EP2971779B1

EP2971779B1 - Vane pump with multiple control chambers

Info

Publication number: EP2971779B1
Application number: EP14763782.1A
Authority: EP
Inventors: Matthew Williamson; David R. Shulver; Cezar Tanasuca
Original assignee: Magna Powertrain Fpc LP
Current assignee: Magna Powertrain Fpc LP
Priority date: 2013-03-13
Filing date: 2014-03-06
Publication date: 2020-08-05
Anticipated expiration: 2034-03-06
Also published as: MX2015012591A; MX365215B; CN105074217A; KR101789899B1; JP2016510102A; CA3014939C; EP2971779A4; WO2014141013A1; JP6130525B2; KR20150128866A; CA2902472C; CA3014939A1; CN105074217B; CA2902472A1; EP2971779A1

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. Utility Application No. 13/800,227, filed on March 13, 2013 , which is a continuation-in-part of United States Patent Application No. 13/686,680, filed on November 27, 2012 , which is a continuation of United States Patent Application No. 12/879,406 filed on September 10, 2010 , now U.S. Patent No. 8,317,486, issued November 27, 2012 , which is a continuation of United States Patent Application No. 11/720,787, filed June 4, 2007 , now Patent No. 7,794,217, issued September 14, 2010 , which is a National Stage of International Application No. PCT/CA2005/001946, filed December 21, 2005 , which claims the benefit of U.S. Provisional Application No. 60/639,185, filed on December 22, 2004 ..

FIELD

The present invention relates to a variable capacity vane pump. More specifically, the present invention relates to a variable capacity vane pump including multiple control chambers. Different sources of pressurized fluid may be provided to the control chambers to control the pump displacement.

BACKGROUND

Variable capacity vane pumps are well known and can include a capacity adjusting element, in the form of a pump control ring that can be moved to alter the rotor eccentricity of the pump and hence alter the volumetric capacity of the pump. If the pump is supplying a system with a substantially constant orifice size, such as an automobile engine lubrication system, changing the output flow of the pump is equivalent to changing the pressure produced by the pump.
Having the ability to alter the volumetric capacity of the pump to maintain an equilibrium pressure is important in environments such as automotive lubrication pumps, wherein the pump will be operated over a range of operating speeds. In such environments, to maintain an equilibrium pressure it is known to employ a feedback supply of the working fluid (e.g. lubricating oil) from the output of the pump to a control chamber adjacent the pump control ring, the pressure in the control chamber acting to move the control ring, typically against a biasing force from a return spring, to alter the capacity of the pump.
When the pressure at the output of the pump increases, such as when the operating speed of the pump increases, the increased pressure is applied to the control ring to overcome the bias of the return spring and to move the control ring to reduce the capacity of the pump, thus reducing the output flow and hence the pressure at the output of the pump.
Conversely, as the pressure at the output of the pump drops, such as when the operating speed of the pump decreases, the decreased pressure applied to the control chamber adjacent the control ring allows the bias of the return spring to move the control ring to increase the capacity of the pump, raising the output flow and hence pressure of the pump. In this manner, an equilibrium pressure is obtained at the output of the pump.
The equilibrium pressure is determined by the area of the control ring against which the working fluid in the control chamber acts, the pressure of the working fluid supplied to the chamber and the bias force generated by the return spring.
Conventionally, the equilibrium pressure is selected to be a pressure which is acceptable for the expected operating range of the engine and is thus somewhat of a compromise as, for example, the engine may be able to operate acceptably at lower operating speeds with a lower working fluid pressure than is required at higher engine operating speeds. In order to prevent undue wear or other damage to the engine, the engine designers will select an equilibrium pressure for the pump which meets the worst case (high operating speed) conditions. Thus, at lower speeds, the pump will be operating at a higher capacity than necessary for those speeds, wasting energy pumping the surplus, unnecessary, working fluid.
CA2588817A1 discloses a variable capacity vane pump with a first and a second control chamber. The control chambers are separated from each other and the rest of the pump by sealings and by the pivot pin. The remaining forces on the pivot pin are not optimized.
WO2006045190 A1 discloses a variable vane pump without a control chamber only showing a pump with a high pressure and low pressure side with a separation by seals. The pivot pin is located in the high pressure fluid areas between the seals. The control of this pump is made either with a piston applying a force versus the spring or with pressure from the pump applying a force versus a control tab 204.
It is desired to have a variable capacity vane pump which can provide at least two selectable equilibrium pressures in a reasonably compact pump housing. It is also desired to have a variable capacity vane pump wherein reaction forces on the pivot pin for the pump control ring are reduced.

