Fluid devices, such as fluid pumps, typically include a variable displacement assembly (e.g., a rotor assembly, cylinder barrel assembly, gerotor assembly, etc.) that displaces a certain volume of fluid as the variable displacement assembly rotates about a rotational axis. Of these fluid devices, many are of the types that include rotors with fluid pumping elements that reciprocate radially relative to a rotational axis (e.g., vane type, radial piston type, cam-lobe type, etc.). These fluid pumping elements act against a cam surface. As the rotor rotates about the rotational axis, the fluid pumping elements extend and retract in response to the rise and fall of the cam surface. This extension and retraction of the fluid pumping elements results in fluid being pumped through the fluid device.
These types of fluid devices can be fixed displacement devices or variable displacement devices. In the variable displacement devices, the displacement is typically varied by offsetting the rotor relative to the cam surface. Such an offset can increase or decrease the distance traveled by the fluid pumping elements thereby increasing or decreasing the volume of fluid displaced through the fluid device.
An aspect of the present disclosure relates to a variable displacement assembly for a fluid device. The variable displacement assembly includes a rotor and a plurality of reciprocating members in engagement with the rotor. The variable displacement assembly further includes a ring assembly. The ring assembly defines a cam surface that is in engagement with the reciprocating members. The ring assembly has a first ring and an axially adjacent second ring with at least one of the first and second rings being adapted for selective movement relative to the other between a neutral position and a displaced position. The first ring has a first ring portion defining a bore that has an inner surface. The second ring has a second ring portion defining a bore that has an inner surface. A first circumferential portion of the inner surface of the first ring portion and a second circumferential portion of the inner surface of the second ring portion define the cam surface in the displaced position.
Another aspect of the present disclosure relates to a fluid device. The fluid device includes a housing defining a fluid inlet and a fluid outlet. A displacement assembly is in fluid communication with the fluid inlet and the fluid outlet. The displacement assembly includes a rotor, a plurality of reciprocating members, and a ring assembly. The rotor has a rotation axis about which the rotor selectively rotates and defines a plurality of bores. The plurality of reciprocating members is in engagement with the plurality of bores of the rotor. The ring assembly defines a cam surface in engagement with the reciprocating members. The ring assembly includes a first ring and an axially adjacent second ring. At least one of the first and second rings is adapted for selective movement relative to the other between a neutral position and a displaced position. The first ring has a first ring portion and defines a central axis. The second ring has a second ring portion and defines a central axis. At least one of the central axes of the first and second ring portions is offset from the rotational axis of the rotor in the displaced position. In one embodiment, the displacement assembly is variable.
Another aspect of the present disclosure relates to a variable displacement assembly for a rotary fluid device. The variable displacement assembly includes a rotor, a plurality of reciprocating members, and a ring assembly. The rotor has a rotation axis about which the rotor selectively rotates and defines a plurality of bores. The plurality of reciprocating members is in engagement with the plurality of bores of the rotor. The ring assembly defines a cam surface in engagement with the reciprocating members. The ring assembly includes a first ring and an axially adjacent second ring. At least one of the first and second rings is adapted for selective movement relative to the other between a neutral position and a displaced position. The first ring has a first ring portion having at least one displacement ring. The at least one displacement ring defines a central axis. The second ring has a second ring portion having at least two displacement rings. The at least two displacement rings define a central axis. At least one of the central axes of the first and second ring portions is offset from the rotational axis of the rotor in the displaced position.
A variety of additional aspects will be set forth in the description that follows. These aspects can relate to individual features and to combinations of features. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the broad concepts upon which the embodiments disclosed herein are based.
Reference will now be made in detail to the exemplary aspects of the present disclosure that are illustrated in the accompanying drawings. Wherever possible, the same reference numbers will be used throughout the drawings to refer to the same or like structure.
