The present invention relates to unified pump which combines an air pump and a liquid pump which are driven by the same shaft.
Vacuum pumps are also commonly used for generating a vacuum, which may be used for a variety of different applications, such as drawing air from a cavity or actuating a device, such as a valve.
Typical vacuum pumps include a rotor mounted to a hub driven by a coupled shaft, which extends away from only one side of the rotor. The rotor includes a slot formed as part of the rotor, and a vane slidably extends through the slot. The rotor and vane are located in a cavity formed as part of a housing such that the rotational axis of the rotor is offset from the center of the housing, and the vane is in sliding contact with the inside surface of the outer wall of the housing. The cavity formed as part of the housing is in fluid communication with an inlet passage and an outlet passage. When the rotor and vane rotate, the vane slides within the slot, creating an enclosed volume in the cavity which expands in size, and an enclosed volume in the cavity which contracts in size. The volume which expands in size creates a vacuum, which is used to perform a variety of functions.
However, the rotor only having the hub extend away from one side of the rotor is vulnerable to “tilting” due to the rotor not being supported on both sides, and “flaring” in which the lobes of the rotor adjacent the vane separate under centrifugal forces as the rotor rotates during operation. Accordingly, there exists a need for a vacuum pump which overcomes these issues.
The present invention is directed to a unified variable displacement pump which includes a vacuum pump and fluid pump combined together into a single unit and driven by the same shaft with an integrated vacuum pump rotor.
In one embodiment, the present invention is a unified variable displacement pump having a housing and a fluid pump and a vacuum pump. A portion of the housing is part of the fluid pump, and a portion of the housing is part of the vacuum pump. A shaft extends through the fluid pump and the vacuum pump, and has a first portion and a second portion. A vacuum pump rotor is formed as part of the shaft such that the first portion extends away from one side of the vacuum pump rotor, and the second portion extends away from the other side of the vacuum pump rotor. The fluid pump includes a vane pump rotor mounted to the second portion of the shaft such that when the shaft rotates, the vacuum pump rotor and the vane pump rotor rotate, causing the fluid pump to pump fluid and the vacuum pump to generate a vacuum.
The present invention combines the vacuum pump and fluid pump into a single component driven by a single shaft. In one embodiment, the unified variable displacement pump is disposed in the crankcase of an engine, where the fluid pump is used to circulate engine oil throughout the engine, and the vacuum pump is used to create a vacuum which may be used for a variety of applications. The vacuum created by the vacuum pump may be used for removing air from a cavity, such as a brake booster reservoir, but it is within the scope of the invention that the vacuum created by the vacuum pump may be used for other applications as well, such as actuating a valve.
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 the Figures generally, a unified variable displacement pump is shown generally at 10. The pump 10 has a casing or housing, shown generally at 12, and more specifically, a vacuum housing 14, and an intermediate housing 16, an inner pump housing 18, and an outer pump housing 20.
Extending through each of the housings 14,16,18,20 is an integrated shaft 22. The shaft 22 has a first portion, generally shown at 24, which extends out of the vacuum housing 14; a sprocket 26 is mounted on the first portion 24, and the sprocket 26 is partially surrounded by a chain 28. The chain 28 is operably connected to and driven by the crankshaft (not shown) of an engine, providing power to the pump 10. The first portion 24 terminates into a first tapered portion 30, and the first tapered portion 30 is connected to a vacuum pump rotor, shown generally at 32. More specifically, the vacuum pump rotor 32 includes a first lobe 31A and a second lobe 31B. The first tapered portion 30 is connected to the lobes 31A,31B. In between the lobes 31A,31B is a slot 34 which extends through the rotor 32, and a vacuum pump vane 36 extends through the slot 34.
Also connected to the lobes 31A,31B of the rotor 32 is a second tapered portion 38, and a second portion, shown generally at 40, of the shaft 22 extends away from the second tapered portion 38. The second portion 40 of the shaft 22 includes a pair of flattened portions 42 which are on opposite sides of the shaft 22 relative to one another, and a reduced diameter portion 44.