SUMMARY

It is an object of the present invention to provide a novel variable capacity vane pump which obviates or mitigates at least one disadvantage of the prior art.
A variable capacity vane pump includes a first control chamber between a pump casing and a first portion of a pump control ring. The first portion of the control ring circumferentially extends on either side of a pivot pin. A second control chamber is provided between the pump casing and a second portion of the pump control ring. The first and second control chambers are operable to receive pressurized fluid to create a force to move the pump control ring to reduce the volumetric capacity of the pump. A return spring biases the pump ring toward a position of maximum volumetric capacity.
A variable volumetric capacity vane pump includes a pump casing including a pump chamber having an inlet port and an outlet port. A pump control ring pivots within the pump chamber to alter the volumetric capacity of the pump. A rotor is rotatably mounted within the pump control ring and includes slots in receipt of slidable vanes. First, second, and third control chambers are formed between the pump casing and an outer surface of the pump control ring. The first and second control chambers are selectively operable to receive pressurized fluid to create forces to move the pump control ring to reduce the volumetric capacity of the pump. The third chamber is in constant receipt of pressurized fluid from the outlet of the pump. A return spring is positioned within the casing to act between the pump ring and the casing to bias the pump ring toward a position of maximum volumetric capacity and act against the force generated by the pressurized fluid within the first and second control chambers.

DRAWINGS

Preferred embodiments of the present invention will now be described, by way of example only, with reference to the attached Figures, wherein:

Figure 1 is a front view of a variable capacity vane pump not falling under the scope of the claims with the control ring positioned for maximum rotor eccentricity;
Figure 2 is a front perspective view of the pump of Figure 1 with the control ring positioned for maximum rotor eccentricity;
Figure 3 is the a front view of the pump of Figure 1 with the control ring position for minimum eccentricity and wherein the areas of the pump control chambers are in hatched line;
Figure 4 shows a schematic representation of a prior art variable capacity vane pump;
Figure 5 shows a front view of the pump of Figure 1 wherein the rotor and vanes have been removed to illustrate the forces within the pump;
Figure 6 provides an exploded perspective view of a variable displacement pump according to the invention;
Figure 7 provides another exploded perspective view of the pump depicted in Figure 6;
Figure 8 is a cross-sectional view taken through the pump depicted in Figures 6 and 7;
Figure 9 is a schematic including a cross-sectional view of another alternate variable capacity vane pump;
Figure 10 is an exploded perspective view of the vane pump depicted in Figure 9; and
Figure 11 is a partial plan view of the pump depicted in Figures 9 and 10 having the pump control ring positioned at a location of minimum pump volumetric capacity.

