Vane pump with dynamic pressure bearing grooves on vane guide ring

Abstract

A vane pump in which a projection is provided on the end of a vane which radially slides as a rotor rotates, and an annular race concentric with an inner peripheral surface of a housing is provided in the inner surface of the end wall of the housing, the projection being brought into engagement with the annular race to control the slide of the vane.

Description

BACKGROUND OF THE INVENTION

The present invention relates to a vane pump which is one of rotary pumps used for various kinds of apparatuses such as a supercharger of an engine, a compressor of a freezing cycle, and the like.

A vane pump schematically shown in FIG. 12 has been heretofore widely known.

In FIG. 12, reference numeral 101 designates a housing; 102, a rotor inserted eccentrically into an inner peripheral space of the housing 101 and rotatably supported by a rotational shaft 103; 105a, 105b and 105c, plate-like vanes disposed radially retractably from vane grooves 104a, 104b and 104c equally spaced apart so as to peripherally divide the outer peripheral side of the rotor 102 into three sections. When the rotor 102 is rotated in the direction as indicated by the arrow X by the rotational shaft 103, the vanes 105a, 105b and 105c are moved out in the direction of the outside diameter by the centrifugal force, and the end edges thereof rotate while slidably contacting the inner peripheral surface of the housing 101. Since the rotor 102 is eccentric with respect to the housing 101 as previously mentioned, as such rotation occurs, volumes of working spaces 106a, 106b and 106c defined by the housing 101, the rotor 102 and the vanes 105a, 105b and 105c are repeatedly enlarged and contracted to allow a fluid taken in from an intake port 107 to be discharged out of an outlet port 108.

However, the above-described conventional vane pump has problems that since the vanes slidably move along the inner peripheral surface of the housing at high speeds, the efficiency of the volume caused by the great power loss due to the sliding resistance and by the generation of high sliding heat unavoidably deteriorates; the vanes materially become worn; and the vanes are expanded due to the generation of sliding heat to produce a galling with the inner side surfaces of both end walls of the housing, and the like.

In view of these problems as noted above, it is an object of the present invention to enhance the efficiency of such a pump and enhance the durability thereof.

SUMMARY OF THE INVENTION

To achieve the aforementioned objects, a vane pump according to one embodiment of the present invention includes projections such as pins on both ends of a vane, and an annular race in peripheral slidable engagement with the projections to define the protrusion of the vane from a vane groove formed coaxially with the inner peripheral surface of the housing.

According to the present invention, the protrusion of the vane from the vane groove is not defined by the contact thereof with the inner peripheral surface of the housing, but it is defined in a manner such that the end edge of the vane depicts a certain locus by the engagement of the projections such as pins provided on the vane with the annular race formed on the side of the housing. The vane may be rotated in the state in which the vane is not in contact with the inner surface of the housing, and therefore, the present invention has excellent advantages which can prevent the deterioration of the efficiency of the pump caused by the sliding resistance and the wear of the vane; and which can prevent occurrence of inconvenience resulting from an increase in sliding heat.

According to the present invention, the protrusion of the vanes from the vane grooves is not defined by the contact with the inner peripheral surface of the housing but it is defined so that the end edges of the vanes depict a given locus by engagement of the retainer plates fitted in the housing with the vanes through the cams. The vanes can be rotated in a state not in contact with the inner surface of the housing. Therefore, the present invention has excellent effects in that the lowering of the rotational efficiency and the wear of the vanes due to the sliding resistance can be prevented, and the occurrence of inconvenience such as the lowering of the volume efficiency due to the increase in heat generation caused by sliding can also be prevented.

