The present invention relates to an electric pump that draws in and discharges fluid such as oil.
Conventionally, electric pumps as disclosed in Japanese Patent No. 4042050 have been proposed. The electric pump includes a metal pump housing, which has a shaft support hole for rotationally supporting a middle part of a rotary shaft, and a motor case, which is fixed to the pump housing. A motor stator is provided in the motor case, and a motor rotor, which is provided on the end of the rotary shaft, is accommodated inside the motor stator. The motor case is formed of plastic and is insert-molded to cover the motor stator. A mounting portion for mounting a circuit substrate is integrally formed on a part of the motor case that is opposite to the part to which the pump housing is fixed. A circuit substrate that contains circuit components is mounted on the mounting portion, and the circuit substrate and the circuit components are covered by a cover fixed to the motor case.
However, in the electric pump as above described, heat generated at a motor section including the motor stator and the motor rotor is not easily dissipated by the plastic motor case. Also, since the heat generated at the motor section is directly transferred from the motor case to the circuit substrate, the heat may cause damage on the circuit components. That is, the heat generated at the motor section may be transferred from the mounting portion integrally formed on the motor case directly to the circuit substrate.
Accordingly, it is an objective of the present invention to provide an electric pump that is less likely to transmit heat of a motor section to a circuit substrate while easily dissipating the heat of the motor section.
In accordance with one aspect of the present disclosure, an electric pump is provided that includes a metal pump housing, a metal motor case, a plastic circuit case member, and a circuit substrate. The metal pump housing includes a shaft support hole for rotationally supporting a middle part of a rotary shaft and a pump chamber component. The rotary shaft includes a first end on which a pump operating portion is provided and a second end on which a motor rotor is provided, and the pump chamber component is configured to define a part of the pump chamber on one end of the shaft support hole. The metal motor case is fixed to the pump housing at a side of the second end. The motor case is configured to accommodate a motor section including a motor stator and a motor rotor inside the motor case. The plastic circuit case member fixed to a part of the motor case that is opposite to the part to which the pump housing is fixed. The circuit substrate contains a circuit component for controlling activation of the motor section. The circuit substrate is fixed to the circuit case member and is separate from the motor case.
According to the above-mentioned configuration, heat generated at the motor section is reliably dissipated from the motor case and the pump housing, which are made of metal. Also, since the circuit substrate fixed to the circuit case member is separate from the motor case, heat of the motor section is not easily transferred from the motor case directly to the circuit substrate. Furthermore, since the circuit case member is made of plastic, heat of the motor case is not easily transferred to the circuit substrate via the circuit case member. Thus, according to the electric pump of the above-mentioned configuration, while easily dissipating heat of the motor section from the motor case and the pump housing, the heat is prevented from being transferred to the circuit substrate. As a result, the circuit component is prevented from being damaged by heat.
According to the above-mentioned configuration, vibration generated at the pump operating portion and the motor section is prevented from being directly transmitted from the motor case to the circuit substrate. As a result, the circuit substrate and the circuit component are prevented from being damaged by vibration.
In accordance with one aspect, the circuit substrate is located inside the motor case.
According to the above-mentioned configuration, the entire length of the electric pump is prevented from being increased while ensuring the length of the motor case required for reliably dissipating heat.
In accordance with one aspect, the electric pump further includes a metal heat sink for dissipating heat of the circuit component, and the circuit case member is arranged between the heat sink and the motor case.
According to the above-mentioned configuration, since the circuit case member formed of plastic is arranged between the motor case and the heat sink, heat generated in the motor section is easily transferred to the metal pump housing and not easily transferred to the heat sink. Thus, the heat sink can be dedicated to dissipating heat generated at the circuit component. Thus, heat of the circuit component is reliably dissipated from the heat sink. As a result, the circuit component is prevented from being damaged by heat.
In accordance with one aspect, the circuit case member retains the circuit substrate in the vicinity of the motor case, and the circuit case member further includes a through hole, which extends in the axial direction of the rotary shaft. Also, the heat sink is provided on the circuit case member to close the through hole.