DETAILED DESCRIPTION

A variable capacity vane pump is indicated generally at 20 in Figures 1, 2 and 3.
Referring now to Figures 1, 2 and 3, pump 20 includes a housing or casing 22 with a front face 24 which is sealed with a pump cover (not shown) and a suitable gasket, to an engine (not shown) or the like for which pump 20 is to supply pressurized working fluid.
Pump 20 includes an input member or drive shaft 28 which is driven by any suitable means, such as the engine or other mechanism to which the pump is to supply working fluid, to operate pump 20. As drive shaft 28 is rotated, a pump rotor 32 located within a pump chamber 36 is turned with drive shaft 28. A series of slidable pump vanes 40 rotate with rotor 32, the outer end of each vane 40 engaging the inner surface of a pump control ring 44, which forms the outer wall of pump chamber 36. Pump chamber 36 is divided into a series of working fluid chambers 48, defined by the inner surface of pump control ring 44, pump rotor 32 and vanes 40. The pump rotor 32 has an axis of rotation that is eccentric from the center of the pump control ring 44.
Pump control ring 44 is mounted within casing 22 via a pivot pin 52 which allows the center of pump control ring 44 to be moved relative to the center of rotor 32. As the center of pump control ring 44 is located eccentrically with respect to the center of pump rotor 32 and each of the interior of pump control ring 44 and pump rotor 32 are circular in shape, the volume of working fluid chambers 48 changes as the chambers 48 rotate around pump chamber 36, with their volume becoming larger at the low pressure side (the left hand side of pump chamber 36 in Figure 1) of pump 20 and smaller at the high pressure side (the right hand side of pump chamber 36 in Figure 1) of pump 20. This change in volume of working fluid chambers 48 generates the pumping action of pump 20, drawing working fluid from an inlet port 50 and pressurizing and delivering it to an outlet port 54.
By moving pump control ring 44 about pivot pin 52 the amount of eccentricity, relative to pump rotor 32, can be changed to vary the amount by which the volume of working fluid chambers 48 change from the low pressure side of pump 20 to the high pressure side of pump 20, thus changing the volumetric capacity of the pump. A return spring 56 biases pump control ring 44 to the position, shown in Figures 1 and 2, wherein the pump has a maximum eccentricity.
As mentioned above, it is known to provide a control chamber adjacent a pump control ring and a return spring to move the pump ring of a variable capacity vane pump to establish an equilibrium output flow, and its related equilibrium pressure.
However, pump 20 includes two control chambers 60 and 64, best seen in Figure 3, to control pump ring 44. Control chamber 60, the rightmost hatched area in Figure 3, is formed between pump casing 22, pump control ring 44, pivot pin 52 and a resilient seal 68, mounted on pump control ring 44 and abutting casing 22. In the illustrated embodiment, control chamber 60 is in direct fluid communication with pump outlet 54 such that pressurized working fluid from pump 20 which is supplied to pump outlet 54 also fills control chamber 60.
As will be apparent to those of skill in the art, control chamber 60 need not be in direct fluid communication with pump outlet 54 and can instead be supplied from any suitable source of working fluid, such as from an oil gallery in an automotive engine being supplied by pump 20.
Pressurized working fluid in control chamber 60 acts against pump control ring 44 and, when the force on pump control ring 44 resulting from the pressure of the pressurized working is sufficient to overcome the biasing force of return spring 56, pump control ring 44 pivots about pivot pin 52, as indicated by arrow 72 in Figure 3, to reduce the eccentricity of pump 20. When the pressure of the pressurized working fluid is not sufficient to overcome the biasing force of return spring 56, pump control ring 44 pivots about pivot pin 52, in the direction opposite to that indicated by arrow 72, to increase the eccentricity of pump 20.
Pump 20 further includes a second control chamber 64, the leftmost hatched area in Figure 3, which is formed between pump casing 22, pump control ring 44, resilient seal 68 and a second resilient seal 76. Resilient seal 76 abuts the wall of pump casing 22 to separate control chamber 64 from pump inlet 50 and resilient seal 68 separates chamber 64 from chamber 60.
Control chamber 64 is supplied with pressurized working fluid through a control port 80. Control port 80 can be supplied with pressurized working fluid from any suitable source, including pump outlet 54 or a working fluid gallery in the engine or other device supplied from pump 20. A control mechanism (not shown) such as a solenoid operated valve or diverter mechanism is employed to selectively supply working fluid to chamber 64 through control port 80, as discussed below. As was the case with control chamber 60, pressurized working fluid supplied to control chamber 64 from control port 80 acts against pump control ring 44.
