This disclosure relates to the field of motor vehicle transmission pumps and more particularly to sliding-pocket variable-displacement vane pumps.
Many vehicles are used over a wide range of vehicle speeds, including both forward and reverse movement. Some types of engines, however, are capable of operating efficiently only within a narrow range of speeds. Consequently, transmissions capable of efficiently transmitting power at a variety of speed ratios are frequently employed. When the vehicle is at low speed, the transmission is usually operated at a high-speed ratio such that it multiplies the engine torque. At high vehicle speed, operating the transmission at a low-speed ratio permits an engine speed associated with quiet, fuel-efficient cruising.
According to one embodiment, a sliding vane pump includes a fixed housing defining inlet and outlet ports and a sliding housing defining a cylindrical cavity and configured to slide within the fixed housing. The fixed housing and the sliding housing define a gap therebetween. A rotor is configured to rotate within the cylindrical cavity and has a plurality of vanes configured to seal against an inner circumferential wall of the cylindrical cavity to define a plurality of pumping chambers. A seal is located in the gap disposed between the fixed housing and the sliding housing to split the gap into first and second compensation chambers. The first chamber is fluidly connected to a first pumping chamber of the plurality of pumping chambers and the second chamber is connected to a second pumping chamber of the plurality of pumping chambers.
According to another embodiment, a sliding vane pump includes a housing defining a first cavity and a seal groove. A slider is disposed in the first cavity and has an outer circumferential wall and an inner circumferential wall that defines a second cavity. The slider defines first and second grooves each extending from the inner wall to the outer wall. The slider and the housing cooperate to define opposing first and second control chambers. A spring is disposed in the first control chamber and is configured to bias the slider to a full-displacement position. The second control chamber is configured to receive pressurized fluid to act against the spring and urge the slider to a low-displacement position. A rotor is configured to rotate within the second cavity and has a plurality of vanes configured to seal against the inner wall to define a plurality of pumping chambers. A seal is disposed in the seal groove and extends between the housing and the outer wall. A first compensation chamber is defined between the housing, the outer wall and the seal. The first compensation chamber is in fluid communication with a first of the pumping chambers via the first groove. A second compensation chamber is defined between the housing, the outer wall, and the seal. The first and second compensation chambers are on opposite sides of the seal and the second compensation chamber is in fluid with a second of the pumping chambers via the second groove.
According to yet another embodiment, a sliding vane pump includes a housing defining a first cavity and a seal groove. A slider is disposed in the first cavity and has an outer circumferential wall and an inner circumferential wall that defines a second cavity. The slider defines first and second grooves each extending from the inner wall to the outer wall. A rotor is configured to rotate within the first cavity and has a plurality of vanes configured to seal against the inner wall to define a plurality of pumping chambers. A seal is disposed in the seal groove and extends to the outer wall. A first compensation chamber is defined between the housing, the outer wall, and the seal and is in fluid with the first groove. A second compensation chamber is defined between the housing, the outer wall, and the seal and is in fluid with the second groove.
Embodiments of the present disclosure are described herein. It is to be understood, however, that the disclosed embodiments are merely examples and other embodiments can take various and alternative forms. The figures are not necessarily to scale; some features could be exaggerated or minimized to show details of particular components. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a representative basis for teaching one skilled in the art to variously employ the present invention. As those of ordinary skill in the art will understand, various features illustrated and described with reference to any one of the figures can be combined with features illustrated in one or more other figures to produce embodiments that are not explicitly illustrated or described. The combinations of features illustrated provide representative embodiments for typical applications. Various combinations and modifications of the features consistent with the teachings of this disclosure, however, could be desired for particular applications or implementations.
Directional terms used herein are made with reference to the views and orientations shown in the exemplary figures. A central axis is shown in the figures and described below. Terms such as “outer” and “inner” are relative to the central axis. For example, an “outer” surface means that the surfaces faces away from the central axis, or is outboard of another “inner” surface. Terms such as “radial,” “diameter,” “circumference,” etc. also are relative to the central axis. The terms “front,” “rear,” “upper” and “lower” designate directions in the drawings to which reference is made. The terms, connected, attached, etc., refer to directly or indirectly connected, attached, etc., unless otherwise indicated explicitly or by context.
