The disclosure generally relates to positive displacement fluid pumps and, more specifically, to electronic positive displacement pumps for pumping fluids such as oil or fuel.
Electro-hydraulic pumps are electromechanical apparatuses in which mechanical energy generated by a motor is transferred to a hydraulic pump section that moves a fluid to provide fluid flow and fluid pressure in a hydraulic circuit. Examples of these pumps used in vehicles include gear pumps such as electronic fuel pumps (EFPs) that feed fuel from the fuel delivery module (FDM) in the fuel tank to a combustion engine of the vehicle. Other examples include electronic oil pumps that move hydraulic fluid to cool and lubricate the internal mechanisms of, for example, an integrated drive module (IDM), such as the drive motor and gear box of the IDM. These electronic pumps may be directly commutated (“brush”) pumps that are driven by a constant voltage signal or electronically commutated (“brushless”) pumps that are driven by dedicated pump controllers. Common electronically commutated pumps include a housing assembly that houses the motor and a circuit board that operates the motor. A pumping section that is driven by the motor is also located in the housing. The pumping section may include, for example, an internal plate, a gerotor assembly that is disposed in the internal plate, and an external plate that closes the housing and includes inlet and outlet ports.
The use of electronically commutated pumps in the field of automotive vehicles has increased with the demand for greater vehicle fuel economy as well as greater drive range for electric vehicles (EVs). This demand requires that the pumps and systems that use them are more robust and efficient, while also offering these improvements at a lower cost. For example, increasing the service life of these pumps requires efficient and effective thermal management so that heat generated by the motor coils and friction/wear between sliding surfaces do not cause premature failure of the pump components. There are various configurations for cooling and lubricating the internal pump components. In cases in which the pump is submerged in a fluid reservoir, passages on the motor section of the pump connect the fluid reservoir to the internal motor chamber and allow fluid from the fluid reservoir to be drawn into and circulate through the motor chamber due to pressure gradients generated in the pump section. Cooling and lubricating of the pump become more difficult if the pump is not submerged in fluid, whereby fluid from the pumping section must be used to perform these functions without adversely affecting pump flow and pressure, as well as without significantly increasing the cost of the pump components. Additionally, fluid may not be completely filled in the motor section of the pump due to trapped air in the motor section.
An improved positive displacement fluid pump is provided. The positive displacement fluid pump includes a housing defining an internal cavity. A motor is housed within the internal cavity of the housing. The motor has a drive shaft that rotates about an axis. The fluid pump further includes an internal plate adjacent the motor. The internal plate includes a central bore through which the drive shaft extends. The fluid pump further includes an external plate including an inlet in fluid communication with a suction port and an outlet in fluid communication with a delivery port. A pumping ring is sandwiched between the internal and external plates. A pumping arrangement is rotatably coupled to the drive shaft such that rotation of the pumping arrangement by the drive shaft causes fluid to be pumped from the suction port to the delivery port. The pumping arrangement is located within the pumping ring and axially between the internal plate and the external plate.
In specific embodiments, the internal plate includes an inwardly-facing face surface, an opposite outwardly-facing face surface, and a complementary delivery port formed in the outwardly-facing face surface and in fluid communication with the delivery port of the external plate.
In particular embodiments, the internal plate further includes a fill passage connected to the complementary delivery port, the fill passage extending to the inwardly-facing face surface of the internal plate and being in fluid communication with the internal cavity of the housing. Fluid pumped by the pumping arrangement is delivered to the internal cavity of the housing through the fill passage.
In certain embodiments, the fill passage is cylindrical.
In particular embodiments, the internal plate includes a hub protruding from the inwardly-facing face surface of the internal plate. The central bore is formed at least in part in the hub, and the hub includes at least one lubrication passage connecting the internal cavity of the housing to the central bore.
In certain embodiments, the at least one lubrication passage is cylindrical.
In certain embodiments, the fluid pump includes two of the lubrication passages.
In certain embodiments, the two lubrication passages are offset approximately 180 degrees from each other in a radial direction around the hub.
In specific embodiments, the fluid pump includes a purge pathway from the internal cavity to the suction port, the purge pathway extending through the internal plate and the pumping ring.
In particular embodiments, the purge pathway further extends from the pumping ring into the external plate.