Referring now to
In addition, the fluid device 10 will be described as a double pump device. The double pump device includes two sets of fluid pumping components. The two sets of fluid pumping components are potentially advantageous as it allows the fluid device 10 to serve two separate fluid circuits or to supply a single fluid circuit with a greater volume of fluid. While the fluid device 10 will be described as a double pump device, it will be understood that the scope of the present disclosure is not limited to the fluid device 10 being a double pump design.
Referring now to
In the depicted embodiment of
Referring now to
In the subject embodiment, the rotor 28 includes an internal spline 32 that is adapted for engagement with a main drive 33. When the fluid device 10 is used as a pump, the rotor assembly 20 rotates about the rotation axis 29 in response to rotation of the main drive 33. As the rotor assembly 20 rotates, fluid is transferred or pumped from one location (e.g., a reservoir, etc.) to another location (e.g., an actuator, etc.).
The rotor 28 includes a body 34 having a first face 36, which is generally perpendicular to the rotation axis 29, an oppositely disposed second face 38, which is generally parallel to the first face 36, and an outer surface 40 disposed between the first and second faces 36, 38. In the subject embodiment, the rotor 28 is cylindrical in shape. Therefore, in the subject embodiment, the outer surface 40 is an outer circumferential surface.
The outer surface 40 defines a plurality of bores 42 disposed about the rotor 28. The bores 42 radially extend from the outer surface 40 toward the rotation axis 29 of the rotor 28. In the subject embodiment, the outer surface 40 defines a first plurality of bores 42a and a second plurality of bores 42b. As best shown in
In the subject embodiment, the first and second plurality of bores 42a, 42b are substantially similar. In addition, the first and second plurality of radially reciprocating members 44a, 44b are substantially similar. Therefore, for ease of description purposes, the first and second plurality of bores 42a, 42b will be referred to as bores 42 while the first and second plurality of radially reciprocating members 44a, 44b will be referred to as reciprocating members 44.
In the subject embodiment, the reciprocating members 44 are radial pistons 46 suitable for use in a radial piston type fluid device. The radial pistons 46 include piston members 48 and piston shoes 50. In one embodiment, the piston members 48 are adapted for stationary engagement in the bores 42 while the piston shoes 50 are adapted to reciprocate relative to the piston members 48. The piston members 48 include first axial end portions 52 and second axial end portions 54. The first axial end portions 52 are adapted for insertion in the bores 42. The second axial end portions 54 are adapted for insertion in a cavity 53 of the piston shoes 50.
The piston shoes 50 of the reciprocating members 44 are adapted for engagement with a cam surface 55 of the ring assembly 22. As the rotor assembly 20 rotates about the rotation axis 29, the piston shoes 50 of the reciprocating members 44 reciprocate relative to the piston members 48 in response to engagement with the cam surface 55 of the ring assembly 22. As the piston shoes 50 reciprocate relative to the piston members 48, volume chambers 56, which are cooperatively defined by the cavities 53 of the piston shoes 50 and the second axial end portions 54 of the piston members 48, expand and contract.
The variable displacement assembly 18 includes at least one inlet region at which fluid is drawn into the variable displacement assembly 18 and at least one outlet region at which fluid is expelled from the variable displacement assembly 18. In the inlet region of the variable displacement assembly 18, a distance between the cam surface 55 of the ring assembly 22 and the rotor 28 increases as the rotor assembly 20 rotates. As the distance between the cam surface 55 and the rotor 28 increases, the piston shoes 50 extend outwardly from the second axial end portions 54 of the piston members 48 causing the corresponding volume chambers 56 to expand and draw fluid in from the fluid inlet 14.
In the outlet region of the variable displacement assembly 18, the distance between the cam surface 55 and the rotor 28 decreases as the rotor assembly 20 rotates. As the distance between the cam surface 55 and the rotor 28 decreases, the piston shoes 50 retract on the second axial end portions 54 of the piston members 44 causing the corresponding volume chambers 56 to contract and expel fluid out the fluid outlet 16. In the subject embodiment, the variable displacement assembly 18 includes two inlet regions and two outlet regions.