Within the transmission 16, the speed and torque are adjusted by a torque converter 24 and a gearbox 26. The torque converter 24 includes an impeller and turbine that transmit power hydro-dynamically whenever the impeller rotates faster than the turbine. It may also include a stator that multiplies the torque. The torque converter may also include a bypass clutch that, when engaged, transmits power mechanically from the impeller to the turbine without the parasitic losses associated with hydrodynamic power transfer. The gearbox 26 includes gearing and clutches arranged such that engaging various subsets of the clutches establish various power flow paths. The different power flow paths have different speed ratios. The gearbox 26 shifts from one speed ratio to another speed ratio by releasing some clutches and engaging other clutches to establish a different power flow path.
The torque converter 24 and gearbox 26 are controlled by adjusting the pressure of hydraulic fluid supplied to various clutches. A pump 28 is driven by the transmission input which is driven by crankshaft 14. The pump 28 draws fluid from a sump 30 and supplies the fluid, at elevated pressure, to valve body 32. The quantity of fluid supplied is based on the engine speed and on a parameter of the pump geometry called pump displacement. As will be described in detail below, the pump 28 is a sliding-pocket variable-displacement vane pump that includes a compensation chamber(s).
The transmission is controlled by a controller 34. In response to signals from the controller 34, the valve body 32 supplies the fluid to the various clutches in the torque converter 24 and the gearbox 26 at controlled pressures less than the pressure supplied by the pump 28. The valve body also supplies fluid to the hydrodynamic chamber of the torque converter 24 and supplies fluid for lubrication to gearbox 26. Fluid travels from the gearbox 26 and the valve body 32 back to the sump 30 to complete the cycle. The quantity of fluid needed varies depending on the current operating state of the transmission. In response to these changes and in response to changes in engine speed, the controller 34 may also direct valve body 32 to adjust the pump displacement to modify output of the pump 28.
Referring to
A sliding housing 52 (also known as a slider) fits within the cavity 51 defined by the outer housing 50. The housing 50 defines recesses 42 and 44 on opposing sides. The slider 52 has projecting portions 46 and 48 that are received in the recesses 42, 44. The distance between bottoms of the recesses 42, 44 is greater than the distance between the tips of the projecting portions 46 and 48 allowing the slider 52 to slide within the cavity 51. Sliding the slider 52 (left and right in the illustrated orientation) changes the displacement of the pump. This pump 28 is in the full-displacement position when slider 52 all the way right and is in the low-displacement position when slid all the way left.
The recesses 42, 44 and the projecting portions 46, 48 cooperate to define control chambers 78 and 84. A spring 54 is disposed in control chamber 84. The spring 54 biases the sliding housing toward the full-displacement position best shown in
The sliding housing 52 defines a circular interior cavity 53. A rotor 56 rotates within the cavity 53 about the axis 55 that is fixed with respect to the outer housing 50. The rotor 56 is driven by a power source such as the engine 12. The rotor 56 may include an associated shaft 59 that is concentric with the axis. A number of vanes 58 rotate with the rotor 56 such that the tips of each vane follow an inner surface 60 of the circular cavity 53 of sliding housing 52. The vanes 58 are rotationally fixed to the rotor 56 but are radial movable so that the vanes 58 retain in contact with the surface 60 as the eccentricity of the rotor 56 changes due to movement of the slider 52. For example, the vanes 58 may be received in slots defined in the rotor 56. The vanes 58 may be stabilized by a ring 57 that synchronizes the radial sliding of the vanes 58.
The rotor, vanes, and sliding housing collectively define a number of pumping chambers 61, 62, 64, 66, 68, 70, and 72. The volumes of the chambers 61, 62, 64, and 66 increase as the rotor turns clockwise. An inlet port 74 is defined in the outer housing 50 (or a cover of the outer housing), generally underneath the chambers 61, 62, and 64 such that fluid is drawn from the inlet port into the expanding chambers. The volumes of chambers 68, 70, and 72, on the other hand, decrease as the rotor turns clockwise. An outlet port 76 is defined in the outer housing (or a cover of the outer housing) generally underneath the chambers 68, 70, and 72 such that fluid is pushed into the outlet port as the chambers shrink.
The outer circumferential wall 73 of the slider 52 is spaced apart from the inner circumferential wall 40 creating void space 41 on the high-pressure side of the pump 28. A seal 100 is disposed in this void space 41 and splits it to form a first compensation chamber 81 and a second compensation chamber 82. The first compensation chamber 81 generally extends circumferentially from the projecting portion 46 to the seal 100. The second compensation chamber 82 generally extends circumferentially from the projecting portion 48 to the seal 100. As will be discussed in more detail below, the compensation chambers 81, 82 are used to balance forces generated during operation of the pump 28.