While the present invention has been briefly outlined, the above and other objects and new features of the present invention will be fully understood from the reading of the ensuing detailed description in conjunction with embodiments shown in the accompanying drawings. It is to be noted that the drawings are exclusively used to show certain embodiments for the understanding of the present invention and are not intended to limit the scope of this invention.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an exploded perspective view of a vane pump according to a fundamental embodiment of the present invention;

FIG. 2 is a sectional view showing the pump of FIG. 1 assembled;

FIG. 3 is a side view of a rotor of the same pump of FIG. 1;

FIGS. 4, 5, 6 and 7 are perspective views of vanes, respectively;

FIG. 4 is a sectional view of a vane pump according to one embodiment;

FIG. 5 is a side view of a rotor of the same pump;

FIG. 6(I) and 6(II) are respective perspective views of retainer rings;

FIG. 7 is a sectional view of another embodiment of a vane pump;

FIG. 8 is a sectional view of a further embodiment of a vane pump;

FIGS. 9, 10 and 11 are respective perspective views of retainer rings; and

FIG. 12 is a sectional view showing one example of a vane pump according to the prior art;

DESCRIPTION OF THE PREFERRED EMBODIMENTS

A fundamental exemplification of a vane pump according to the present invention will now be described with reference to FIGS. 1 to 3.

In FIGS. 1 and 2, a front housing 1 and a rear housing 2, both of which housings are made of non-ferrous metal such as aluminum, which is light in weight and is small in the coefficient of thermal expansion, are secured integral with each other by means of bolts 3. A rotor 4 made of iron eccentrically inserted into an inner peripheral space 5 of the housing is extended through both the housings 1 and 2 through a ball bearing 7a held by a fixed ring 6 in anti-slipout fashion in an axial shoulder of the front housing 1 and a ball bearing 7b held by a bearing cover 8 in anti-slipout fashion in an axial shoulder of the rear housing 2 and is rotatably mounted on a rotational shaft 10 to which a drive force is transmitted from a pulley 9. Plate-like vanes 11a, 11b and 11c principally made of a carbon material having an excellent slidability are disposed to be radially projected and retracted in vane grooves 12a, 12b and 12c, respectively, which are formed in the form of depressions equally spaced apart so as to peripherally divide the outer peripheral side of the rotor 4 into three sections, on the rotor 4. On opposite ends of each of the vanes 11a, 11b and 11c corresponding to axial opposite sides of the rotor 4 are projected steel pins 13 and 13, respectively, and a sleeve bearing 14 made of resin having excellent slidability and abrasion resistance is slipped over each of pins 13. In annular recesses 15a and 15b formed in inner surfaces 1' and 2' of end walls where the front housing 1 and the rear housing 2 are opposed to each other coaxial with the inner peripheral space 5 of the housing (coaxial with the inner peripheral surface 1" of the front housing 1), retainer rings 16a and 16b made of non-ferrous metal such as aluminum and each having an annular race 17 are rotatably fitted through ball bearings 18a and 18b, respectively. The pins 13 and 13 projected on the respective vanes 11a, 11b and 11c peripherally slidably engage the annular races 17 and 17 of the retainer rings 16a and 16b through the respective sleeve bearings 14. This engagement defines the radial movement of the vanes 11a, 11b and 11c during rotation so as to maintain a state in which there is formed a slight clearance between the end edges 11a', 11b' and 11c' (see FIG. 3) thereof and the inner peripheral surface 1" of the front housing 1. An intake port 19 for guiding a fluid into the inner peripheral space 5 of the housing from the exterior of the pump and an outlet port 20 for guiding a fluid to the exterior from the inner peripheral space 5 of the housing are formed in the rear housing 2. Reference numerals 21, 21 designate tubes mounted on the intake port 19 and outlet port 20, respectively; 22 a bolt used to secure the bearing cover 8 to the rear housing 2; and 23, a nut in engagement with an external thread 10' of the end of the rotational shaft 10 in order to secure the pulley 9 to the rotational shaft 10.