In one embodiment, one of the first and second faces 36, 38 of the rotor 28 includes a plurality of fluid passages 57. The fluid passages 57 of the rotor 28 are in fluid communication with the volume chambers 56 in the rotor assembly 20. In the subject embodiment, the first and second faces 36, 38 define a first plurality of fluid passages 57a that are in fluid communication with the first plurality of bores 42a and a second plurality of fluid passages 57b that are in fluid communication with the second plurality of bores 42b.
In one embodiment, the rotor 28 is in commutating fluid communication with a pintle 58. In the subject embodiment, the rotor 28 is in commutating fluid communication with a first pintle 58a and a second pintle 58b. The first and second pintles 58a, 58b are non-rotatably disposed in the housing 12 and are in fluid communication with the fluid inlet 14 and the fluid outlet 16 of the fluid device 10. In the subject embodiment, each of the first and second pintles 58a, 58b includes a first axial end 60, an opposite second axial end 62 and an outer circumferential surface 63.
The outer circumferential surface 63 defines a first groove 64 that is in fluid communication with the fluid inlet 14 and a second groove 66 that is in fluid communication with the fluid outlet 16. The first axial end 60 of the pintle 58 defines a plurality of inlet fluid passageways 68 in fluid communication with the first groove 64 and a plurality of outlet fluid passageways in fluid communication with the second groove 66.
The first axial end 60 of the first pintle 58a is adapted for sealing engagement with the first face 36 of the rotor 28 while the first axial end 60 of the second pintle 58b is adapted for sealing engagement with the second face 38 of the rotor 28. As the rotor 28 rotates about the rotation axis 29, the inlet fluid passageways 68 and outlet fluid passageways of the first and second pintles 58a, 58b are in commutating fluid communication with the first and second plurality of fluid passages 57a, 57b, respectively, of the rotor assembly 20 such that fluid from the inlet fluid passageways 68 of the first and second pintles 58a, 58b are drawn into the expanding volume chambers 56 while fluid from the contracting volume chambers 56 is expelled through the outlet fluid passageways.
Referring now to
The ring portion 72 of each of the rings 70 is generally cylindrical and defines a central axis 76. The ring portion 72 includes a first surface 78 (best shown in
The ring portion 72 defines a bore 84 that extends through the first and second surfaces 78, 80. In the subject embodiment, the bore 84 is generally cylindrical and is axisymmetric about the central axis 76 of the ring portion 72. The bore 84 includes an inner surface 86 having a radius. In the subject embodiment, at least a portion of the rotor assembly 20 is disposed within the bore 84 such that at least a portion of the reciprocating members 44 act against at least a portion of the inner surface 86. In one embodiment, at least a portion of the reciprocating members 44 act directly against at least a portion of the inner surface 86 of the bore 84.
The pivot portion 74 of each of the plurality of rings 70 extends outwardly from the outer surface 82 of the ring portion 72. The pivot portion 74 is adapted to provide pivoting or rocking movement of the ring 70. In the subject embodiment, each of the pivot portions 74 includes a pivot axis 90 about which the ring 70 pivots.
In the subject embodiment, the pivot portion 74 includes a convex surface 92. The convex surface 92 is adapted for engagement in a pocket 94 of a support structure such as the outer ring 19 or the housing 12. The pocket 94 prevents the pivot portion 74 from moving in a radial outward direction from the longitudinal central axis 30 of the fluid device 10 while allowing the pivot portion 74 to pivot within the pocket 94.
Referring now to
In the subject embodiment, the inner surface 102a of the inner band 98 is adapted for direct engagement with the reciprocating members 44. The frictional forces between the inner surface 102a of the inner band 98 and the reciprocating members 44 cause the inner band 98 to rotate about the rotation axis 29. In the subject embodiment, the inner band 98 rotates about the rotation axis 29 of the rotor assembly 20 at substantially the same speed as the rotor assembly 20. While the inner band 98 rotates about the rotation axis 29, the outer band 100 remains rotationally stationary in the ring 70.
