Patent Grant
8057201
The present invention relates to variable displacement vane pumps. More specifically, the present invention relates to variable displacement vane pumps in which at least two different equilibrium pressures can be selected between by supplying working fluid to two or more control chambers which act against the control ring.
Variable displacement vane pumps are well known and can include a displacement adjusting element, in the form of a pump control ring that can be pivoted or moved to alter the rotor eccentricity of the pump and hence alter the volumetric displacement 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 displacement volume of the pump is equivalent to changing the pressure produced by the pump.
Having the ability to alter the volumetric displacement 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 where the pressure of the working fluid is used to generate a force, either directly or via a moveable piston, to move the control ring, typically against a biasing force from a return spring, to alter the displacement 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 in the control chamber is applied to the control ring, either directly or via a piston, to overcome the bias of the return spring and to move the control ring to reduce the displacement of the pump, thus reducing the output volume 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 supplied to the control chamber allows the bias of the return spring to move the control ring to increase the displacement of the pump, raising the output volume 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, or piston, 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, supplying a greater pressure of working fluid than required for those speeds, wasting energy pumping the surplus, unnecessary, working fluid.
It is desired to have variable displacement vane pumps which can provide at least two selectable equilibrium pressures in a reasonably compact pump housing.
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.
According to a first aspect of the present invention, there is provided a variable capacity vane pump having a pump control ring which is moveable to alter the capacity of the pump, the pump being operable at least two selected equilibrium pressures, comprising: a pump housing having a rotor chamber therein; a vane pump rotor rotatably mounted in the rotor chamber; a pump control ring enclosing the vane pump rotor within said rotor chamber, the pump control ring being moveable within the rotor chamber to alter the volumetric displacement of the pump; a first control chamber between the pump housing and the pump control ring, the first control chamber operable to receive pressurized fluid to create a force to move the pump control ring to reduce the volumetric displacement of the pump; a second control chamber operable to receive pressurized fluid to create a force to move the pump control ring to alter the volumetric displacement of the pump; and a biasing spring acting between pump control ring and the pump housing to bias the pump control ring towards a position of maximum volumetric displacement, the biasing spring acting against the force of at least the first control chamber to establish an equilibrium pressure and wherein the supply of pressurized fluid to the second control chamber can be applied or removed to change the equilibrium pressure of the pump.
Preferred embodiments of the present invention will now be described, by way of example only, with reference to the attached Figures, wherein:
A variable capacity vane pump in accordance with an embodiment of the present invention is indicated generally at 20 in
Pump 20 includes a pump rotor 28 rotatably mounted within a rotor chamber 32 and rotor 28 is turned with a drive shaft 34. A series of slidable pump vanes 36 rotate with rotor 28, the radially outer end of each vane 36 engaging the inner surface of a pump control ring 40 to divide the volume about rotor 28 into a series of pumping chambers 44, defined by the inner surface of pump control ring 40, pump rotor 28 and vanes 36.
In the illustrated embodiment, pump control ring 40 is mounted within housing 24 via a pivot pin 48 mounted in housing 24. It is also contemplated that pump control ring 40 can be pivotally mounted within housing 24 via any other suitable method as will occur to those of skill in the art.
The pivoting of pump control ring 40 allows the center of pump control ring 40 to be moved relative to the center of rotor 28. As the center of pump control ring 40 is located eccentrically with respect to the center of pump rotor 28 and each of the interior of pump control ring 40 and pump rotor 28 are circular in shape, the volume of pumping chambers 44 changes as pumping chambers 44 rotate around rotor chamber 32, with their volume becoming larger at the low pressure side (the left hand side of rotor chamber 32 in
This change in volume of pumping chambers 44 generates the pumping action of pump 20, drawing working fluid from an inlet port (schematically shown) at the low pressure side and pressurizing and delivering the working fluid to an outlet port (schematically shown) at the high pressure side.
By moving pump control ring 40 about pivot surfaces 48 and 50, the amount of eccentricity, relative to pump rotor 28, can be changed to vary the amount by which the volume of pumping chambers 44 changes from the low pressure side of pump 20 to the high pressure side of pump 20, thus changing the volumetric capacity/displacement of pump 20.
Control ring 40 includes a control structure 56 opposite pivot surface 48 from rotor 32. Control structure 56 includes a spring surface 60 and a biasing spring 64 acts between spring surface 60 and pump housing 24 to bias control ring 40 toward the position of maximum eccentricity/maximum displacement for pump 20.
Control structure 56 further includes first and second reaction surfaces, 68 and 72 respectively which, in conjunction with pump housing 24 and resilient seals 52, form first and second control chambers, 76 and 80 respectively.
Each of first and second control chambers 76 and 80 can be supplied with pressurized working fluid from pump 20, either directly from the outlet port of pump 20, or via a pump control system 21 which is being supplied with pressurized working fluid from pump 20. Pump control system 21 is a series of valves that can be operated mechanically or electronically in response to input signals, such as engine speed and oil temperature.
Pressurized working fluid in first control chamber 76 exerts a force on first reaction surface 68 and this force acts against the biasing force of biasing spring 64 to move control ring 40 towards a position wherein the volumetric displacement of pump 20 is reduced.
Similarly, pressurized working fluid in second control chamber 80 exerts a force on second reaction surface 72 and this force acts against the biasing force of biasing spring 64 to move control ring 40 towards a position wherein the volumetric displacement of pump 20 is reduced.