As should now be apparent, pump 20 can operate in a conventional manner to achieve an equilibrium pressure as pressurized working fluid supplied to pump outlet 54 also fills control chamber 60. When the pressure of the working fluid is greater than the equilibrium pressure, the force created by the pressure of the supplied working fluid over the portion of pump control ring 44 within chamber 60 will overcome the force of return spring 56 to move pump ring 44 to decrease the volumetric capacity of pump 20. Conversely, when the pressure of the working fluid is less than the equilibrium pressure, the force of return spring 56 will exceed the force created by the pressure of the supplied working fluid over the portion of pump control ring 44 within chamber 60 and return spring 56 will to move pump ring 44 to increase the volumetric capacity of pump 20.
However, unlike with conventional pumps, pump 20 can be operated at a second equilibrium pressure. Specifically, by selectively supplying pressurized working fluid to control chamber 64, via control port 80, a second equilibrium pressure can be selected. For example, a solenoid-operated valve controlled by an engine control system, can supply pressurized working fluid to control chamber 64, via control port 80, such that the force created by the pressurized working fluid on the relevant area of pump control ring 44 within chamber 64 is added to the force created by the pressurized working fluid in control chamber 60, thus moving pump control ring 44 further than would otherwise be the case, to establish a new, lower, equilibrium pressure for pump 20.
As an example, at low operating speeds of pump 20, pressurized working fluid can be provided to both chambers 60 and 64 and pump ring 44 will be moved to a position wherein the capacity of the pump produces a first, lower, equilibrium pressure which is acceptable at low operating speeds.
When pump 20 is driven at higher speeds, the control mechanism can operate to remove the supply of pressurized working fluid to control chamber 64, thus moving pump ring 44, via return spring 56, to establish a second equilibrium pressure for pump 20, which second equilibrium pressure is higher than the first equilibrium pressure.
While in the illustrated example chamber 60 is in fluid communication with pump outlet 54, it will be apparent to those of skill in the art that it is a simple matter, if desired, to alter the design of control chamber 60 such that it is supplied with pressurized working fluid from a control port, similar to control port 80, rather than from pump outlet 54. In such a case, a control mechanism (not shown) such as a solenoid operated valve or a diverter mechanism can be employed to selectively supply working fluid to chamber 60 through the control port. As the area of control ring 44 within each of control chambers 60 and 64 differs, by selectively applying pressurized working fluid to control chamber 60, to control chamber 64 or to both of control chambers 60 and 64 three different equilibrium pressures can be established, as desired.
As will, also be apparent to those of skill in the art, should additional equilibrium pressures be desired, pump casing 22 and pump control ring 44 can be fabricated to form one or more additional control chambers, as necessary.
Pump 20 offers a further advantage over conventional vane pumps such as pump 200 shown in Figure 4. In conventional vane pumps such as pump 200, the low pressure fluid 204 in the pump chamber exerts a force on pump ring 216 as does the high pressure fluid 208 in the pump chamber. These forces result in a significant net force 212 on the pump control ring 216 and this force is largely carried by pivot pin 220 which is located at the point where force 212 acts.
Further, the high pressure fluid within the outlet port 224 (indicated in dashed line), acting over the area of pump ring 216 between pivot pin 220 and resilient seal 222, also results in a significant force 228 on pump control ring 216. While force 228 is somewhat offset by the force 232 of return spring 236, the net of forces 228 less force 232 can still be significant and this net force is also largely carried by pivot pin 220.
Thus pivot pin 220 carries large reaction forces 240 and 244, to counter net forces 212 and 228 respectively, and these forces can result in undesirable wear of pivot pin 220 over time and/or "stiction" of pump control ring 216, wherein it does not pivot smoothly about pivot pin 220, making fine control of pump 200 more difficult to achieve.
As shown in Figure 5, the low pressure side 300 and high pressure side 304 of pump 20 result in a net force 308 which is applied to pump control ring 44 almost directly upon pivot pin 52 and a corresponding reaction force, shown as a horizontal (with respect to the orientation shown in the Figure) force 312, is produced on pivot pin 52. Unlike conventional variable capacity vane pumps such as pump 200, in pump 20 resilient seal 68 is located relatively closely to pivot pin 52 to reduce the area of pump control ring 44 upon which the pressurized working fluid in control chamber 60 acts and thus to significantly reduce the magnitude of the force 316 produced on pump control ring 44.
Further, control chamber 60 is positioned such that force 316 includes a horizontal component, which acts to oppose force 308 and thus reduce reaction force 312 on pivot pin 52. The vertical (with respect to the orientation shown in the Figure) component of force 316 does result in a vertical reaction force 320 on pivot pin 52 but, as mentioned above, force 316 is of less magnitude than would be the case with conventional pumps and the vertical reaction force 320 is also reduced by a vertical component of the biasing force 324 produced by return spring 56