The inner band 98 is made from a first material having a first thickness while the outer band 100 is made from a second material having a second thickness. In the subject embodiment, the first material is different than the second material. The first and second materials are selected so as to provide a suitable bearing surface at the interface between the inner and outer bands 98, 100. In the subject embodiment, and by way of example only, the first material is a nickel bronze material while the second material is a bearing quality tool steel (e.g., 52100, etc.).
Referring now to
Referring now to
In
As the inner surface 86 of the ring portion 72 of each of the first and second rings 70a, 70b is generally circular in shape, the reciprocating members 44 (shown schematically as arrows in
As best shown in
At least one of the first and second rings 70a, 70b is selectively moveable relative to the other between the neutral position (shown in
Referring now to
Referring now to
In the displaced position, the first circumferential portion 110 of the first ring 70a is less than half of the total circumference of the inner surface 86 of the first ring 70a or less than 50% of the total circumference of the inner surface 86 of the first ring 70a. The second circumferential portion 112 of the second ring 70b is also less than half of the total circumference of the inner surface 86 of the second ring 70b or less than 50% of the total circumference of the inner surface 86 of the second ring 70b. As the percentage of the first and second circumferential portions 110, 112 of the cam surface 55 relative to the total circumference of the inner surfaces 86 of the first and second rings 70a, 70b, respectively, decrease, the displacement of the variable displacement assembly 18 increases.
Referring now to
The displacement piston 120 extends and retracts along a longitudinal axis 126 that extends radially toward the rotating axis 29 of the rotor assembly 20. In the depicted embodiment, the displacement piston 120 is biased by a spring 128 toward the extended position. In this embodiment, the variable displacement assembly 18 is biased to the maximum displaced position.
Fluid is selectively supplied to the second end 124 of the displacement piston 120 by an electro-hydraulic servo valve 130 (EHSV). In the subject embodiment, the second end 124 of the displacement piston 120 is generally cylindrical in shape. The diameter of the second end 124 of the displacement piston 120 is sized to balance forces 132 (shown schematically as arrows in
The pressure of the fluid supplied by the EHSV 130 acts on an end surface 134 of the displacement piston 120 such that the pressure of the fluid acting on the end surface 134 balances the forces 132 acting against the inner surface 86 of the ring 70 by the reciprocating members 44 disposed in the rotor assembly 20. With the forces 132 of the reciprocating members 44 balanced by the pressure from the fluid supplied by the EHSV 130, the full biasing force of the spring 128 is transferred to the ring 70 to offset the ring 70 from the neutral position and thereby increase the displacement of the variable displacement assembly 18.
In the subject embodiment, a variable orifice 136 is in fluid communication with the second end 124 of the displacement piston 120. The variable orifice 136 is selectively operable in a range of positions between fully open and fully closed. With the variable orifice 136 in a position that is at least partially open, the variable orifice 136 relieves a portion of the pressure of the fluid supplied by the EHSV 130 that acts against the end surface 134 of the displacement piston 120. With the pressure of the fluid at least partially relieved, a portion of the biasing force of the spring 128 is used to balance the forces 132 acting against the inner surface 86 of the ring 70. As a result, less spring force is available to displace the variable displacement assembly 18. Therefore, the displacement of the variable displacement assembly 18 is less with the variable orifice 136 in an at least partially open position than in a fully closed position.
Referring now to
With fluid supplied by the EHSV 130 acting on the end surface 134 of at least one of the displacement pistons 120, at least one of the rings 70 pivots about the pivot axis 90 of the pivot portion 74 to the displaced position. As best shown in
Referring now to
Referring now to
In the subject embodiment, the ring assembly 150 includes a first ring 152 and a second ring 154. The first ring 152 includes a first ring portion 156 and a first pivot portion 158 while the second ring 154 includes a second ring portion 160 and a second pivot portion 162.
