The present invention relates to an arrangement of a variable capacity vane pump.
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 eccentricity of the pump and hence alter the volumetric capacity of the pump. If the pump is supplying a system with a substantially constant speed and hydraulic resistance, such as a lubrication system of an automobile vehicle engine, 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 and temperatures. In such environments, to maintain an equilibrium pressure it is known to employ a feedback pressure of the pumping fluid (e.g., lubricating oil) from the engine 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 engine increases, such as when the operating speed of the pump increases, the increased pressure is applied to a solenoid valve, which in turn applies a greater pressure 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 engine, such as when the operating speed of the pump decreases, the decreased pressure applied to the control chamber by the solenoid valve 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 pumping fluid in the control chamber acts, the pressure of the pumping 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 pumping fluid pressure than is required at higher engine operating speeds. 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, pumping fluid.
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 desirable to provide an arrangement of a vane pump with improved pump performance and capability range without adding cost or size.
To make manifest the above noted and other positive desires, a revelation of the present invention is brought forth. The present invention endows a freedom of an arrangement of an automobile variable capacity vane pump that includes a pump housing having an outlet and inlet. A pump control ring is provided having a cavity. The control ring is positioned within the housing to move about a pivot. A vane pump rotor is positioned within the cavity of the pump control ring. A position of the pump control ring determines an offset between a center of the pump control ring cavity and an axis of rotation of the vane pump rotor. Vanes are provided that are driven by the rotor and which engage the interior surface of the pump control ring. The vanes and the engaged surface at least partially defining pumping fluid chambers. A first control chamber is provided. The first control chamber is exposed to a first circumferential side of the pivot between the pump housing and the pump control ring. The first control chamber is positioned on an opposite (outer) side of the pump control ring as the (inner) pumping fluid chambers. The first control chamber is operable to receive pressurized fluid to create a force to move the pump control ring to reduce a volumetric capacity of the pump.
A second control chamber is provided between the pump housing and a second outer surface of the pump control ring. The second outer surface of the pump control ring is positioned on an opposite (outer) side of the pump control ring as the (inner) pumping fluid chambers. The second control chamber is operable to receive pressurized fluid to create a force to move the pump control ring to increase the volumetric capacity of the pump. A major portion if not total portion of the second control chamber is juxtaposed between the housing outlet and the housing inlet. The housing outlet juxtaposes a second circumferential side of the pivot and a major portion of the second control chamber.
A return spring is provided biasing the pump control ring toward a position of maximum volumetric capacity. The return spring acting against the forces created by the pressurized fluid within the first control chamber. The return spring is exposed to the inlet and is in a position sealed from the first and second chambers.
Further areas of applicability of the present invention will become apparent from the detailed description provided hereinafter. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are intended for purposes of illustration only and are not intended to limit the scope of the invention.
The present invention will become more fully understood from the detailed description and the accompanying drawings, wherein:
The following description of the preferred embodiment(s) is merely exemplary in nature and is in no way intended to limit the invention, its application, or uses.
Referring to
A pump control ring 24 is provided having a cavity 28. The control ring 24 is positioned within the housing 10 to move about a pivot 32. The pivot 32 includes a pin 36 fixed to the housing 10, wherein a portion of the pump control ring includes a curved surface 40 engaging a portion 90 of the pin 36. Shown best in
The pump housing 10 has an internally formed fluid line 11 having a port end 13 for fluidly connecting with a main oil gallery (after the fuel filter) of an engine. The line 11 has a port end 15 for connecting to a valve supply and sensing port of the solenoid valve 17 that is mounted in the pump housing 10. The solenoid valve 17 can be a two level or fully variable solenoid valve.