Thus, the unique positioning of control chamber 60 and return spring 56, with respect to pivot pin 52, results in reduced reaction forces on pivot pin 52 and can improve the operating lifetime of pump 20 and can reduce "stiction" of pump control ring 44 to allow smoother control of pump 20. As will be apparent to those of skill in the art, this unique positioning is not limited to use in variable capacity vane pumps with two or more equilibrium pressures and can be employed with variable capacity vane pumps with single equilibrium pressures.
Figures 6-8 depict a variable capacity vane pump constructed in accordance with the teachings of the present disclosure and identified at reference numeral 400. Pump 400 includes a housing 402 including a first cover 404 fixed to a second cover 406 by a plurality of fasteners 408. A dowel pin 409 aligns the first and second covers. Pump 400 includes an input or a drive shaft 410 having at least one end protruding from housing 402. Drive shaft 410 may be driven by any suitable means such as an internal combustion engine. A rotor 412 is fixed for rotation with drive shaft 410 and positioned within a pumping chamber 414 defined by pump housing 402. Vanes 416 are slidably engaged within radially extending slots 418 defined by rotor 412. Outer surfaces 420 of each vane slidably engage a sealing surface 422 of a moveable pump control ring 424. Sealing surface 422 is shaped as a circular cylinder having a center which may be offset from a center of drive shaft 410. Retaining rings 425 limit the inboard extent to which the vanes may slide to maintain engagement of surfaces 420 with surface 422.
Pump control ring 424 is positioned within chamber 414 and is pivotally coupled to housing 402 via a pivot pin 426. Pump control ring 424 includes a radially outwardly extending arm 428. A bias spring 430 engages arm 428 to urge pump control ring 424 toward a position of maximum capacity.
Pump control ring 424 includes first through third projections identified at reference numerals 432, 434, 436. Each of the first through third projections includes an associated groove 438, 440, 442. A first seal assembly 446 is positioned within first groove 438 to sealingly engage housing 402. A second seal assembly 448 is positioned within second groove 440 to sealingly engage a different portion of housing 402. A third seal assembly 450 is positioned within third groove 442. Third seal assembly 450 sealingly engages another portion of housing 402. Each seal assembly includes a cylindrically shaped first elastomer 452 engaging a second elastomer 454 having a substantially rectangular cross-section. Each seal assembly is positioned within an associated seal groove. A first chamber 460 extends between first seal assembly 446 and third seal assembly 450 and between an outer surface of pump control ring 424 and housing 402. A second chamber 462 is defined between first seal assembly 446 and second seal assembly 448, as well as the other surface of pump control ring 424 and housing 402.
First seal assembly 446 is positioned relative to pivot pin 426 to define a first radius or moment arm R₁. The position of third seal assembly 450 also defines a radius or moment arm R₂ in relation to the center of pivot pin 426. The length of moment arm R₁ defined by first seal assembly 446 is greater than the length of moment arm R₂ defined by the position of third seal assembly 450 such that a turning moment is generated when first chamber 460 is pressurized. The turning moment urges pump control ring 424 to oppose the force applied by bias spring 430. First seal assembly 446 is circumferentially spaced apart from third seal assembly 450 an angle greater than 100 degrees with the angle vertex being the center of the pump control ring cavity bounded by surface 422. Figure 8 depicts this angle as approximately 117 degrees. It should be appreciated that the position of first seal assembly 446 and second seal assembly 448 relative to pivot pin 426 also causes the pressurized fluid entering the second chamber to impart a moment of pump control ring 424 that opposes the force applied by bias ring 430.
An outlet port 470 extends through housing 402 to allow pressurized fluid to exit pump 400. An enlarged discharge cavity 472 is defined by housing 402. Enlarged discharge cavity 472 extends from third seal assembly 450 to outlet port 470. It should be appreciated that enlarged discharge cavity extends on either side of pivot pin 426. This feature is provided by having the outer surface 476 of pump control ring 424 being spaced apart from an inner wall 478 of housing 402. In particular, first cover 404 includes a stanchion 482 including an aperture 484 for receipt of pivot pin 426. Stanchion 482 is spaced apart from inner wall 478. Relatively low resistance to fluid discharge is encountered by incorporating this configuration.