The first ring 152 is similar to the first ring 70a described above. However, in the subject embodiment, the first ring portion 156 of the first ring 152 includes at least one displacement ring 164. In the subject embodiment, the first ring portion 156 of the first ring 152 includes multiple displacement rings 164. In the subject embodiment, each of the multiple displacement rings 164 of the first ring 152 is coaxial with an adjacent displacement ring 164 of the first ring 152 but axially offset from the adjacent displacement ring 164. This axial offset provides a lateral space 166 between the adjacent displacement rings 164 of the first ring 152.
In the subject embodiment, the number of displacement rings 164 in the first ring portion 156 of the first ring 152 is equal to a number (N) of sets of pumping components in the fluid device 10. In the depicted embodiment of
The second ring 154 is similar to the second ring 70b described above. However, in the subject embodiment, the second ring portion 160 of the second ring 154 includes at least two displacement rings 168. In the subject embodiment, each of the displacement rings 168 of the second ring 154 is coaxial with an adjacent displacement ring 168 of the second ring 154 but axially offset from the adjacent displacement ring 168. This axial offset provides a lateral space 170 between the adjacent displacement rings 168 of the second ring 154.
In the subject embodiment, the number of displacement rings 168 in the second ring portion 160 of the second ring 154 is equal to number (N) of displacement rings 164 of the first ring 152 plus one. As described above, in the depicted embodiment of
In the subject embodiment, a width W1a of the first displacement ring 164a of the first ring 152 is about equal to a width W1b of the second displacement ring 164b of the first ring 152. In the subject embodiment, a width W2a of the first displacement ring 168a of the second ring 154 is about equal to a width W2c of the third displacement ring 168c of the second ring 154. Each of the widths W2a, W2c of the first and third displacement rings 168a, 168c is about half of the widths W1a, W1b of the first and second displacement rings 164a, 164b of the first ring 152. The width W2b of the second displacement ring 168b is about equal to the width W1a of the first displacement ring 164a of the first ring 152.
Referring now to
Referring now to
Referring now to
In the subject embodiment, the first axial end portion 202 of the reciprocating member 200 is adapted to reciprocate in the bore 42. In the subject embodiment, the bore 42 of the rotor 28 and the first axial end portion 202 of the reciprocating member 200 define the volume chamber 56 that expands and contracts as the reciprocating member 200 extends and retracts in the bore 42.
The first axial end portion 202 includes a frusto-spherical portion 206. The frusto-spherical portion 206 includes a maximum diameter that is sized slightly smaller than the diameter of the bore 42 to allow the reciprocating member 200 to reciprocate within the bore 42 while reducing fluid leakage from the volume chambers 56 between the bore 42 and the frusto-spherical portion 206.
The first axial end portion 202 further includes an end surface 207. In the subject embodiment, the end surface 207 is immediately adjacent to the frusto-spherical surface 206. In the depicted embodiment, the end surface 207 is flat surface.
The first axial end portion 202 further includes a neck portion 208. In the subject embodiment, the neck portion 208 joins the frusto-spherical portion 206 of the first axial end portion 202 to the second axial end portion 204 of the reciprocating member 200. The neck portion 208 is sized such that the outer diameter of the neck portion 208 is smaller than the diameter of the frusto-spherical portion 206.
In the subject embodiment, the second axial end portion 204 includes an outer surface 210. The outer surface 210 of the second axial end portion 204 is adapted for engagement with the cam surface 55 of the variable displacement assembly 18. In the depicted embodiment, the outer surface 210 of the second axial end portion 204 defines a length L and a width W. The outer surface 210 defines a radius R along the length L. The radius R is less than or equal to the radius of the inner surface 86 of the bore 84.