According to the above-mentioned configuration, the heat sink, which closes the through hole of the circuit case member, is exposed toward the motor case from the circuit case member on which the circuit substrate is retained. Thus, heat generated on the circuit component is efficiently transferred to the heat sink. As a result, heat of the circuit component is efficiently dissipated.
In accordance with one aspect, the heat sink is located inward of the outer shape of the circuit case member as viewed in the axial direction of the rotary shaft.
According to the above configuration, the size of the heat sink, which is made of metal that has a higher specific gravity as compared to plastic, is reduced. Therefore, load such as imposed load that the heat sink applies to the plastic circuit case member is efficiently reduced. Also, since the circuit case member is formed of plastic, deterioration by heat from the motor case is concerned. Thus, reducing the imposed load of the heat sink on the circuit case member is effective in terms of reducing deterioration of the circuit case member.
In accordance with one aspect, the motor stator includes a connecting portion. The circuit substrate includes an introduction bore connected to the connecting portion of the motor stator, and the axis of the introduction bore extends through the through hole of the circuit case member.
According to the above-mentioned configuration, the connection between the introduction bore of the circuit substrate and the coil connecting portion of the motor stator can be visually checked via the through hole of the circuit case member in a state in which the heat sink is not mounted. As a result, operability is improved.
In accordance with one aspect, the circuit case member includes an accommodating recess that recesses in a direction away from the circuit substrate to accommodate the circuit component, and the heat sink is arranged side-by-side with the accommodating recess in a direction orthogonal to the rotary shaft.
According to the above-mentioned configuration, the heat sink is arranged side-by-side with the accommodating recess in a direction orthogonal to the rotary shaft. Thus, the size of the circuit case member is prevented from being increased in the axial direction by providing the heat sink. The configuration contributes to size reduction of the electric pump in the axial direction.
In accordance with one aspect, the heat sink is a heat sink cover, and the heat sink cover and the motor case are fixed to sandwich the circuit case member. Also, a part of the heat sink cover close to the motor case includes a circuit accommodating recess for accommodating the circuit component.
According to the above-mentioned configuration, the circuit component is accommodated in the circuit accommodating recess of the heat sink cover. Thus, heat generated in the circuit component is more reliably dissipated from the heat sink cover. As a result, the circuit component is more reliably prevented from being damaged by heat.
In accordance with one aspect, the electric component includes a large circuit component and a small circuit component, and the large circuit component is larger than the small circuit component. The circuit accommodating recess includes a large recess, which is deep in the axial direction of the rotary shaft to be able to accommodate the large circuit component, and a small recess, which is shallow in the axial direction to be able to accommodate the small circuit component. A dissipation fin is formed on the back surface of the heat sink cover that corresponds to the small recess, the dissipation fin projecting in the axial direction.
According to the above-mentioned configuration, the dissipation fin, which projects in the axial direction, is formed on the back surface of the heat sink cover at a part that corresponds to the small recess. Thus, the dissipation fin is prevented from increasing the entire axial length of the electric pump, and the dissipation fin improves the dissipation performance.
In accordance with one aspect, the small circuit component includes a power transistor for controlling the motor stator, the motor stator is a stator of a brushless motor, and the small recess accommodates the power transistor.
According to the above-mentioned configuration, the power transistor for controlling the motor stator is accommodated in the small recess. Thus, heat from the power transistor that easily generates heat is efficiently dissipated from the dissipation fin, which is formed on the back surface of the small recess.
In accordance with one aspect, the power transistor is mounted on the circuit substrate, and the power transistor contacts a bottom surface of the small recess via an elastic member.
According to the above-mentioned configuration, the power transistor is mounted on the circuit substrate fixed to the circuit case member, and is abutted against the bottom surface of the small recess via an elastic member. Thus, the heat sink cover is prepared without requiring high dimensional accuracy, and heat from the power transistor is more efficiently dissipated from the dissipation fin, which is formed on the back surface of the small recess, via the elastic member.