Referring to
Pressure differentials within the various chambers may generate unwanted forces, in some operating conditions, that act on the sliding housing 52. These forces may cause the slider 52 to move towards the low-displacement position resulting in reduced pump performance and/or may increase friction between the slider 52 and the fixed housing 50 reducing ease of movement therebetween.
For example, when the pump 28 is rotating quickly, the pressures in chambers 68, 70, and 72 are not equal. Due to entrained air in the fluid, the fluid has non-negligible compressibility. As the chamber moves through the position occupied by chamber 68, the percentage change in volume per degree of rotation is small. Consequently, the pressure in the chamber in that position may be less than the pressure in the outlet port 76. On the other hand, the chamber in the position of chamber 72 has a large percentage decrease in volume per degree of rotation. Therefore, the pressure is higher than the pressure in the outlet port 76. This effect may be particularly strong when the slider 52 is in the full-displacement position and the air content of the fluid is high. The differential pressure between the chambers in these positions results in a net force urging the sliding housing 52 toward the low-displacement position (
In another example, pumping chambers 62, 64, 66, 68, 70, and 72 also exert force on sliding housing 52. In order to push the fluid through downstream flow restrictions, the pressure in the outlet port 76 is higher than the pressure in the inlet port 74. At relatively low speed, the pressure in pumping chambers 62, 64, and 66 is approximately equal to the pressure in inlet port 74 and the pressure in pumping chambers 68, 70, and 72 is approximately equal to the pressure in outlet port 76. These pressures produce a net force in the downward direction of
The sliding vane pump 28 is designed to address the control issues discussed above. The sliding housing 52 defines grooves 92 and 94 extending from the inner circumferential surface 60 to an outer circumferential surface 73. The grooves 92 and 94 connect the pumping chambers, e.g., 66 and 72, in fluid communication with the compensation chambers 81 and 82. The grooves 92 and 94 may be recessed into a face 98 of the slider 52, such as the face opposite the inlet and outlet ports. The groove 92 may have a width that is less than or equal to a thickness of the vanes 58 so that the groove 92 is only in fluid communication with one pumping chamber at a time. The groove 94 may be wider than the groove 92. Additionally, the groove 94 may be oriented radially relative to the center of the inner circumferential surface 60, whereas the groove 92 may not be oriented radially. As shown in the figures, the groove 92 is oriented at an oblique angle relative to the center of the surface 60. The groove 92 may be placed circumferentially upstream (counterclockwise in
The compensation chambers 81 and 82 are separated by the seal 100, which may be seated within a seal groove 102. The seal groove 102 is recessed into the inner circumferential surface 40 of the housing 50. The seal groove 102 may extend in the axial direction of the pump 28. The seal 100 may be a linear seal. The base of the seal is received in groove 102 and the tip of the seal 100 engages with the outer circumferential surface 73 of the sliding housing 52 to separate the compensation chambers 81 and 82.
Referring to
Referring back to
At all rotor speeds, the pressures inside chambers 81 and 82 generate forces that counter act the above-described forces to inhibit unintended movement of the sliding housing 52 downwardly and to the left (when viewed in the orientation of
Having two compensation chambers separated by a seal, as shown, has advantages over a single compensation chamber in at least some applications. For example, adding the two chambers 82 and 81 allow for a relatively large pressure differential to be achieved in these two regions, which may result in larger force in the full-displacement direction thus reducing unintended movement (self-regulation) of the sliding housing 52 toward the low-displacement position. The seal 100 also inhibits oil leak through the compensation chambers 81, 82 resulting in greater pump efficiency. The dual-chamber design may also reduce pump pressure ripples.
While exemplary embodiments are described above, it is not intended that these embodiments describe all possible forms encompassed by the claims. The words used in the specification are words of description rather than limitation, and it is understood that various changes can be made without departing from the spirit and scope of the disclosure. As previously described, the features of various embodiments can be combined to form further embodiments of the invention that may not be explicitly described or illustrated. While various embodiments could have been described as providing advantages or being preferred over other embodiments or prior art implementations with respect to one or more desired characteristics, those of ordinary skill in the art recognize that one or more features or characteristics can be compromised to achieve desired overall system attributes, which depend on the specific application and implementation. These attributes can include, but are not limited to strength, durability, marketability, appearance, packaging, size, serviceability, weight, manufacturability, ease of assembly, etc. As such, embodiments described as less desirable than other embodiments or prior art implementations with respect to one or more characteristics are not outside the scope of the disclosure and can be desirable for particular applications.