Referring now to
In the subject embodiment, the first axial end portion 302 of the reciprocating member 300 is adapted to reciprocate in the bore 42. The first axial end portion 302 includes a frusto-spherical portion 306. The frusto-spherical portion 306 includes a maximum diameter that is sized slightly smaller than the diameter of the bore 42 to allow the reciprocating member 300 to reciprocate within the bore 42 while reducing fluid leakage from the volume chambers 56 between the bore 42 and the frusto-spherical portion 306.
The second axial end portion 304 includes a first lateral edge segment 308, an oppositely disposed second lateral edge segment 310 and a center segment 312, with the center segment 312 disposed between the first and second lateral edge segments 308, 310. In the subject embodiment, the first and second lateral edge segments 308, 310 are adapted for engagement with the first and second displacement rings 168a, 168b of the second ring 154 while the center segment 312 is adapted for engagement with the first displacement ring 164a of the first ring 152.
The first and second lateral edge segments 308, 310 of the second axial end portion 304 are adapted movement relative to the central segment 312. In the subject embodiment, the first and second lateral edge segments 308, 310 pivot about a pin 314 that pivotally engages the first and second lateral edge segments 308, 310 to the center segment 312. In the subject embodiment, the first and second lateral edge segments 308, 310 pivot independently about the pin 314.
In the subject embodiment, each of the first and second lateral edge segments 308, 310 and the center segment 312 include an outer surface 316. The outer surface 316 of each of the first and second lateral edge segments 308, 310 and the center segment 312 of the second axial end portion 304 is adapted for engagement with at least a portion of the cam surface 55 of the variable displacement assembly 18. In the depicted embodiment, the outer surface 316 defines a radius R2.
In the subject embodiment, the reciprocating member 300 includes a neck portion that engages the center segment 312 of the second axial end portion 304 to the first axial end portion 302. In the subject embodiment, the neck portion joins the frusto-spherical portion 306 of the first axial end portion 302 to the center segment 312 of the second axial end portion 304 of the reciprocating member 300. In the subject embodiment, the neck portion is rigidly engaged with the central segment 312 of the second axial end portion 304. In the subject embodiment, the neck portion is integral with center segment 312 of the second axial end portion 304.
This multi-segment reciprocating member 300 is potentially advantageous as it allows for a smooth transition in a transition area that is located at the intersection of the first circumferential portion 110 to the second circumferential portion 112 of the cam surface 55 when the ring assembly 22 is in the displaced position. In operation, the first and second lateral edge segments 308, 310 pivot about the pin 314 so as to gradually disengage from the first and second displacement rings 168a, 168b of the second ring 154 as the center segment 312 engages the first displacement ring 164a of the first ring 152 when the ring assembly 22 is in the displaced position. This pivoting of the first and second lateral edge segments 308, 310 affects the loading on the second axial end 304 of the reciprocating members 300 by preventing an abrupt change in contact area between the reciprocating members 300 and the cam surface 55 in the transition area.
Various modifications and alterations of this disclosure will become apparent to those skilled in the art without departing from the scope and spirit of this disclosure, and it should be understood that the scope of this disclosure is not to be unduly limited to the illustrative embodiments set forth herein.
This application is a National Stage Application of PCT/US2009/067885, filed Dec. 14, 2009, which claims benefit of U.S. Provisional Patent Application Ser. No. 61/145,879 entitled “Variable Displacement Fluid Device” and filed on Jan. 20, 2009 and which applications are incorporated herein by reference. To the extent appropriate, a claim of priority is made to each of the above disclosed applications.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/US2009/067885 | 12/14/2009 | WO | 00 | 10/3/2011 |
Publishing Document | Publishing Date | Country | Kind |
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WO2010/085301 | 7/29/2010 | WO | A |
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196 52 157 | Apr 1998 | DE |
10 2004 049 864 | Apr 2006 | DE |
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Number | Date | Country | |
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20120042774 A1 | Feb 2012 | US |
Number | Date | Country | |
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61145879 | Jan 2009 | US |