In accordance with one aspect, the motor stator includes a coil connecting end. The circuit case member includes a guiding and retaining portion for retaining the coil connecting end and guiding the coil connecting end toward the circuit accommodating recess. The motor case and the circuit case member have a retaining structure that prevents movement of the motor case and the circuit case member relative to each other.
According to the above-mentioned configuration, the circuit case member includes the guiding and retaining portion, which retains the coil connecting end of the motor stator, and guides the coil connecting end toward the circuit accommodating recess. The motor case and the circuit case member have a retaining structure that prevents movement relative to each other. Thus, the coil connecting end is arranged in a stable manner facing toward the circuit accommodating recess. If the structure does not include the guiding and retaining groove nor the retaining structure, the coil connecting end can move freely and undesirably deform. In this case, it is difficult to improve the reliability of the connection between the coil connecting end and the circuit substrate, which is fixed to the circuit case member. However, the above-mentioned configuration improves such connection reliability.
In accordance with one aspect, the circuit case member is formed of a flexible plastic material.
According to the above-mentioned configuration, the flexible circuit case member absorbs vibration of the motor case. Thus, the vibration is prevented from being transmitted from the motor stator to the circuit substrate via the circuit case member.
In accordance with one aspect, the circuit substrate is fixed to the circuit case member by thermal staking.
According to the above-described configuration, circuit case member and the circuit substrate are fixed to each other without using a fixing member such as bolts. As a result, the structure is simplified.
In accordance with another aspect of the present disclosure, an electric pump is provided that includes a metal pump housing, a metal stator case, a plastic circuit case member, and a metal heat sink cover. The metal pump housing includes a shaft support hole for rotationally supporting a middle part of a rotary shaft and a pump chamber component. The rotary shaft includes a first end on which a pump operating portion is provided and a second end on which a motor rotor is provided, and the pump chamber component is configured to define a part of the pump chamber on one end of the shaft support hole. The metal stator case is fixed to the pump housing at a side of the second end. The stator case accommodates and fixes a motor stator, and the motor rotor is accommodated inside the motor stator. The plastic circuit case member is fixed to a part of the motor case that is opposite to the part to which the pump housing is fixed. The heat sink cover and the stator case are fixed to sandwich the circuit case member, and a part of the heat sink cover that is close to the stator case includes a circuit accommodating recess for accommodating a circuit component.
According to the above-described configuration, heat generated at the motor section including the motor stator and the motor rotor is reliably dissipated from the stator case and the pump housing, which are made of metal. Since the plastic circuit case member is located between the motor section and the heat sink cover, heat of the motor section is not easily transferred to the metal heat sink cover. That is, heat of the motor section is not easily transferred to the circuit accommodating recess. Thus, heat generated at the motor is not easily transferred to the circuit component accommodated in the circuit accommodating recess of the heat sink cover. Also, heat generated at the circuit component is reliably dissipated from the heat sink cover. Thus, the circuit component is prevented from being damaged by heat.
Other aspects and advantages of the disclosure will become apparent from the following description, taken in conjunction with the accompanying drawings, illustrating by way of example the principles of the disclosure.
The features of the present disclosure that are believed to be novel are set forth with particularity in the appended claims. The disclosure, together with objects and advantages thereof, may best be understood by reference to the following description of the presently preferred embodiments together with the accompanying drawings in which:
An electric pump for circulating vehicle oil according to a first embodiment of the present invention will be described with reference to
In
As shown in
The pump housing 1 is formed of metal, and more specifically, is formed of an aluminum alloy, which is a nonmagnetic metal. The pump housing 1 is columnar and has a shaft support hole 1a at the axis for rotationally supporting the middle part of the rotary shaft 7. The rotary shaft 7 of the first embodiment is formed of stainless-steel, which is a nonmagnetic metal. Also, a pump chamber recess 1b is formed on the first end of the pump housing 1 (left side in
The pump end plate 2 is formed of metal, and more specifically, is formed of an aluminum alloy, which is a nonmagnetic metal. The pump end plate 2 closes the pump chamber recess 1b as shown in
The pump rotor 8 of the first embodiment is of an internal gear type, and includes an outer rotor 8a, the number of teeth of which is represented by n (n is a natural number greater than or equal to 3), and an inner rotor 8b, the number of teeth of which is represented by n−1. The first end of the rotary shaft 7 is press-fitted in the inner rotor 8b.