The operation of the above-described vane pump will be described hereinafter. When the rotational shaft 10 and rotor 4 are rotated by the drive force from the pulley 9, the vanes 11a, 11b and 11c also rotate, and the pins 13 and 13 projected on the vanes 11a, 11b and 11c, respectively, and the sleeve bearings 14 and 14 slipped over the pins 13 and 13 rotate along the annular races 17 and 17. Since as shown in FIG. 3, the inner peripheral surface 1" of the housing and the annular race 17 are in coaxial relation and the annular race 17 and the rotor 4 are in eccentric relation, the vanes 11a, 11b and 11c are radially slidably moved in the vane grooves 12a, 12b and 12c of the rotor 4 to be projected and retracted repeatedly with the result that the volumes of the working spaces 5a, 5b and 5c defined by both the housings 1, 2, the rotor 4 and the vanes 11a, 11b and 11c repeatedly increase and decrease. That is, in FIG. 3, the working space 5a, with the rotation, increases its volume to suck the fluid from the intake port 19 (not shown; see FIG. 1) opening to portion 5a; the working space 5c, with the rotation, decreases its volume to discharge the fluid into the outlet port 20 (not shown; see FIG. 1) opening to portion 5c; and the working space 5b transfers the thus sucked fluid toward the outlet port 20. In the above-described operation, the end edges 11a', 11b' and 11c' of the vanes 11a, 11b and 11c are not in sliding contact with the inner peripheral surface 1" of the front housing, as previously mentioned, and therefore, abrasion or high heat hardly occurs. In addition, the sleeve bearing 14 slipped over the pin 13 is slidably rotated while being pressed against the outside diameter side by the centrifugal force within the annular race 17 of the retainer rings 16a and 16b while the retainer rings 16a and 16b follow the sleeve bearing 14 for rotation because the former are in the state to be rotatable by the ball bearings 18a and 18b, respectively. The relative sliding speed between the sleeve bearing 14 and the annular race 17 is low whereby the abrasions of annular race 17, retainer rings 16a and 16b, the sleeve bearing 14 and the like can be minimized.

It is believed that the fundamental mode of the present invention is now fully understood from the above-described description. The pump of the first embodiment shown in FIGS. 1 to 3 constitutes, in a sense, the core of the variations described below.

A vane pump belonging to the embodiment of FIGS. 4 and 5 is characterized in that bearings are rotatably mounted coaxially with the inner peripheral surface of a housing internally of both end walls of the housing, and projections provided on both side ends of vanes opposed to said end walls and the inner peripheral surfaces of the bearings are brought into contact with each other to define the protrusion of the vanes during rotation.

That is, the vane pump is designed to use bearings in place of the retainer rings used in the vane pumps as previously described to save the trouble of forming annular races in the retainer rings. According to this arrangement, in the vane moved out of the vane groove by virtue of the centrifugal force during rotation, the projections on the opposite ends thereof come into contact with the inner peripheral surfaces of the bearings provided coaxially of the inner peripheral surface of the housing, in other words, in eccentric fashion with respect to the rotor whereby the radial movement thereof is defined, and the vane rotates in non-contact with the housing. In that case, the bearings are also rotated approximately in synchronism with the rotor by the contact of the projections of the vane, and therefore the relative sliding movement between the bearings and the projections of the vane can be minimized.

One example of such a vane pump will be described hereinafter with reference to the drawings.

In FIGS. 4 and 5, journal bearings 45a and 45b formed of light-weight material such as aluminum are rotatably loosely mounted in annular recesses 15a and 15b formed coaxially with the inner peripheral surface of a housing in the inner surfaces 1' and 2' of both end walls of the housing, and the opposed peripheral surface (outer peripheral surface) and the opposed side with respect to the annular recesses 15a and 15b in journal bearings 45a and 45b are formed with dynamic pressure producing grooves 46 and 47 as shown in FIGS. 6(I) and 6(II). Pins 13 and 13 of vanes 11a, 11b and 11c are located on the inner peripheral sides of the journal bearings 45a and 45b, and the pins 13 and 13 come into contact with the inner peripheral surfaces of the bearings 45a and 45b during rotation whereby the vanes 11a, 11b and 11c are defined in their radial movement and can rotate in non-contact with the inner peripheral surface of the housing. Small-diameter bosses indicated at 48a and 48b are provided to impede unnecessary retraction of the vanes 11a, 11b and 11c into the vane grooves 12a, 12b and 12c when the pump stops, and to avoid an excessive shock between the pins 13 and 13 and the journal bearings 45a and 45b caused by the sudden protrusion of the vanes 11a, 11b and 11c when the pump starts, the bosses being projected concentric with the annular recesses 15a and 15b. This vane pump is constructed as described above. When the rotational shaft 10 and the rotor 4 are rotated in the direction as indicated at X by the drive force from the pulley 9, the vanes 11a, 11b and 11c rotate in non-contact with the front housing 1 and the rear housing 2 with the pins 13 and 13 placed in contact with the inner peripheral surfaces of the journal bearings 45a and 45b by virtue of the centrifugal force.