In operation, pump 400 may be configured to operate in at least two different modes. In each of the modes of operation, first chamber 460 is provided pressurized fluid at pump outlet pressure. In a first mode of operation, second chamber 462 may be selectively supplied pressurized fluid from any source of pressure through the use of an on/off solenoid valve. In this first operation mode, an upper equilibrium pressure of pump 400 is defined by the pump outlet pressure and a lower equilibrium pressure may be defined by the second source.
In a second mode of operation, pump 400 may be associated with a proportional solenoid valve which may be operable to continuously vary the pressure to second chamber 462 and allow intermediate equilibrium pressures. As such, pump 400 operates at an infinite number of equilibrium pressures and not only the two fixed pressures as provided in the first arrangement.
Figures 9-11 depict another alternate variable displacement pump at reference numeral 500. Pump 500 may form a portion of a lubrication system 502 useful for supplying pressurized lubricant to an engine, transmission or other vehicle power transfer mechanism. Lubrication system 502 includes a reservoir 504 providing fluid to an inlet pipe 506 in fluid communication with an inlet 508 of pump 500. An outlet 510 of pump 500 provides pressurized fluid to a cooler 512, a filter 514 and a main gallery 516. Pressurized fluid travelling through main gallery 516 is supplied to the component to be lubricated, such as an internal combustion engine. Pressurized fluid is also provided to a feedback line 518. Feedback line 518 is in direct communication with a first control chamber 520 of pump 500. A solenoid valve 522 acts to control the fluid communication between feedback line 518 and a second control chamber 524.
Pump 500 is similar to pump 400 regarding the use of a pivoting pump control ring 526, first through fourth seal assemblies 528, 530, 532, 534, a bias spring 536, vanes 538, a rotor 540, a rotor shaft 542 and retaining rings 544. Similar elements will not be described in detail.
First seal assembly 528 and second seal assembly 530 act in concert with an outer surface 546 of control ring 526 and a cavity wall 548 to at least partially define first control chamber 520. Second control chamber 524 extends between second seal assembly 530 and third seal assembly 532 as well as between outer surface 546 and cavity wall 548. An outlet passage 550 extends between first seal assembly 528 and fourth seal assembly 534. A stanchion 554 includes an aperture 556 in receipt of a pivot pin 558 to couple control ring 526 for rotation with stanchion 554. As previously described in relation to pump 400, the enlarged outlet passage 550 substantially reduces restriction to pressurized fluid exiting pump 500. In yet another alternate arrangement not depicted, pivot pin 558 may provide a sealing function and allow removal of fourth seal assembly 534.
First seal assembly 528 is positioned at a first distance from a center of pivot pin 558 to define a first moment arm R₁. In similar fashion, a moment arm R₂ is defined by the position of fourth seal assembly 534 in relation to pivot pin 558. If moment arm lengths R₁ and R₂ are set to be equal, the pressure within outlet passage 550 provides no contribution to pressure regulation. On the other hand, moment arms R₁ and R₂ may be designed to be unequal if a permanent contribution from the pump outlet pressure is desired. As such, outlet passage 550 may function as a third control chamber. For example, it may be beneficial to provide a pressure regulation at a vehicle cold start condition. At cold start, it may be desirable to urge control ring 526 toward a position of minimum displacement as shown in Figure 11. This may be accomplished by having moment arm R₁ be longer than moment arm R₂. Alternatively, it may be desirable to compensate for forces acting internally within pump 500 and acting on pump control ring 526. To address this concern, it may be desirable to construct moment arm R₁ at a length less than the length of moment arm R₂ to urge pump control ring 526 toward the maximum displacement position. Figure 9 represents control ring 526 at a position of maximum eccentricity, thereby providing maximum pump displacement. For the pump depicted in Figures 9-11, first seal assembly 528 is circumferentially spaced apart from fourth seal assembly 534 an angle greater than 80 degrees.
In operation, first control chamber 520 is always active and may be in receipt of pressurized fluid from any source, such as the pump output. Second control chamber 524 is switched on and off via solenoid 522. The supply of pressurized fluid may be from any source. Outlet passage 550, or third control chamber 550, may or may not contribute to the pressure controlling function as described in relation to the relative lengths of moment arms R₁ and R₂.
Pump 500 need only be associated with an on/off type solenoid valve 522 due to the provision of three control chambers. Third control chamber 550 provides for a very low restriction outlet flow path. First control chamber 520 and second control chamber 524 allow two equilibrium pressures that are determined by sources other than the pump outlet pressure.
The above-described embodiments of the disclosure are intended to be examples of the present disclosure and alterations and modifications may be effected thereto, by those of skill in the art, without departing from the scope of the disclosure which is defined solely by the claims appended hereto.