Also, the stator case 3 is fixed to the second end of the pump housing 1.
The stator case 3 is formed of metal (for example, iron or steel), and the motor stator 6 is accommodated and fixed inside the stator case 3 as shown in
Also, the motor stator 6 is a stator that forms an inner rotor type brushless motor together with the motor rotor 9, and is formed by winding a coil 6b around teeth of a stator core 6a. The diameter of a socket-and-spigot fitting portion of the above-described embodiment, that is, the outer diameter of the pump housing spigot cylinder 1c and the inner diameter of the stator case socket cylinder 3c are set to be larger than the inner diameter of the motor stator 6. Also, the motor rotor 9 is a consequent pole rotor as shown in
Also, among the rotating bodies including the rotary shaft 7, the pump rotor 8, and the motor rotor 9, the weight moment at a section closer to the pump rotor 8 from the axial center of the shaft support hole 1a and the weight moment at a section closer to the motor rotor 9 from the axial center of the shaft support hole 1a are set to match with each other. The weight moments are values determined by the weights of the pump rotor 8 and the motor rotor 9, and the distances from the axial center of the shaft support hole 1a to the pump rotor 8 and the motor rotor 9.
The axial center of the motor stator 6 is slightly displaced from the axial center of the motor rotor 9 in the axial direction. The axial center of the motor stator 6 of the first embodiment is provided at a position displaced closer to the second end of the motor rotor 9 (right side in
As shown in
As shown in
Also, a circuit substrate 23 is fixed to the second end (right side in
As shown in
Also, dissipation fins 5d, which protrude in the axial direction, are formed on the back surface of the small recess 5c of the heat sink cover 5 as shown in
The operation (action) of the above described embodiment will now be described.
Three-phase drive current is supplied from a non-illustrated external power source to the coil 6b of the motor stator 6 via the connecting terminal 17 of the connector portion 4d and the circuit components of the circuit substrate 23. Then, a rotating magnetic field is generated in the motor stator 6, and rotating bodies including the motor rotor 9, the rotary shaft 7, and the pump rotor 8 are integrally rotated based on the rotating magnetic field. As the pump rotor 8 is rotated, oil is drawn into the pump chamber P from the inlet 2a, and the oil is discharged from the outlet 2b.
The first embodiment has the following advantages.
(1) Heat generated in the brushless motor including the motor stator 6 and the motor rotor 9 is reliably dissipated from the stator case 3 and the pump housing 1, which are made of metal. The circuit substrate 23, which is fixed to the circuit case member 4, is separate from the stator case 3. Thus, heat of the motor stator 6 is not easily transferred from the stator case 3 directly to the circuit substrate 23. Also, since the circuit case member 4 is formed of plastic, heat of the stator case 3 is not easily transferred to the circuit substrate 23 via the circuit case member 4. Thus, the heat is not easily transferred to the circuit substrate 23 while easily dissipating heat of the motor stator 6 from the stator case 3 and the pump housing 1. As a result, the circuit components such as the capacitors 21 and the power transistor 22 are prevented from being damaged by heat.
(2) The plastic circuit case member 4 is provided between the stator case 3 and the heat sink cover 5. Thus, heat generated in the motor stator 6 is not easily transferred to the heat sink cover 5, which is made of metal, and the circuit accommodating recess 5a. Thus, heat generated in the brushless motor is not easily transferred to the circuit components accommodated in the circuit accommodating recess 5a of the heat sink cover 5. Since heat generated in the circuit components is reliably dissipated from the heat sink cover 5, the circuit components are prevented from being damaged by heat.
