same. Further, an increased pressure in each ejection backpressure groove 4 which is attributed to the radially inward movement of each van is applied by way of the recess portion 6 to the radial innermost end of the vane in an angular area where the same is to be protruded to the outermost position, so that the vane can be enabled to protrude quickly from the rotor at the start of the pump operation.
In vane pumps of this type, the radial movement of each vane supported in the rotor is done with the side surface thereof being slidably guided on the inside end surface of the side plate 1 in the same manner as shown in
As discussed above, in the prior art technology, the inside end surface of the side plate (side wall member) 1 which slidably guides the side surface of each vane in the angular area over which each ejection port elongates is the guide area (e) whose radial width is almost constant and narrow. This tends to cause each vane passing there to incline relative to the side plate 1, and thus, the side plate 1 is insufficient to guide each vane. On the other hand, the force which causes each vane rotating with the rotor to move radially inwardly within the same angular area is generated by sliding the radial outer end of each vane on the slanted cam surface at the internal surface of the cam ring against the friction force therebetween. Therefore, the force tends to involve self-induced vibration and varies irregularly in terms of time and place. In this way, as the irregularly variable force is exerted on each vane guided by the guide surface which is insufficient in the function therefor, each vane is inclined relative to the guide area (e) to scrape against the same and cannot move stably and smoothly. For this reason, there arises a problem that the cam surface at the internal surface of the cam ring is abraded notably within the aforementioned angular area, thereby generating pulsation in the pump ejection pressure as well as increasing the operation noise.
A similar problem arises in the case where the backpressure groove 2 is of the type that the recess portions 6 are omitted to constitute the backpressure groove 2 only by the suction and ejection backpressure grooves 3, 4 and the communication grooves 5. In this modified case, within the angular area over which each ejection port 22 elongates, the inside end surface of the side plate 1 which slidably guides one side surface of each vane when the same is moved radially inwardly defines a guide area whose radial width is almost constant and narrow (though somewhat wider than that on the aforementioned guide area (e)) between the outer circumferential arc edge of each ejection backpressure groove 4 and the inner circumferential arc edge of each ejection port 22. Accordingly, the similar problem results in smaller damage than that in the aforementioned case, but remains left unsolved.
In addition, the similar problem arises in the case of a further modified side plate wherein the backpressure groove 2 is formed by extending the suction backpressure grooves 3 (or the ejection backpressure grooves 4) continuously over the whole circumferential length.
Accordingly, in view of the foregoing drawbacks, it is a primary object of the present invention to provide an improved vane pump capable of enlarging a guide area for guiding each vane around at an ejection port.
Briefly, in a vane pump according to the present invention, a vane pump section is composed of a cam ring contained in a pump housing, a rotor rotatably provided in the cam ring with a plurality of slits formed in radial direction, and a plurality of vanes guided to be radially slidable respectively in the slits and brought at radial outermost ends into sliding engagement with a cam surface formed at the internal surface of the cam ring for partitioning a space between the outer circumferential surface of the rotor and the cam surface into plural pump chambers each of which is varied in volume as the rotor rotates. The vane pump further comprises at least one side wall member closing a side surface of the vane pump section and enabling the rotor and the vanes to be slidable thereon. An annular backpressure groove is formed on an inside end surface of the side wall member and encircles the rotational axis of the rotor to communicate with innermost end portions of the slits. The annular backpressure groove is supplied with pressurized fluid ejected from the pump. Within an angular area where each of the vanes is moved radially inwardly while being rotated together with the rotor, the outer circumferential edge of the backpressure groove is indented toward the rotational axis of the rotor along a locus which the radial innermost end of each vane draws so that the radial innermost end of each vane does not protrude radially inwardly beyond a predetermined distance from the outer circumferential edge of the backpressure groove.
With this configuration, within the angular area where each of the vanes is moved radially inwardly while being rotated together with the rotor, the outer circumferential edge of the backpressure groove is indented toward the rotational axis of the rotor along the locus, so that the radial innermost end of each vane is prevented from protruding radially inwardly beyond the predetermined distance from the outer circumferential edge of the backpressure groove. Thus, the radial width of a guide area on the inside end surface of the side wall member which slidably guides one side surface of each vane when the same is moved radially inwardly is enlarged by the amount indented toward the rotational axis of the rotor. Therefore, since the vane guide function of the inside end surface of the side wall member is ensured, the radially inward movement of each vane within the aforementioned angular area can be stabilized and smoothened compared to that in the prior art. Consequently, the cam surface at the internal surface of the cam ring can be prevented from suffering notable abrasion. Further, pulsation is hardly generated in the pump ejection pressure, nor does noise increase in the pump operation.