In certain embodiments, the internal plate includes an inwardly-facing face surface and an opposite, outwardly-facing face surface adjacent the pumping ring. The external plate includes an inwardly-facing face surface adjacent the pumping ring. A groove is formed in the inwardly-facing face surface of the external plate, and the groove is connected to the suction port. The pumping ring includes an inwardly-facing face surface adjacent the outwardly-facing face surface of the internal plate, and an opposite, outwardly-facing face surface adjacent the inwardly-facing face surface of the external plate. The outwardly-facing face surface of the pumping ring includes a channel formed therein. One end of the channel is connected to the groove in the external plate and another end of the channel is connected to a passage that extends through the pumping ring from the outwardly-facing face surface of the pumping ring to the inwardly-facing face surface of the pumping ring. The internal plate includes a purge passage extending from the outwardly-facing face surface of the internal plate to the inwardly-facing face surface of the internal plate. The purge passage in the internal plate is connected to the passage in the pumping ring. The purge pathway is defined by the purge passage in the internal plate, the passage in the pumping ring, the channel in the pumping ring, and the groove in the external plate.
In certain embodiments, the purge passage protrudes from the internal plate into the internal cavity of the housing.
In certain embodiments, the purge passage is in fluid communication with the internal cavity of the housing.
In specific embodiments, the pumping arrangement and the pumping ring are made of materials having a similar coefficient of thermal expansion (CTE).
In specific embodiments, the pumping arrangement includes a rotating element that is an inner gear rotor mounted on the drive shaft, and the pumping arrangement further includes an outer gear rotor engaged and driven by the inner gear rotor. The inner gear rotor and outer gear rotor together define a plurality of variable volume pumping chambers in fluid communication with the suction port and the delivery port.
In particular embodiments, the pumping ring is an eccentric ring including a circular gear rotor bore that is offset from the axis of the drive shaft.
In specific embodiments, the motor is an electric motor.
In specific embodiments, the inlet is arranged in an axial direction aligned with the axis of the drive shaft, and the outlet is arranged in one of: (i) the axial direction; or (ii) a radial direction extending radially with respect to the axis of the drive shaft.
In specific embodiments, (i) the inlet and outlet are isolated from the internal cavity; (ii) the inlet is isolated from the internal cavity and the outlet is open to the internal cavity; or (iii) the inlet is open to the internal cavity and the outlet is isolated from the internal cavity.
In specific embodiments, one of the suction port and the delivery port is in fluid communication with the internal cavity such that fluid is either delivered from the suction port or the delivery port to the internal cavity.
A method of cooling and lubricating the positive displacement pump is also provided. The method includes forming a complementary delivery port in an outwardly-facing face surface of the internal plate. The complementary delivery port is in fluid communication with the delivery port of the external plate. The method further includes forming a fill passage in the internal plate. The fill passage is connected to the complementary delivery port, the fill passage extends to an inwardly-facing face surface of the internal plate, and the fill passage is in fluid communication with the internal cavity of the housing. Fluid pumped by the pumping arrangement is delivered to the internal cavity of the housing through the fill passage.
In specific embodiments, the method further includes forming at least one lubrication passage in a hub of the internal plate. The hub is a smaller diameter portion that protrudes from the inwardly-facing face surface of the internal plate, and the central bore is formed at least in part in the hub. The at least one lubrication passage connects the internal cavity of the housing to the central bore. Fluid is delivered from the internal cavity of the housing to the central bore through the at least one lubrication passage.
In specific embodiments, the method further includes forming a groove in the inwardly-facing face surface of the external plate. The method also includes forming a channel in an outwardly-facing face surface of the pumping ring. One end of the channel is connected to the groove in the external plate and another end of the channel is connected to a passage that extends through the pumping ring from the outwardly-facing face surface of the pumping ring to an inwardly-facing face surface of the pumping ring. The method also includes forming a purge passage that extends from an outwardly-facing face surface of the internal plate to an inwardly-facing face surface of the internal plate. The purge passage in the internal plate is connected to the passage in the pumping ring. Air is bled from the internal cavity of the housing serially through the purge passage in the internal plate, the passage in the pumping ring, the channel in the pumping ring, and the groove in the external plate to the suction port.
In particular embodiments, fluid delivered to the internal cavity of the housing through the fill passage is recirculated from the internal cavity to the suction port serially through the purge passage in the internal plate, the passage in the pumping ring, the channel in the pumping ring, and the groove in the external plate.