(3) The circuit accommodating recess 5a includes the large recess 5b, which is deep in the axial direction to be able to accommodate the large circuit components such as the capacitors 21, and the small recess 5c, which is shallow in the axial direction to be able to accommodate a small and thin circuit component such as the power transistor 22. The dissipation fins 5d, which project in the axial direction, are formed on the back surface of the small recess 5c of the heat sink cover 5. Thus, the dissipation fins 5d are prevented from increasing the entire axial length of the electric pump, and the dissipation fins 5d improve the dissipation performance.
(4) The power transistor 22 for controlling the motor stator 6 is accommodated in the small recess 5c. Thus, heat from the power transistor 22, which easily generates heat, is efficiently dissipated from the dissipation fins 5d, which are formed on the back surface of the small recess 5c.
(5) The power transistor 22 is mounted on the circuit substrate 23 fixed to the circuit case member 4. Furthermore, the power transistor 22 is abutted against the bottom surface of the small recess 5c via the silicone rubber 24. Thus, heat from the power transistor 22 is more efficiently dissipated from the dissipation fins 5d, which are formed on the back surface of the small recess 5c, via the silicone rubber 24 without requiring high dimensional accuracy.
(6) The circuit case member 4 has the guiding and retaining grooves 4g, which retain the coil connecting ends 6c. The guiding and retaining grooves 4g guide the coil connecting ends 6c toward the circuit accommodating recess 5a. The stator case 3 and the circuit case member 4 have the clinch pieces 3e and the clinch receiving portions 4e, which serve as the retaining structure that prevents the stator case 3 and the circuit case member 4 from moving relative to each other. Thus, the coil connecting ends 6c are arranged in a stable manner facing toward the circuit accommodating recess 5a. If the structure does not include the guiding and retaining grooves 4g nor the retaining structure, which includes the clinch pieces 3e and the clinch receiving portion 4e, the coil connecting ends 6c may move freely and undesirably deform. Thus, for example, it might be difficult to improve the reliability of the connection between the coil connecting ends 6c and the circuit substrate 23, which is fixed to the circuit case member 4. However, the first embodiment improves the connection reliability of the coil connecting ends 6c.
(7) The rotor core 15 is a laminated core formed by laminating core sheets. Thus, eddy current that tends to occur by employing the consequent pole rotor is reduced. Thus, the brushless motor becomes highly efficient, and generation of heat in the rotor core 15 is reduced. Thus, the circuit components are further prevented from being damaged by heat.
(8) The circuit case member 4 is formed of a flexible plastic material. Since the circuit case member 4 absorbs vibration of the stator case 3, the vibration is prevented from being transmitted from the motor stator 6 to the circuit substrate 23 via the circuit case member 4.
The above described embodiment may be modified as follows.
In the above described embodiment, the stator case 3 includes the large cylinder portion 3a, the disk section 3b, and the stator case socket cylinder 3c. The pump housing spigot cylinder is fit in the stator case socket cylinder 3c in an axially long range in the socket-and-spigot manner. However, the shape and the configuration of parts may be modified as long as the stator case is fit to the pump housing in the socket-and-spigot manner.
For example, the present invention may be modified as shown in
According to the above-described embodiment, the axial lengths, that is, the thicknesses of the radially inward part and the radially outward part of the rotor core 15 are constant. However, the axial length of the rotor core at the radially inward part, in which the rotary shaft 7 is press-fitted, may be shorter than the axial length of the radially outward part.
For example, the invention may be modified as shown in
In this case, the weight of the rotor core 41 is reduced. Thus, for example, the weight moment of part of the rotating body close to the motor rotor 9 is reduced, and is easily set to match with the weight moment of the part of the rotating body close to the pump rotor 8. Also, the far-side annular recess 41b is formed in part of the rotor core 41 on the opposite side from the pump housing 1, that is, the right side in the drawing, and at a position far from the shaft support hole 1a. Thus, as compared to a case in which a near-side annular recess is formed in the vicinity of only the pump housing 1 as a comparative example, the weight moment of part of the rotating body close to the motor rotor 9 is further reduced. Thus, for example, it is possible to set the weight moment of part of the rotating body close to the motor rotor 9 and the weight moment of part of the rotating body close to the pump rotor 8 to easily match with each other.