The foregoing and other objects and many of the attendant advantages of the present invention may readily be appreciated as the same becomes better understood by reference to the preferred embodiment of the present invention when considered in connection with the accompanying drawings, wherein like reference numerals designate the same or corresponding parts throughout several views, and in which:
A vane pump in one embodiment according to the present invention will be described hereinafter with reference to
As best shown in
As best shown in
The backpressure groove 25 is arranged to communicate with radial innermost end portions of the slits 32a. As shown in
Next, the shapes of the ejection backpressure grooves 27 and the recess portions 29 will be described in grater detail with reference to
Further, in order to shorten the length over which each vane 33 contacts the inside end surface of the side plate 20, each of the cutout or recess portions 29 is formed to extend radially outwardly from each ejection backpressure groove 27 and each communication groove 28 behind rotationally within an angular area which begins from a position slightly ahead of the rotationally preceding end of each suction backpressure groove 26 and which ends at the rotationally preceding end portion of each ejection backpressure groove 27. At almost all the part except for a part preceding in the rotational direction of the rotor 32, the outer circumferential edge of each recess portion 29 makes an arc which has a radius slightly larger than the long radius of the locus (L) with respect to a center on the rotational axis of the pump shaft 35. At the part preceding in the rotational direction of the rotor 32, however, the outer circumferential edge of each recess portion 29 extends in parallel to the locus (L) which the radial innermost end of each vane 32 draws and slightly outside of the locus (L) thereby to be indented toward the rotational axis of the pump shaft 35. Thus, the radial innermost end of each vane 33, when the same is moved radially inwardly, is prevented from protruding radially inwardly beyond the predetermined distance from the outer circumferential edge of each recess portion 29 and is smoothly connected to the outer circumferential edge of each ejection backpressure groove 27 within the almost two-third angular area ahead in the rotational direction of the rotor 32.
The radius of the outer circumferential edge of each recess portion 29 is so chosen that a reliable sealing capability is secured on a part of the flat inside end surface of the side plate 20 which part is left between the recess portion 29 and the whisker groove 22b of the ejection port 22 for sliding contact with the side surface of the rotor 32. Further, the foregoing predetermined distance corresponds to the amount through which each vane 33 is indented radially inwardly from the outer circumferential edge of each recess portion 29 at the part behind in the rotational direction of the rotor 32 and from the outer circumferential edge of each ejection backpressure groove 27 at the part ahead in the rotational direction of the rotor 32. The predetermined distance is chosen so that a value which is necessary and sufficient to perform the function of guiding and supporting the vanes 3 is secured as the radial width of an guide area (d) which is formed on the inside surface of the side plate 20 between the rotationally preceding and radially indented part, which is common to the outer circumferential edges of each ejection backpressure groove 27 and each recess portion 29, and the inner circumferential edge of each ejection port 22 for guiding the side surface of each vane 33.
The rear housing 12 closes the side surface of the vane pump section 30 at the opposite side of the side plate 20. Primarily for pressure balance, a pair of suction ports, a pair of ejection ports and a backpressure groove which is composed of suction and ejection backpressure grooves, communication grooves and recess portions are formed on an inside end surface of the rear housing 12 in the same manner as, and symmetrically of, those formed on the inside end surface of the side plate 20. A guide area corresponding to that indicated at (d) on the side plate 20 is formed on the inside end surface of the rear housing 12 between each ejection backpressure groove and each ejection port. The suction ports formed on the rear housing 12 communicate With the suction passage 13, while the ejection ports and the backpressure groove formed on the rear housing 12 do not communicate with the exterior of the housing 11.
(Operation)
The operation of the embodiment as constructed above will be described hereinafter. Since the side plate 20 and the rear housing 12 have substantially the same functions in guiding the end surfaces of the rotor 32 and the vanes 33, the following description concerning the operation of the embodiment will be referred mainly to the side plate 20 unless particularly referred to on the contrary.