A vane pump rotor 44 is positioned within the cavity of the pump control ring 24. A position of the pump control ring 24 determines an offset between a center of the pump control ring cavity and an axis of rotation of the vane pump rotor 44. Vanes 5 are provided slidably mounted in mushroom shaped radially outward extending stem slots 41. Vanes 5 are driven by the rotor 44 and which engage an inner cylindrical surface 48 of the pump control ring that surrounds the cavity 28. An inner radial tip surface 27 of the vanes 5 make aligning contact with upper and lower vane rings 21 (only one shown). The vanes 5 and the engaged surface 48 at least partially defining pumping fluid chambers 52.
A first control chamber 56 is provided. The first control chamber 56 is exposed to a first circumferential side 60 of the pivot 32 between the pump housing 10 and a first outer surface 64 of the pump control ring. The first outer surface of the pump control ring 64 is positioned on a radially outer side of the pump control ring as the pumping fluid chambers 52. The first control chamber 56 is operable to receive pressurized fluid to create a force to move the pump control ring to reduce a volumetric capacity of the pump 7. The pump housing 10 has internally formed line 23 having a port end 25 for fluidly connecting a control port of the solenoid valve 17 with the first control chamber 56. The pivot 32 acts as a seal at one end (a left end as shown in
A second control chamber 68 is provided between the pump housing 10 and a second outer surface 72 of the pump control ring. The second outer surface 72 of the pump control ring 24 is positioned on a radially outward or opposite side of the pump control ring as the pumping fluid chambers 52. The second control chamber 68 is operable to receive pressurized fluid to create a force to move the pump control ring 24 to increase the volumetric capacity of the pump 7. The second control chamber 68 has a restricted drain 69. The second control chamber 68 receives fluid pressurized in the area of the pump outlet 14 that escapes through the horizontal (as shown in
A major portion if not the entire of the second control chamber 68 is juxtaposed between and the housing outlet 14 and the inlet 20. The housing outlet 14 juxtaposes a second circumferential side 76 of the pivot 32 and a major portion if not the entire of second control chamber 68. A sealing member 87 can be utilized to seal the second control chamber 68 from the outlet 14. In an embodiment of the invention (not shown), a second control chamber extends to and is sealed by the pivot. Thus, the sealing member 87 is not required. The outlet then loops over the control ring and the second control chamber, however a major portion of the second control chamber is juxtaposed from the pivot by this “loop” outlet design.
A return spring 82 is provided biasing the pump control ring 24 toward a position of maximum volumetric capacity. The return spring 82 acts against the forces created by the pressurized fluid within the first control chamber 56. The return spring 82 is exposed to the inlet port 26 (sometimes referred to as suction port) and is in a position sealed from the first and second chambers 56 and 68 by mechanically biased (sometimes referred to as spring biased) seals 88 and 92, respectively. A first radial arm 111 defined by a line from the pivot 32 to a sealing member 88 between the first control chamber 56 and the inlet port 26 is greater in length than a second radial arm 113 defined by a line from the pivot 32 to a sealing member 92 between the second chamber 68 and the inlet port 26 and wherein at least 75% of the length of the spring is between the first 111 and second radial arms 113. A third line 115 defined by a line from sealing member 92 to sealing member 88 bisects the spring 82.
The control ring 24, on the top and bottom has reduced thickness area 93 to facilitate fluid from inlet port 26 entering the pumping chambers 52. The reduced thickness area 93 extends beyond the radial arm 111 to an area 95 that is opposite the first control chamber 56.
Referring to
In operation the pump 7 in
The description of the invention is merely exemplary in nature and, thus, variations that do not depart from the gist of the invention are intended to be within the scope of the invention. Such variations are not to be regarded as a departure from the spirit and scope of the invention.
Number | Name | Date | Kind |
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8684702 | Watanabe | Apr 2014 | B2 |
9903367 | Watanabe | Feb 2018 | B2 |
10161398 | Saga | Dec 2018 | B2 |
11168684 | Saga | Nov 2021 | B2 |
Number | Date | Country | |
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20220235764 A1 | Jul 2022 | US |
Number | Date | Country | |
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63140609 | Jan 2021 | US |