As will be apparent to those of skill on the art, the areas of first reaction surface 68 and second reaction surface 72 can differ, such that the same pressure of working fluid in first control chamber 76 can produce a different force on pump control ring 40 than the pressurized working fluid in second control chamber 80.
Similarly, first and second reaction surfaces 68 and 72 can be located at different radial distances from the point at which control ring 40 pivots, thus applying the forces generated in first and second control chambers 76 and 80 with different mechanical advantages. In the illustrated embodiment, first reaction surface 68 is radially closer to pivot surfaces 48 and 50 than second reaction surface 72 and thus, if reaction surfaces 68 and 72 are the same size and first and second control chambers 76 and 80 are supplied with the same pressure of working fluid, second reaction surface 72 will counter the biasing force of biasing spring 64 to a greater extent than will first reaction surface 68.
As will be apparent to those of skill in the art, if it is desired that each of first and second control chambers 76 and 80 contribute the same amount of movement to control ring 40 for a given pressure, the sizes of first and second reaction surfaces 68 and 72 can be varied from each other to counteract the effects of their different radial distances from the pivot point of control ring 40.
In one embodiment, it is contemplated that one of first control chamber 76 and second control chamber 80 will be supplied with pressurized working fluid, through pump control system 21, from pump 20 while the other of first control chamber 76 and second control chamber 80 will be selectively supplied with pressurized working fluid directly from pump 20. For the purposes of illustration, second control chamber 80 can be selectively supplied with pressurized working fluid. In such a case, pump 20 is operated with the supply of pressurized working fluid to second control chamber 80 removed, pump 20 operates in a substantially conventional manner with a single equilibrium pressure with the force created on control ring 40 by the pressure of the working fluid in first control chamber 76 acting against the biasing force of biasing spring 64.
However, when pressurized working fluid is also supplied to second control chamber 80, via pump control system 21, pump 20 will operate at a second, different, equilibrium operating pressure with the force created on control ring 40 by the pressure of the working fluid in second control chamber 76 adding to the force created by the pressurized working fluid in first control chamber 76 and the sum of these forces act against the biasing force of biasing spring 64.
It is also contemplated that the supply of pressurized working fluid can be selectively supplied to both of first reaction chamber 76 and second reaction chamber 80, as illustrated in broken lines to and from pump control system 21. In such a case, provided that first and second control chambers 76 and 80 produce different forces on control pump ring 40 due to different areas of reaction surfaces 68 and 72 and/or their different radial distances from the pivot point of control ring 40, pump 20 can be operated through pump control system 21 at a selected one of three different equilibrium pressures by selectively providing pressurized working to fluid to: (i) first control chamber 76; (ii) second control chamber 80; and (iii) both of first control chamber 76 and second control chamber 80.
In the embodiment illustrated in
As illustrated, control ring 204 is sealed with resilient seals 212. As mentioned above, the use of such seals is not required but such seals can provide a manufacturing cost advantage in that relatively expensive machining steps, which would otherwise be required to ensure adequate sealing of control ring 204 with respect to control chambers 76 and 80, etc. can be avoided.
In operation, one or both of control chambers 76 and 80 can be selectively supplied, directly or indirectly, with pressurized working fluid from pump 200 to operate pump 200 at any of two, or three, equilibrium operating pressures. The method of selectively supplying pressurized working fluid from pump 200 to control chambers 76 and 80 is not particularly limited and can comprise a mechanical or solenoid operated valve etc. If it is desired to operate at pump 200 at a selectable one of two equilibrium pressures, it is contemplated that one of control chambers 76 or 80 can be always connected, directly or indirectly, to the outlet of pump 200 while the other of control chambers 76 and 80 will selectively be supplied with pressurized working fluid. When the other of control chambers 76 and 80 is selectively supplied with pressurized working fluid, the force created on the respective reaction surface in that control chamber adds to the force created on the reaction surface of the other control chamber to further slide control ring 204 towards biasing spring 64, further reducing the displacement of pump 200.
As will be apparent to those of skill in the art, the sizes and locations of reaction surfaces 60, 68 and 72 and control chambers 76 and 80 can be altered, as required, to meet a particular requirement for pump 200. For example, control chambers 76 and/or 80 can be repositioned to better counter and/or reduce reaction forces exerted on pump control ring 204 during operation of pump 200. Further, additional resilient seals can be employed, as necessary, to provide additional sealing.
The above-described embodiments of the invention are intended to be examples of the present invention and alterations and modifications may be effected thereto, by those of skill in the art, without departing from the scope of the invention which is defined solely by the claims appended hereto.
This application is the national phase under 35 U.S.C. §371 of PCT International Application No. PCT/CA2007/000753, which has an International filing date of May 4, 2007, which designated the United States of America, which PCT application claims the benefit of U.S. Provisional Application No. 60/746,422, filed May 4, 2006. The entire disclosures of each of the above applications are incorporated herein by reference.
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/CA2007/000753 | 5/4/2007 | WO | 00 | 10/31/2008 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2007/128105 | 11/15/2007 | WO | A |
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| Number | Date | Country | |
|---|---|---|---|
| 20090196780 A1 | Aug 2009 | US |
| Number | Date | Country | |
|---|---|---|---|
| 60746422 | May 2006 | US |