Various advantages and aspects of this disclosure may be understood in view of the following detailed description when considered in connection with the accompanying drawings, wherein:
A positive displacement fluid pump is provided. Referring to
With reference to
Motor section 16 includes an electric motor 24 which is disposed within the motor cavity 22 of the housing 20. The electric motor 24 may be, for example, an electronically commutated (EC) brushless motor. Electric motor 24 includes a shaft 26 extending therefrom into the pumping section 18. A permanent magnet rotor 28 is attached at an opposite end of the shaft 26, and the rotor 28 is surrounded by a stator 30. Shaft 26 rotates about a first axis 32 when an electric current is applied to the stator 30 of the electric motor 24. The electric motor 24 is connected to a supply of power and an external controller by wires 34 connected to a wire harness 36. Electric motors and their operation are well known, consequently, electric motor 24 will not be discussed further herein.
With continued reference to
Since the eccentric pumping ring 42 is separate from both the internal plate 38 and the external plate 40, it is possible to construct the pumping ring 42 from a material that has a similar coefficient of thermal expansion (CTE) as the pumping arrangement 44 (i.e., inner and outer gear rotors 46, 48). This provides for reduced axial clearance variation between the pumping ring 42 and the pumping arrangement 44 within the operating temperature range of the oil pump 10, which is typically in the range of −40° C. and 150° C. In certain embodiments, the pumping ring 42 and the pumping arrangement 44 may be constructed of the same or similar material. In certain embodiments, the pumping ring 42 and the pumping arrangement 44 may be constructed of the same or similar material. For example, the gears 46, 48 of the pumping arrangement 44 may be made of powdered metal or plastic (e.g., phenolic polymer or polyetheretherketone (PEEK)), while the eccentric pumping ring 42 may be made of aluminum or a phenolic polymer. In contrast, conventionally the pumping ring is integrated into one of the internal or external plates, which are made of cast aluminum, and the gear rotors are made of a material such as nickel steel powdered metal, which has half the CTE of aluminum.
The external plate 40 is disposed at the outer end of the oil pump 10 and includes outwardly-facing face surface 60 on the outside of the pump 10 and an inwardly-facing face surface 61 adjacent the pumping ring 42. A low-pressure inlet 62 and a high-pressure outlet 63 are formed in the outwardly-facing face surface 60 of the external plate 40. The inlet 62 and outlet 63 may include a conduit that extends outwardly beyond the outwardly-facing face surface 60 of the external plate 40. The inlet 62 is connected to and in fluid communication with (fluidly connected to) a suction port 64 formed in the inwardly-facing face surface 61 of the external plate 40. The outlet 63 is connected to and in fluid communication with a delivery port 65 formed in the inwardly-facing face surface 61 of the external plate 40. The inlet 62 and outlet 63 both face and extend in the axial direction (direction of drive shaft axis 32). However, it should be understood that the outlet may instead face in the radial direction relative to the drive shaft axis 32. The inlet 62 of the external plate 40 is aligned with a portion of gear rotor bore 52 within which the geometry between external teeth 54 and internal tooth recesses 56 create pumping chambers 58 of relatively large size while the outlet 63 of the external plate 40 is aligned with a portion of gear rotor bore 52 within which the geometry between external teeth 54 and internal tooth recesses 56 create pumping chambers 58 of relatively small size. When the electric motor 24 is rotated by application of an electric current, inner gear rotor 46 rotates about drive shaft axis 32. By virtue of external teeth 54 engaging internal tooth recesses 56, rotation of inner gear rotor 46 causes outer gear rotor 48 to rotate about the second axis. In this way, the volume of pumping chambers 58 decreases as each pumping chamber 58 rotates from being in communication with the inlet 62 (and suction port 64) to being in communication with the outlet 63 (and delivery port 65), thereby causing oil to be pressurized and pumped from the inlet 62 to the outlet 63.