When the rotor 32 is rotated bodily with the pump shaft 35, the vane 33 guided in each slit 32a is reciprocated radially as the radial outmost end thereof is slidden along the cam surface 31a of the cam ring 31. Within the expansion angular area where each vane 33 is moved radially outwardly, the operating oil flown from the suction hole 13a is sucked from the suction ports 21 into each pump chamber (P) whose volume is increasing. Within the compression angular area where each vane 33 is moved radially inwardly, the operating oil within each pump chamber (P) whose volume is decreasing is ejected from each of the ejection ports 22 through the ejection passage (not shown) to a suitable fluid-operated actuator, such as for example an automotive power steering device. The force by which each vane 33 rotating with the rotor 32 is urged to move radially inwardly is generated as a result that the radial outermost end of each vane 33 protruding from the rotor 32 is slidden on each slanted part of the cam surface 31a at the internal surface of the cam ring 31 against the friction force and therefore irregularly fluctuates in terms of time and place because it is likely to be accompanied by self-induced vibration. However, in this particular embodiment, each of the guide areas (d) at diametrically opposite sides is formed on the inside end surface of each of the side plate 20 and the rear housing 12 between each ejection port 22 and each ejection backpressure groove 27 and the associated recess portion 29 thereby to guide and support the side surface of each vane 33. And, each guide area (d) is chosen to have the radial width which is necessary and sufficient to perform the function of guiding and supporting each vane 33. This can be done by directing or deflecting the rotationally preceding part common to the outer circumferential edges of each ejection backpressure groove 27 and the associated recess portion 29 toward the rotational axis of the rotor 32 to be indented along or in parallel to the locus (L) which each vane 33 draws at its radial innermost end. Thus, each vane 33 does not tend to incline on the guide areas (d). Accordingly, even if the force that urges each vane 33 to move radially inwardly is that which irregularly fluctuates in terms of time and place, it does not occur that each vane 33 is inclined on each guide area (d) to scrape against the same. This ensures that each vane 33 moves smoothly and stably, so that the cam ring 31 does not suffer notable abrasion at the cam surface 31a. Further, pulsation is hardly generated in the pump ejected pressure, nor does noise increase in the pump operation.
In the foregoing embodiment, the present invention is applied to the vane pump of the type that the backpressure groove 25 is provided with the recess portions 29 for enabling the vanes 33 to protrude quickly form the circumferential surface of the rotor 32 at the operation start of the pump. In this case, the advantage is particularly notable because the radial width of the guide area (d) which is formed between each ejection port 22 and the ejection backpressure groove 27 and the associated recess portion 29 is largely increased compared with that in the prior art vane pump wherein as shown in
However, the application of the present invention is not limited to the vane pump with such recess portions 29. Rather, the present invention may be applied to a modified vane pump that is constituted by omitting the recess portions 6 from the prior art vane pump whose side plate 1 is shown in FIG. 4. In this modified vane pump, by deflecting the rotationally preceding part of the outer circumferential edge of each ejection backpressure groove 27 to be indented toward the rotor rotational axis in parallel to the locus (L) drawn by the radial innermost end of each vane 33 in the same manner as the foregoing embodiment, the radial width which is formed between the ejection port 22 and the ejection backpressure groove 27 can be enlarged compared to that (e) of the prior art pump wherein as shown in
In addition, the present invention may be applied to a further modified vane pump wherein the backpressure groove 25 is constituted to have the same cross-section as the suction backpressure grooves 26 (or the ejection backpressure grooves 27) over the entire circumferential length thereof. In this further modified vane pump, a part of the backpressure groove 25 within an angular area corresponding to each ejection port 22 is deflected to be indented toward the rotor rotational axis along or in parallel to the aforementioned locus (L). Thus, the further modified vane pump can have an enlarged radial width at the guide area which is formed between each ejection port 22 and the radially inwardly indented part of the backpressure groove, and the movement of each vane 33 becomes stable to attain substantially the same effect as is attained in the foregoing embodiment.