The vacuum housing 14 includes a cavity, shown generally at 46, and an aperture 48. When the pump 10 is assembled, the rotor 32 is disposed within the cavity 46 and is adjacent an inner surface 50, and the first tapered portion 30 and the first portion 24 are disposed in the aperture 48. The aperture 48 is of a corresponding shape relative to the shape of the first portion 24 and first tapered portion 30, but provides for a gap or clearance area, generally shown at 52. The gap 52 also accommodates a first bearing 54 disposed on the first portion 24, which supports the shaft 22.
The inner surface 50 of the cavity 46 is substantially perpendicular to a wall portion 60. The wall portion 60 terminates in an outer surface 62 that has a groove 64 which receives a seal 66. When the pump 10 is assembled, pressure is applied to compress the seal 66 a predetermined amount against a first outer surface 68 of the intermediate housing 16. The intermediate housing 16 also includes an aperture 70 which receives the second tapered portion 38, and is of a similar shape relative to the second tapered portion 38. Although the aperture 70 is substantially the same shape as the second tapered portion 38, the aperture 70 is larger relative to the second tapered portion 38 to allow for a gap or clearance area, shown generally at 72.
The second portion 40 of the shaft 22 extends through the inner pump housing 18 and into a recess 74 formed as part of the outer pump housing 20. Also disposed within the recess 74 is a second bearing 76, which surrounds the reduced diameter portion 44 of the shaft 22. The bearings 54,76 allow the shaft 22 to rotate relative to the housing 20.
Mounted on the second portion 40 of the shaft 22 is a vane pump rotor 78, which has an aperture 80 through which the second portion 40 extends such that the vane pump rotor 78 is mounted on the second portion 40 of the shaft 22. The aperture 80 includes a pair of flat surfaces 82 which are of a corresponding shape relative to the flattened portions 42. The vane pump rotor 78 is mounted to the second portion 40 of the shaft 22 such that the flat surfaces 82 are in contact with the flattened portions 42 of the shaft 22, such that the vane pump rotor 78 is driven by the shaft 22 as the shaft 22 rotates, best seen in
The vane pump rotor 78 is disposed within a cavity, shown generally at 84, formed as part of the inner pump housing 18. The vane pump rotor 78 is also positioned in contact with a second outer surface 86 formed as part of the intermediate housing 16, and the inner pump housing 18 is also adjacent the intermediate housing 16 and in contact with the second outer surface 86. Also disposed within the cavity 84 is an eccentric ring 88, and the eccentric ring 88 surrounds the vane pump rotor 78. The eccentric ring 88 has a first notch 90A which partially receives a pivot pin 92, and the pivot pin 92 is also partially disposed in a second notch 90B formed as part of the inner pump housing 18.
The eccentric ring 88 also has an outer flange 94 which has an upper notch 96A for receiving a seal 96B which contacts an upper inner surface 98 of the cavity 84. The outer flange 94 is in contact with a biasing member or spring 100, and the spring 100 is also in contact with a support surface 102. A t- shaped recess 104A is also formed as part of the inner pump housing 18 which receives an insert, more specifically, a t-shaped insert 104B. The t-shaped insert 104B sets the maximum amount of distance the eccentric ring 88 is allowed to pivot. Different inserts 104B of different sizes may be used to change the maximum amount of distance the eccentric ring 88 is allowed to pivot, depending upon the application and the desired amount of maximum displacement.
The vane pump rotor 78 also includes several slots 106, each of which receives a respective one of a plurality of vanes 108. Each vane 108 is supported by a pair of support rings 110, and the support rings 110 are slidably disposed in recessed portions 134 formed as part of the vane pump rotor 78. The vanes 108 are in sliding contact with an inner surface 114 of the eccentric ring 88 for generating a pumping action.
The outer pump housing 20 includes an intake passage, shown generally at 116, and output passage, shown generally at 118. Both passages 116,118 are in fluid communication with the cavity 84. The outer pump housing 20 also includes a pressure relief valve, shown generally at 120, which is in fluid communication with the output passage 118. More specifically, the intake passage 116 and the output passage 118 are in fluid communication with the part of the cavity 84 surrounded by the inner surface 114 of the eccentric ring 88. The pressure relief valve 120 includes a check ball 122 and a spring 124 disposed in a bore 126 formed as part of the outer pump housing 20.