In the above-described operation, the vanes 11a, 11b and 11c are totally free from sliding contact with the front housing 1 and rear housing 12 as previously mentioned while the pins 13 and 13 integral with the vanes 11a, 11b and 11c come into sliding contact with the journal bearings 45a and 45b, but the amount of sliding contact thereof is small because the journal bearings 45a and 45b rotate approximately in synchronism with the rotor 4 by the frictional force with respect to the pins 13 and 13. Since the rotation of the journal bearings 45a and 45b is effected in a floated fashion by a great dynamic pressure produced in a fluid layer between the annular recesses 15a and 15b on the housing side by the dynamic pressure producing grooves 46 and 47, the sliding resistance is very small. For these reasons, it is possible to minimize the deterioration of the efficiency and abrasion resulting from the sliding resistance and sliding heat, and the temperature of the discharged fluid also lowers.

Next, a pump shown in FIG. 7 uses ball bearings 49a and 49b in place of the journal bearings 45a and 45b in the pump shown in FIG. 4, and the ball bearings 49a and 49b are mounted in the annular recesses 15a and 15b of the inner surfaces 1' and 2' of both end walls of the housing. That is, the ball bearings 49a and 49b have their outer races 50a and 50b fitted and secured to the inner peripheral surfaces of the annular recesses 15a and 15b, and the pins 13 and 13 come into contact with the inner peripheral surfaces of the inner races 51a and 51b whereby the inner races 51a and 51b rotate approximately in synchronism with the rotor 4, which pump has the function substantially equal to the pump of FIG. 4.

It is to be noted that since the rotor is eccentric, the relative angle between the vane and the inner peripheral surface of the housing repeatedly varies as rotation proceeds, and therefore, in the event the protrusion of the vane is defined as shown in the aforesaid drawings, the locus of the end edge of the vane assumes an approximate elliptic shape. It is therefore desirable that the inner peripheral surface of the housing is formed into a shape corresponding to the aforesaid locus so as to always maintain constant a clearance between the end edge of the vane and the inner peripheral surface of the housing.

The vane pump described above is designed so that the projections provided on the opposite side ends of the vane are placed in contact with the inner peripheral surface of the bearings provided coaxial with the inner peripheral surface of the housing and rotatably to define the radial movement thereof so that the vane may be rotated in non-contact with the housing, as described above. Therefore, it is possible to minimize the deterioration of the pump efficiency and the advance of abrasion resulting from the sliding resistance and the high sliding heat and to lower the temperature of fluids discharged from the pump, this exhibiting excellence performances for use with various apparatuses such as a supercharger in an engine, a compressor in a freezing cycle, and the like.

A vane pump belonging to the embodiment of FIG. 8 has a dynamic pressure bearing mechanism provided on the end or peripheral surface of a retainer, and particularly being characterized in that said dynamic pressure bearing mechanism comprises a groove or recess capable of producing dynamic pressure such as a spiral groove, a Rayleigh step groove or a herringbone groove or a recess or a combination of the aforesaid grooves and the recess.