Claims

A variable capacity vane pump (400) comprising:
a pump casing (402) including a pump chamber (414);

a pump control ring (424) moveable within the pump chamber (414) to vary the volumetric capacity of the pump;

a vane pump rotor (412) positioned within a cavity of the pump control ring (424) and being rotatable about an axis offset from a center of the pump control ring cavity;

vanes (416) being driven by the rotor (412) and engaging an inside surface (422) of the pump control ring (424);

a first control chamber (460) between the pump casing (402) and a first portion of the pump control ring (424), the first control chamber (460, 520) operable to receive pressurized fluid to create a force to move the pump control ring to reduce the volumetric capacity of the pump;

a second control chamber (462, 524) between the pump casing (402) and a second portion of the pump control ring (424) between a first seal assembly (446) and a second seal assembly (448), the second control chamber operable to receive pressurized fluid to create a force to move the pump control ring to reduce the volumetric capacity of the pump; and

a return spring (430) biasing the pump control ring (424) toward a position of maximum volumetric capacity, the return spring (430) acting against the forces created by the pressurized fluid within the first and second control chambers (460, 462), characterized in the first portion of the pump control ring (424) circumferentially extending on either side of a pivot pin (52, 426) between the first seal assembly (446) and a third seal assembly (450).
The variable capacity vane pump of claim 1, characterized in the third seal assembly (450) being positioned closer to the pivot pin (426) than the first seal assembly (446).
The variable capacity vane pump of claim 2, wherein the pump control ring (424) includes first and second transversely extending and circumferentially spaced apart grooves (438, 440) wherein the first groove is in receipt of the first seal assembly (466), the second seal assembly (448) being positioned within the second groove (440) in sealing engagement with the pump casing.
The variable capacity vane pump of claim 3, wherein the pump casing (402) includes a stanchion (482) spaced apart from a casing wall engaged by the seals, the pivot pin (426) being fixed to the stanchion (482).
The variable capacity vane pump of claim 1, wherein the first chamber (460) is in continuous receipt of fluid at the pump outlet pressure.
The variable capacity vane pump of claim 5, wherein the first seal assembly (446) is circumferentially spaced apart from the third seal assembly an angle greater than 100 degrees, the vertex of the angle being at the center of the pump control ring cavity.