The housings 18,20, vane pump rotor 78, eccentric ring 88, vanes 108, support ring 110, and other components located in the cavity 84 are part of a fluid pump, shown generally at 128, powered by the shaft 22. When the shaft 22 is driven for rotation by the chain 28, the rotor 78 rotates as well, driving the vanes 108 to pump fluid. The areas in between the vanes 108 function as either expansion areas 130 or compression areas 132, depending upon the position of the vanes 108 and rotor 78. The expansion areas 130 are substantially in fluid communication with the intake passage 116, and the compression areas 132 are substantailly in fluid communication with the output passage 118. As the vanes 108 pass over the intake passage 116, the area in between the vanes 108 expands, creating a suction force, which draws fluid into the expansion areas 130. The area in between the vanes 108 then reaches a maximum amount, and then begins to reduce in size as the vanes 108 pass over the output passage 118 (i.e., the compression areas 132). As the area between the vanes 108 gets smaller, the fluid in between the vanes 108 is forced into the output passage 118.
The vanes 108 remain in sliding contact with the inner surface 114 of the eccentric ring 88 because of the support ring 110. It can be seen in
As the eccentric ring 88 pivots about the pivot pin 92, the vanes 108 and support rings 110 move relative to the rotor 78, but the vanes 108 are still allowed to slide in their respective slots 106. This changes the displacement of the fluid pump 128 by changing the maximum and minimum size of the expansion areas 130 and compression areas 132. The displacement is not only controlled by the spring 98, but is also controlled by the amount of fluid pressure in a pressure regulation chamber, or decrease chamber, shown generally at 140.
If the force created by the pressure in the decrease chamber 140 acting on the eccentric ring 88 is greater than the force applied to the eccentric ring 88 by the pressure in the spring 98, the displacement of the pump 128 decreases. If the force created by the pressure in the chamber 140 is less than or equal to the force applied to the eccentric ring 88 by the spring 98, then the pump 128 remains at a constant displacement. If the force created by the pressure in the chamber 140 is less than the force applied to the eccentric ring 88 by the spring 98, then the displacement of the pump 128 increases.
The pump 128 may also have substantially zero displacement and not pump fluid if the eccentric ring 88 is positioned such that the center of the eccentric ring 88 is substantially aligned with the center of the rotor 78, which causes the center of the support rings 110 to be substantially aligned with the center of the rotor 78. When this occurs, the vanes 108 do not move in their respective slots 106 as the rotor 78 rotates, and the expansion areas 130 and compression areas 132 are substantially equal in size to one another, and do not change size as the rotor 78 rotates, and therefore do not pump fluid.
In an alternate embodiment, the pump 128 may also include an increase chamber, shown generally at 142, which acts with the spring 98 to increase the displacement of the pump 128. For example, if the pressure in the increase chamber 142 combined with the force applied to the eccentric ring 88 is greater than the pressure in the decrease chamber 140, the displacement of the pump 128 increases.
As mentioned above, the pump 128 also includes a pressure relief valve 120. Upon certain operating conditions such as a cold start, the if the fluid pressure in the output passage 118 exceeds a predetermined value, the pressure acts on the check ball 122, overcoming the force of the spring 124 applied to the check ball 122, allowing fluid to enter the bore 126 and exit a fluid exhaust port 144 into the crankcase of the engine. This helps to limit the amount of fluid pressure in the output passage 118 to a predetermined maximum value.
The decrease chamber 140 is in fluid communication with a bore (not shown) formed as part of the intermediate housing 16. The bore in the intermediate housing 16 is in fluid communication with an arcuate passage 146 formed as part of the outer surface 62, best seen in
Also formed as part of the vacuum housing 14 is an air inlet passage 158, which is fluid communication with a check valve, shown generally at 160, having a check ball 162 disposed in a bore 164, and a return spring 166. The return spring 166 biases the check ball 162 toward a seat portion 168. The bore 164 is of a larger diameter than the air inlet passage 158, and there is a smaller bore 170 formed as part of the intermediate housing 16, and the smaller bore 170 includes a support surface 172. The return spring 166 is located between the support surface 172 and the check ball 162. The smaller bore 170 is in fluid communication with a transverse bore 174, and the transverse bore 174 is in fluid communication with the cavity 46 of the vacuum housing 14. Also in fluid communication with the cavity 46 of the vacuum housing 14 are two breather bores (not shown) which are in respective fluid communication with a first breather outlet 176 and a second breather outlet 178.