One example of such a vane pump belonging to this type will be described hereinafter with reference to the drawings. The outer ends of the retainer rings 16a and 16b mounted as shown in FIG. 30 opposed to the inner side of the housing 1 are formed with spiral grooves 52 as shown in FIG. 9, and the outer peripheral surfaces thereof formed with Rayleigh step grooves 53 and herringbone grooves 54 as shown in FIGS. 10 and 11. The dynamic pressure bearing mechanism is provided to smoothly rotate the retainer rings 16a and 16b within the annular recesses 15a, 15b with respect to the housing 1.

The pins 13 are slidably rotated while being pressed against the outside diameter side by the centrifugal force within the annular race 17 of the retainer rings 16a and 16b but the retainer rings 16a and 16b follow the pins 13 and rotate since the retainer rings 16a and 16b are in the state in which they may be smoothly rotated by the dynamic pressure bearing mechanism. The relative sliding speed between the pins 13 and the annular race 17 is very small thereby minimizing the abrasions of the annular race 17, retainer rings 16a, 16b, pins 13, etc. The aforesaid dynamic pressure bearing mechanism can be replaced, in addition to the already mentioned spiral grooves 52, Rayleigh step grooves 53 and herringbone grooves 54, by various grooves, recesses and a combination of these which can produce dynamic pressure in a manner similar to the former.

The vane pump may have means for defining a protrusion of vanes toward the inner peripheral surface of the housing, wherein small-diameter bosses coaxial with the inner peripheral surface of a housing are projected internally of both end walls of the housing to define a backward movement of the vanes into the vane grooves. With this, when the rotor stops, the inner end edges of the vanes come into contact with the outer peripheral surfaces of the bosses to check the excessive retraction of the vanes into the vane grooves, thus preventing an occurrence of a sudden protrusion of the vanes at the time of start. For more details, see FIGS. 4 and 7 and the description thereof.

While we have described the preferred embodiment of the present invention, it will be obvious that various other modifications can be made without departing from the principle of the present invention. Accordingly, it is desired that all the modifications that may substantially obtain the effect of the present invention through the use of the structure substantially identical with or corresponding to the present invention are included in the scope of the present invention.

This application incorporates herein the disclosures of U.S. Ser. No. 075,006, filed July 17, 1987; U.S. Ser. No. 110,919 filed Oct. 21, 1987; U.S. Ser. No. 113,568 filed Oct. 26, 1987; and U.S. Ser. No. 115,677 filed Oct. 30, 1987.

Claims

1. A rotary machine for handling a fluid comprising a housing means having a rotor chamber, said rotor chamber having an inner peripheral surface, a rotor means rotatably mounted in said rotor chamber, said inner peripheral surface having a central axis which is eccentrically disposed relative to the axis of rotation of said rotor means, said rotor means having a plurality of generally radially disposed vane slots, a plurality of vane means slidably mounted in said vane slots and operable to define variable volume chambers for said fluid as said rotor means rotates and said vane means move generally radially in and out of said vane slots, said vane means having longitudinal ends, projection means projecting from said longitudinal ends, said housing means having end walls which define longitudinal ends of said rotor chamber, annular recesses in said end walls coaxial with said central axis, said recesses having recess walls, annular ring means rotatable in said annular recesses about said central axis, an annular channel in each of said ring means coaxial with said central axis, said projection means on said vane means extending into said annular channels such that during rotation of said rotor means, the resulting centrifugal force urges said vane means radially outwardly of the respective vane slot such that said projection means engages said channels to limit the extent of outward radial movement of said vane means from its respective vane slot to preclude sliding contact between said vane means and said inner peripheral surface of said housing means, said ring means having an outer surface, and groove means on said outer surface operable to produce a layer of said fluid between said outer surface and said recess walls during rotation of said ring means to thereby minimize the frictional rotational resistance of said ring means in said recesses, said ring means thereby being rotated in approximate synchronism with said rotor means by the frictional contact between said projection means and said channels in said ring means.

2. A rotary machine according to claim 1, wherein each of said channels has a constant generally U-shaped cross-sectional configuration throughout its annular extent.