Although in the illustrated embodiment, the outer circumferential edges of each ejection backpressure groove 27 and the associated recess portion 29 define a single, common rotationally preceding part thereof which is deflected to be indented toward the rotor rotational axis along or in parallel to the aforementioned locus (L), they may define individual rotationally preceding parts thereof each of which is deflected to be indented toward the rotor rotational axis along or in parallel to the aforementioned locus (L),
Moreover, the rotationally preceding part along the aforementioned locus (L) of each ejection backpressure groove 27 in the illustrated embodiment or of the backpressure groove 25 in the further modified embodiment may extend in parallel to the aforementioned locus (L) slightly radial outside of the same as shown in
Furthermore, the part indented along the aforementioned locus (L) of each ejection backpressure groove 27, of the backpressure groove 25 or of each recess portion 29 may be formed on the inside end surface of any one of the side plate 20 and the rear housing 12, but not on the inside end surface of the other.
Finally, various features and many of the attendant advantages in the foregoing embodiment will be summarized as follows:
In one aspect of the forgoing embodiment, as typically shown in
In another aspect of the forgoing embodiment, the backpressure groove 25 is composed of the suction backpressure groove 26 within each expansion angular area, the ejection backpressure groove 27 within each compression angular area and the communication grooves 28 connecting the suction and ejection backpressure grooves 26, 27 for a complete circle as the backpressure groove 25. In this modified vane pump, the outer circumferential edge of the ejection backpressure groove 27 is deflected at a rotationally preceding part thereof to be indented toward the rotational axis of the rotor 32 along the locus (L) so that the radial innermost end of each vane 33 being moved radially inwardly is prevented from protruding radially inwardly beyond the predetermined distance from the outer circumferential edge of the ejection backpressure groove 27. Thus, the radial width of each guide area (d) on the inside end surface of the side wall member 20 (or 12) which slidably guides one side surface of each vane 33 when the same is moved radially is enlarged by the area which is indented toward the rotational axis of the rotor 32. Therefore, since the vane guide function of the inside end surface of the side wall member 20 (or 12) is ensured, the radially inward movement of each vane 33 within the aforementioned angular area can be stabilized and smoothened compared to that in the prior art. Consequently, the cam surface 31a at the internal surface of the cam ring 31 does not suffer notable abrasion, and pulsation is hardly generated in the pump ejection pressure, nor does noise increase in the pump operation.
In a further aspect of the forgoing embodiment, within at least a part of another angular area where each vane 33 is moved radially inwardly from the radial outermost position, the recess portion 29 for preventing the radial innermost part of the side end surface of each vane 33 from contacting the inside end surface of the side wall member 20 (or 12) is further provided on the inside end surface of the side wall member 20 (or 12) which slidably contact the rotor 32 and each vane 33. As a result, the length that the side surface of each vane 33 contacts the inside end surface of the side wall member 20 (or 12) is further shortened, and this reduces the sliding resistance against each vane 33, so that the same can be enabled to protrude quickly from the rotor 32 at the operation start of the vane pump. In addition, the outer circumferential edge of the recess portion 29 is deflected at its rotationally preceding part to be indented toward the rotational axis of the rotor 32 along the locus (L) so that the radial innermost end of each vane 33 does not protrude radially inwardly beyond the predetermined distance from the outer circumferential edge of the recess portion 29. Thus, the radial width of the guide area (d) on the inside end surface of the side wall member 20 (or 12) which slidably guides one side surface of each vane 33 when the same is moved radially is enlarged by the portion indented toward the rotational axis of the rotor 32. Therefore, although the contact length of the vane side surface with the inside end surface of the side wall member 20 (or 12) is shortened by the provision of the recess portion 29, the radially inward movement of each vane 33 within the aforementioned angular area can be stabilized and smoothened compared to that in the prior art since the vane guide function of the inside end surface of the side wall member 20 (or 12) is ensured. Consequently, the cam surface 31a at the internal surface of the cam ring 31 does not suffer notable abrasion, and pulsation is hardly generated in the pump ejection pressure, nor does noise increase in the pump operation.
Obviously, numerous modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the present invention may be practiced otherwise than as specifically described herein.
Number | Date | Country | Kind |
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2003-105286 | Apr 2003 | JP | national |
Number | Name | Date | Kind |
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4386891 | Riefel et al. | Jun 1983 | A |
6068461 | Haga et al. | May 2000 | A |
6203303 | Fujiwara et al. | Mar 2001 | B1 |
6244830 | Agner | Jun 2001 | B1 |
Number | Date | Country |
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1008753 | Jun 2000 | EP |
Number | Date | Country | |
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20040202565 A1 | Oct 2004 | US |