The invention may be modified as shown in
In this case, the weight of the rotor core 42 is reduced. Thus, for example, the weight moment of part of the rotating body close to the motor rotor 9 is reduced, and is easily set to match with the weight moment of part of the rotating body close to the pump rotor 8. Also, at least part of the oil seal 11, in this example, the entire oil seal 11 is arranged in the near-side annular recess 42b. Thus, the entire axial length of the electric pump is reduced as compared to a case in which the oil seal 11 is not arranged in the near-side annular recess 42b as a comparative example such as the manner in
The invention may be modified as shown in
In the above-described embodiment, the diameter of a socket-and-spigot fitting portion of the pump housing 1 and the stator case 3, that is, the outer diameter of the pump housing spigot cylinder is and the inner diameter of the stator case socket cylinder 3c are set to be larger than the inner diameter of the motor stator 6. However, the diameter of a socket-and-spigot fitting portion may be set equal to the inner diameter of the motor stator 6.
In the above-described embodiment, the pump housing 1 and the stator case 3 are fastened by the through bolts 12. The through bolts 12 extend from the first end of the pump housing 1 to the second end of the stator case 3, which are the axial ends located far from each other. Furthermore, the through bolts 12 extend from the pump end plate 2 to the heat sink cover 5, which are members on both sides of the electric pump. However, the pump housing 1 may be fixed to the stator case 3 by other structure.
In the above-described embodiment, the circuit accommodating recess 5a includes the large recess 5b and the small recess 5c. However, for example, the circuit accommodating recess may have a constant depth.
In the above-described embodiment, the dissipation fins 5d, which project in the axial direction, are formed on the back surface of the small recess 5c of the heat sink cover 5. However, for example, the heat sink cover does not necessarily have to include the dissipation fins 5d, or the dissipation fins may be formed on the back surface of the large recess 5b.
In the above-described embodiment, the power transistor 22 is accommodated in the small recess 5c. However, the structure does not need to accommodate the power transistor 22. Also, in the above-described embodiment, the power transistor 22 contacts the bottom surface of the small recess 5c via the silicone rubber 24. However, for example, the structure does not necessarily have to include the silicone rubber 24. In this case, the power transistor 22 does not contact the bottom surface of the small recess 5c.
In the above described embodiment, the circuit case member 4 includes the guiding and retaining grooves 4g. The stator case 3 and the circuit case member 4 include the clinch pieces 3e and the clinch receiving portions 4e, which serve as the retaining structure that prevents movement relative to each other. However, the structure does not necessarily have to include the guiding and retaining grooves 4g and the retaining structure, which includes the clinch pieces 3e and the clinch receiving portions 4e. Also, the guiding and retaining portions of the above described embodiment are not limited to the guiding and retaining grooves 4g as long as the guiding and retaining portions retain the coil connecting ends 6c and guide the coil connecting ends 6c toward the circuit accommodating recess 5a. For example, the guiding and retaining portion may be changed to a guiding and retaining hole that extends through the inwardly extending portion 4f in the axial direction.
In the above described embodiment, the rotor core 15 is a laminated core formed by laminating core sheets. However, for example, the rotor core 15 may be changed to a rotor core formed of a sintered metal.
In the above described embodiment, the motor rotor 9 is a consequent pole rotor. However, the motor rotor 9 may be changed to other types of rotors.
In the above described embodiment, the rotating body including the rotary shaft 7, the pump rotor 8, and the motor rotor 9 is set such that the weight moment of a part close to the pump rotor 8 from the axial center of the shaft support hole 1a matches with the weight moment of a part close to the motor rotor 9 from the axial center of the shaft support hole 1a. However, it is not necessary to set as described above.