3. A rotary machine according to claim 1, wherein each of said recesses has a constant generally U-shaped cross-sectional configuration throughout its annular extent.

4. A rotary machine according to claim 1, wherein said ring means has an outer peripheral surface and a generally planar end surface perpendicular to said central axis, said recess having a bottom wall juxtaposed to said end surface of said ring means, groove means being formed on said outer peripheral surface and on said generally planar end surface of said ring means, said channel being superimposed relative to said end surface of said ring means, said end surface of said ring means being devoid of any through openings to said superimposed channel to thereby enable maintaining said layer of fluid between said end surface of said ring means and said bottom wall of said recess during rotation of said ring means in said recess.

5. A rotary machine according to claim 1, wherein said ring means has an outer peripheral surface and an end surface perpendicular to said central axis, said groove means being formed on said outer peripheral surface and on said end surface of said ring means.

6. A rotary machine according to claim 5, wherein said grooves are helical grooves.

7. A rotary machine according to claim 5, wherein said grooves are herringbone grooves.

8. A rotary machine according to claim 5, wherein said grooves are Raleigh-step grooves.

9. A rotary machine according to claim 5, wherein each of said recesses has a radially outer cylindrical wall and a bottom wall perpendicular to said central axis, said layer of fluid being formed between said outer peripheral surface of said ring means and said radially outer cylindrical wall of said recess and between said end surface of said ring means and said bottom wall of said recess.

10. A rotary machine according to claim 9, wherein said radially outer cylindrical wall of said recess is an uninterrupted cylindrical wall devoid of openings to thereby enable maintaining said layer of fluid between said outer peripheral surface of said ring means and said radially outer cylindrical wall of said recess during rotation of said ring means in said channel.

11. A rotary machine for handling a fluid comprising a housing means having a rotor chamber, said rotor chamber having an inner peripheral surface, a rotor means rotatably mounted in said rotor chamber, said inner peripheral surface having a central axis which is eccentrically disposed relative to the axis of rotation of said rotor means, said rotor means having a plurality of generally radially disposed vane slots, a plurality of vane means slidably mounted in said vane slots and operable to define variable volume chambers for said fluid as said rotor means rotates and said vane means move generally radially in and out of said vane slots, said vane means having longitudinal ends, projection means projecting from said longitudinal ends, said housing means having end walls which define longitudinal ends of said rotor chamber, annular recesses in said end walls coaxial with said central axis, said recesses having recess walls, annular ring means rotatable in said annular recesses about said central axis, an annular channel in each of said ring means coaxial with said central axis, said projection means on said vane means extending into said annular channels such that during rotation of said rotor means, the resulting centrifugal force urges said vane means radially outwardly of the respective vane slot such that said projection means engages said channels to limit the extent of outward radial movement of said vane means from its respective vane slot to preclude sliding contact between said vane means and said inner peripheral surface of said housing means, said ring means having an outer cylindrical surface and an end surface perpendicular to said central axis, and dynamic pressure producing groove means formed in said surfaces and operable during rotation of said ring means to provide a layer of said fluid between said surfaces and said recess walls to thereby minimize the frictional rotational resistance of said ring means in said recesses and thereby minimizing the sliding contact between said projection means and said channels as said ring means rotate approximately in synchronism with said rotor means by the frictional engagement between said projection means and said channels in said ring means.

12. A rotary machine according to claim 11, wherein each of said end walls which define the longitudinal ends of said rotor chamber have an outer radial end wall portion and an inner radial end wall portion, said outer radial end wall portion being axially spaced from said inner radial end wall portion.

13. A rotary machine according to claim 12, wherein said recesses are disposed in said outer radial end wall portion of said housing means.

14. A rotary machine according to claim 13, wherein said recesses each have an inner radial cylindrical wall, said inner radial end wall portion of said housing means having an outer cylindrical wall which is axially aligned with said inner radial cylindrical wall of said recess.

15. A rotary machine according to claim 14, wherein said outer cylindrical wall of said inner radial end wall portion of said housing means has an axis coincident with said central axis.