The internal plate 38 is adjacent the electric motor 24 and includes an inwardly-facing face surface 66 that faces the internal cavity 22, an opposite outwardly-facing face surface 67 that is adjacent the pumping ring 42, and a complementary suction port 68 formed in the outwardly-facing face surface 67. The complementary suction port 68 is in fluid communication with the suction port 64 of the external plate 40 via the pumping chambers 58 of the pumping arrangement 44 that are intermediate the suction port 64 and the complementary suction port 68. Similarly, a complementary delivery port 69 is also formed in the outwardly-facing face surface 67 of the internal plate 38. The complementary delivery port 69 is in fluid communication with the delivery port 65 of the external plate 40 via the pumping chambers 58 of the pumping arrangement 44 that are intermediate the delivery port 65 and the complementary delivery port 69. A fill passage 70 is connected to and in fluid communication with the complementary delivery port 69. The fill passage 70 extends to the inwardly-facing face surface 66 of the internal plate 38 and is also in fluid communication with the internal cavity 22 of the housing 20. The fill passage 70 is not particularly limited in shape, and may be, for example, a small, cylindrically-shaped orifice from the complementary delivery port 69 to the inwardly-facing face surface 66 of the internal plate 38. The internal plate 38 further includes a hub 71 in the form of a smaller diameter portion protruding from the inwardly-facing face surface 66 of the internal plate 38, i.e. the hub 71 has a small diameter than the diameter of the inwardly-facing face surface 66. The central bore 50 of the internal plate 38 is formed at least in part in the hub 71, and the hub 71 includes at least one, preferably two, lubrication passages 72 connecting the internal cavity 22 of the housing 20 to the central bore 50. Similar to the fill passage 70, the lubrication passages 72 may each be an orifice having a cylindrical shape; however, the lubrication passages are not limited to any particular shape. The two lubrication passages 72 may be offset approximately 180 degrees from each other in a radial direction around the hub 71, although the lubrication passages may be arranged in other relative dispositions. The lubrication passages 72 are connected to an annular ring 73 that encircles and surrounds a portion of the drive shaft 26.
A purge passage 74 extends from the outwardly-facing face surface 67 of the internal plate 38 to the inwardly-facing face surface 66 of the internal plate 38. The purge passage 74 protrudes from the internal plate 38 into the internal cavity 22 of the housing 20 and is thereby in fluid communication with the internal cavity 22. The pumping ring 42 includes an inwardly-facing face surface 75 adjacent the outwardly-facing face surface 67 of the internal plate 38, and an opposite, outwardly-facing face surface 76 adjacent the inwardly-facing face surface 61 of the external plate 40. A through passage 77 extends through the pumping ring 42 from the outwardly-facing face surface 76 to the inwardly-facing face surface 75. A channel 78 is formed in the outwardly-facing face surface 76 of the pumping ring 42. The channel 78 extends arcuately around a portion of the pumping ring 42 and is connected on one end 79 to the through passage 77 through the pumping ring 42. Further, a groove 80 is formed in the inwardly-facing face surface 61 of the external plate 40. The groove 80 is connected to and in fluid communication with the suction port 64, and the groove 80 is also connected to and in fluid communication with the other end 81 of the channel 78 in the pumping ring 42. Alternatively, the channel 78 may be formed in the inwardly-facing face surface 75 of the pumping ring 42, and the groove 80 may be formed in the outwardly-facing surface 67 of the internal plate 38 such that the groove is connected to and in fluid communication with the complementary suction port 68.
The internal plate 38 is mounted to the housing by a plurality of fasteners 82, such as two bolts or similar, that extend through the internal plate 38 and into the sidewall of the housing 20. Further, the internal plate 38, the pumping ring 42, and the external plate 40 are connected together by a plurality of fasteners 83, such as four bolts or similar, that extend through the plates 38, 40 and pumping ring 42, and also beyond the internal plate 38 and into the sidewall of the housing 20.
In operation, electricity is applied to the electric motor 24 which causes pumping arrangement 44 to rotate via rotation of the drive shaft 26, thereby drawing oil in through inlet 62 into the suction port 64 and subsequently to the pumping chambers 58 and the complementary suction port 68 at an initial pressure which may be by way of non-limiting example only, 0 kPa. Rotation of pumping arrangement 44 further causes the volume of pumping chambers 58 to decrease as each pumping chamber 58 rotates from being in communication with suction port 64 to being in communication with the delivery port 65 and complementary delivery port 69, thereby causing oil to be pressurized to a final pressure which is much greater than the initial pressure, and pumped from the delivery port 65 to the outlet 63. Simultaneously, the oil pumped by the pumping arrangement 44 is delivered to the internal cavity 22 of the housing 20 through the fill passage 70 that extends from complementary delivery port 69. The internal cavity 22 is thereby also pressurized with oil. The oil delivered to the internal cavity 22 provides for both cooling of the electric motor 24 and lubrication. The oil delivered to the internal cavity 22 also lubricates the drive shaft 26 bearing surface when it travels from the internal cavity 22 through the lubrication passages 72 to the annular ring 73. Further, at the same time, any air trapped in the internal cavity 22 is bled from the internal cavity 22 through the purge passage 74, the through passage 77 in the pumping ring 42, the channel 78 in the pumping ring 42, and the groove 80 in the external plate 40 in that order to the suction port 64. Purging of any air trapped in the internal cavity 22 assures that the internal cavity is fully lubricated and that there are no air pockets within the internal cavity that are not filled with liquid lubricant. Additionally, this purge pathway defined by the purge passage 74, through passage 77, channel 78, and groove 80 that connects the internal cavity 22 to the suction port 64 provides a route for pressurized oil to exit the internal cavity 22, thereby providing for circulation of the cooling/lubrication oil through the internal cavity 22 from the complementary delivery port 69 back to the suction port 64.