In the above described embodiment, the axial center of the motor stator 6 is provided to be located closer to the second end of the motor rotor 9 than the axial center of the motor rotor 9. That is, the axial center of the motor stator 6 is located at a position displaced in a direction to separate from the pump chamber P. However, the axial center of the motor stator 6 may be located near the first end, that is, at a position displaced toward the pump chamber P.
In the above described embodiment, the axial center of the motor stator 6 is located at a position displaced in the axial direction from the axial center of the motor rotor 9. However, the motor stator 6 and the motor rotor 9 may be provided such that the axial centers of the motor stator 6 and the motor rotor 9 match with each other.
In the above described embodiment, the motor rotor 9 is a flat rotor that has a diameter larger than the axial length. However, the motor rotor 9 may be changed to a rotor that has an axial length greater than the diameter.
In the above described embodiment, the pump operating portion, which is the pump rotor 8, is of an internal gear type. However, the pump operating portion may be changed to other pump rotor as long as it draws in and discharges fluid.
In the above described embodiment, the circuit substrate 23 may be fixed to the circuit case member 4 by thermal staking. With this structure, the circuit case member 4 and the circuit substrate 23 are fixed to each other without using a fixing member such as bolts. As a result, the structure is simplified.
A second embodiment of the present invention will now be described with reference to
In an electric pump according to the second embodiment, mainly the circuit case member differs from the first embodiment, and the fixing configuration of the circuit substrate is also different. Thus, hereinafter, like or the same reference numerals are given to those components that are like or the same as the corresponding components of the first embodiment and detailed explanations are omitted.
As shown in
The circuit case member 51 is formed of a flexible plastic material, and has a circular shape that is coaxial with the stator case 50 as viewed in the axial direction as shown in
A circuit substrate 60 is fixed to the circuit case member 51 to be located at part of the circuit case member 51 close to the stator case 50. Various circuit components such as capacitors 61, a noise eliminating element, which is a coil 62, power transistors 63, and a control IC 64 are mounted on the circuit substrate 60.
More specifically, substrate fixing portions 52 (four in the second embodiment), which bulge radially inward from the outer circumferential wall 51a and extend in the axial direction, are formed on the circuit case member 51 as shown in
A projection 52b, which projects in the axial direction, is formed on each contact surface 52a. In a state in which the projections 52b are inserted in the circuit substrate 60 and the contact surfaces 52a contact the circuit substrate 60, the projections 52b are melted by heat so that the circuit substrate 60 is thermally crimped to the contact surfaces 52a.
The circuit substrate 60 is fixed to be orthogonal to the axis of the rotary shaft 7 by contacting the contact surfaces 52a (see
As shown in
As shown in
As shown in
As shown in
As shown in
In this manner, the circuit case member 51 of the second embodiment covers the open end 50a of the stator case 50 with the accommodating recess 53 and the heat sink mounting portion 55. Since the through hole 57 formed in the heat sink mounting portion 55 is closed by the heat sink 54, the open end 50a of the stator case 50 is sealed.
As shown in
Also, as shown in
As shown in
As shown in
The power transistors 63 perform switching control of current supplied to the coil 6b of the motor stator 6, and are circuit components that tend to generate heat. In the second embodiment, at least some of the power transistors 63 are arranged within the projected range of the heat sink 54 in the axial direction. Thus, the power transistors 63 are arranged in the vicinity of the heat sink 54, and heat generated in the power transistors 63 are efficiently dissipated.
The operation of the second embodiment will now be described.
The stator case 50 is formed of metal, and the plastic circuit case member 51 is fixed to the open end 50a of the stator case 50 on the opposite side from the metal pump housing 1. Thus, heat generated at the motor section (the motor rotor 9 and the motor stator 6) is reliably dissipated from the stator case 50 and the pump housing 1. The circuit substrate 60 is fixed to the circuit case member 51, and is separated from the stator case 50. Thus, heat of the motor section is not easily transferred directly from the stator case 50 to the circuit substrate 60. Also, since the circuit case member 51 is formed of plastic, heat of the stator case 50 is not easily transferred to the circuit substrate 60 via the circuit case member 51. Thus, while facilitating dissipation of heat of the motor section from the stator case 50 and the pump housing 1, heat is prevented from being transferred to the circuit substrate 60. As a result, the circuit components are prevented from being damaged by heat. Also, vibration generated at the pump rotor 8 and the motor section is prevented from being directly transmitted from the stator case 50 to the circuit substrate 60. As a result, the circuit substrate 60 and the circuit components are prevented from being damaged by vibration.