As previously discussed, the vacuum pump vane 36 is disposed in slot 34 formed as part of the vacuum pump rotor 32, and the rotor 32 and vane 36 rotate within the cavity 46 of the vacuum housing 14. Referring to
During operation, the chain 28 is driven by the crankshaft of the engine, which rotates the sprocket 26. The sprocket 26 in turn rotates the shaft 22 and therefore the vacuum pump rotor 32 and the vane pump rotor 78. The vane pump rotor 78, eccentric ring 88, and vanes 108 of the fluid pump 128 are used for pumping fluid, and the displacement of the pump 128 is controlled as described above.
As the vacuum pump rotor 32 rotates, the vane 36 rotates as well. However, it can be seen in FIGS. 3 and 5-6 that the center of the shaft 22 is offset from the center of the cavity 46. This causes the vane 36 to slide within the slot 34 of the vacuum pump rotor 32 as the vacuum pump rotor 32 and the vane 36 rotate. As the rotor 32 and vane 36 rotate, air is drawn into the cavity 46. The vane 36, rotor 32, and wall portion 60 create an air expansion area, shown generally at 190, and an air compression area, shown generally at 192. The air expansion area 190 changes to the air compression area 192, depending upon the position of the rotor 32 and vane 36. The shaft 22, and therefore the rotor 32 and vane 36, rotate clockwise when looking at
The air expansion area 190 increases in size as the rotor 32 and vane 36 rotate, as shown in
The unified variable displacement pump 10 of the present invention provides the advantage of having the vane pump or fluid pump 128 and the vacuum pump 188 unified and driven by the same shaft 22. This improves overall packaging and efficiency, reduces part count, and increases robustness by eliminating tipping.
A small portion of the fluid pumped by the fluid pump 128 is used to provide lubrication for the various parts of the unified variable displacement pump 10. More particularly, there is a first fluid delivery conduit 194 in fluid communication with the aperture 48 formed as part of the vacuum housing 14 and the output passage 118. The first fluid delivery conduit 194 is formed as part of the outer pump housing 20, inner pump housing 18, the intermediate housing 16, and the vacuum housing 14. A portion of the pressurized fluid generated by the fluid pump 128 flows through the first fluid delivery conduit 194 and to the bearing 54. Drainage from the bearing 54 passes through the aperture 48 to lubricate the vacuum pump 188. A small portion of the fluid also flows from the aperture 48 toward the cavity 46 and provides provides lubrication between the vacuum pump rotor 32 and the inner surface 50 of the cavity 50, as well as between the vacuum pump rotor 32 and the first outer surface 68 of the intermediate housing 16. The fluid in the cavity 50 also provides lubrication between the tip portions 180,184 of the vacuum pump vane 36 and the wall portion 60.
Referring to
In another alternate embodiment, the fluid pump 128 may be a gerotor pump, shown generally at 200, instead of a vane pump, as previously described. Referring to
The gerotor pump housing 202 (and therefore the outer gerotor 204 and the inner gerotor 206), is narrower in width compared to the inner pump housing 18. However, the intermediate housing 16 is wider in this embodiment compared to the intermediate housing 16 shown in
The gerotor pump 200 also includes areas between the lobes 212 and receses 214 which are used for pumping fluid. More specifically, there are expansion areas, shown generally at 216, and fluid compression areas, shown generally at 218, which change depending upon the position of the outer gerotor 204 and inner gerotor 206. The areas 216,218 are in fluid communication with the intake passage 116 and the output passage 118. More specifically, the expansion areas 216 are in fluid communication with the intake passage 116, and the compression areas 218 are in fluid communication with the output passage 118. As each expansion area 216 passes over the intake passage 116, a vacuum is created, drawing fluid into the expansion area 216. Once the expansion area 216 has reached a maximum size, the expansion area 216 then becomes a compression area 218 and reduces in size, pressurizing the fluid and forcing the fluid into the output passage 118.
The gerotor pump 200 is a fixed displacement pump, and the amount of fluid pressure generated by the gerotor pump 200 is based on the speed at which the inner gerotor 206 and outer gerotor 204 are rotated.
The description of the invention is merely exemplary in nature and, thus, variations that do not depart from the essence 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.