While the oil pump 10 has been described above by example as being a gerotor-type fluid pump, the oil pump may be another type of positive displacement pump such as an impeller-type pump or a vane-type pump, such that the rotating element of the pumping arrangement may take other forms which may include, by way of non-limiting example, an impeller.
Turning now to
With reference to
The pump 110′ shown in
With reference to
The pump 210′ shown in
With reference to
The pump 310′ shown in
With reference to
The pump 410′ shown in
With reference to
The pump 510′ shown in
It is to be understood that the appended claims are not limited to express and particular compounds, compositions, or methods described in the detailed description, which may vary between particular embodiments which fall within the scope of the appended claims. With respect to any Markush groups relied upon herein for describing particular features or aspects of various embodiments, different, special, and/or unexpected results may be obtained from each member of the respective Markush group independent from all other Markush members. Each member of a Markush group may be relied upon individually and or in combination and provides adequate support for specific embodiments within the scope of the appended claims.
Further, any ranges and subranges relied upon in describing various embodiments of the present invention independently and collectively fall within the scope of the appended claims, and are understood to describe and contemplate all ranges including whole and/or fractional values therein, even if such values are not expressly written herein. One of skill in the art readily recognizes that the enumerated ranges and subranges sufficiently describe and enable various embodiments of the present invention, and such ranges and subranges may be further delineated into relevant halves, thirds, quarters, fifths, and so on. As just one example, a range “of from 0.1 to 0.9” may be further delineated into a lower third, i.e., from 0.1 to 0.3, a middle third, i.e., from 0.4 to 0.6, and an upper third, i.e., from 0.7 to 0.9, which individually and collectively are within the scope of the appended claims, and may be relied upon individually and/or collectively and provide adequate support for specific embodiments within the scope of the appended claims. In addition, with respect to the language which defines or modifies a range, such as “at least,” “greater than,” “less than,” “no more than,” and the like, it is to be understood that such language includes subranges and/or an upper or lower limit. As another example, a range of “at least 10” inherently includes a subrange of from at least 10 to 35, a subrange of from at least 10 to 25, a subrange of from 25 to 35, and so on, and each subrange may be relied upon individually and/or collectively and provides adequate support for specific embodiments within the scope of the appended claims. Finally, an individual number within a disclosed range may be relied upon and provides adequate support for specific embodiments within the scope of the appended claims. For example, a range “of from 1 to 9” includes various individual integers, such as 3, as well as individual numbers including a decimal point (or fraction), such as 4.1, which may be relied upon and provide adequate support for specific embodiments within the scope of the appended claims.
The above description is that of current embodiments of the invention. Various alterations and changes can be made without departing from the spirit and broader aspects of the invention as defined in the appended claims, which are to be interpreted in accordance with the principles of patent law including the doctrine of equivalents. This disclosure is presented for illustrative purposes and should not be interpreted as an exhaustive description of all embodiments of the invention or to limit the scope of the claims to the specific elements illustrated or described in connection with these embodiments. For example, and without limitation, any individual element(s) of the described invention may be replaced by alternative elements that provide substantially similar functionality or otherwise provide adequate operation. This includes, for example, presently known alternative elements, such as those that might be currently known to one skilled in the art, and alternative elements that may be developed in the future, such as those that one skilled in the art might, upon development, recognize as an alternative. Further, the disclosed embodiments include a plurality of features that are described in concert and that might cooperatively provide a collection of benefits. The present invention is not limited to only those embodiments that include all of these features or that provide all of the stated benefits, except to the extent otherwise expressly set forth in the issued claims. Any reference to claim elements by ordinal terms, for example “first,” “second,” and “third,” are used for clarity, and are not to be construed as limiting the order in which the claim elements appear. Any reference to claim elements in the singular, for example, using the articles “a,” “an,” “the” or “said,” is not to be construed as limiting the element to the singular.