Also, the circuit case member 51 is fixed to the open end 50a of the stator case 50, and the heat sink 54 is provided to form a part of the circuit case member 51. That is, since the plastic circuit case member 51 is arranged between the stator case 50 and the heat sink 54, heat generated at the motor section is easily transferred to the metal pump housing 1 and is hindered from being transferred to the heat sink 54.
Also, the circuit substrate 60 fixed to the circuit case member 51 is configured to be located inside the large diameter portion 50b of the stator case 50. If a structure in which the circuit substrate 60 is arranged in the circuit case member 51 unlike the second embodiment is considered as a comparative example, the size of the circuit case member 51 is increased in the axial direction. Furthermore, in the structure in which the circuit substrate 60 is arranged in the circuit case member 51, the axial length of the stator case 3 may be reduced to prevent the entire length or the axial length of the electric pump from being changed, that is, to prevent the entire length of the electric pump from being increased. That is, the ratio of the stator case 3 with respect to the entire length of the electric pump may be reduced. However, if the axial length of the stator case 3 is reduced, dissipating performance of the stator case 3 that dissipates heat of the motor section is reduced. In this respect, the second embodiment prevents the entire length of the electric pump from being increased since the circuit substrate 60 is arranged inside the stator case 50, without reducing the axial length of the stator case 3, that is, without reducing the ratio of the stator case 3 with respect to the entire length of the electric pump. That is, the second embodiment prevents the entire length of the electric pump from being increased while ensuring the axial length of the stator case 50 required to reliably dissipate the heat.
The second embodiment has the following advantages.
(9) The plastic circuit case member 51 is fixed to the open end 50a of the stator case 50. The circuit components for controlling activation of the motor section (the motor rotor 9 and the motor stator 6) are mounted on the circuit substrate 60. The circuit substrate 60 is fixed to the circuit case member 51 and is separate from the stator case 50. With this structure, heat generated at the motor section is reliably dissipated from the metal stator case 50 and the pump housing 1 located on the opposite side from the circuit case member 51. Also, since the circuit substrate 60 fixed to the circuit case member 51 is separate from the stator case 50, heat of the motor section is not easily transferred from the stator case 50 directly to the circuit substrate 60. Also, since the circuit case member 51 is formed of plastic, heat of the stator case 50 is not easily transferred to the circuit substrate 60 via the circuit case member 51. Thus, heat is prevented from being transferred to the circuit substrate 60 while facilitating dissipation of heat of the motor section from the stator case 50 and the pump housing 1. As a result, the circuit components are prevented from being damaged by heat. Also, vibration generated at the pump rotor 8 and the motor section is prevented from being directly transmitted from the stator case 50 to the circuit substrate 60. As a result, the circuit substrate 60 and the circuit components are prevented from being damaged by vibration.
(10) The electric pump includes the metal heat sink 54 for dissipating heat of the circuit components. The circuit case member 51 is located between the heat sink 54 and the stator case 50. With this structure, since the plastic circuit case member 51 is located between the stator case 50 and the heat sink 54, heat generated at the motor section is easily transferred to the metal pump housing 1 and is prevented from being transmitted to the heat sink 54. Thus, the heat sink 54 is allowed to dedicate to dissipating heat generated at the circuit components. Thus, heat of the circuit components is reliably dissipated from the heat sink 54. As a result, the circuit components are prevented from being damaged by heat.
(11) The circuit substrate 60 is configured to be located inside the large diameter portion 50b of the stator case 50. Thus, the entire length of the electric pump is prevented from being increased, and the size of the electric pump in the axial direction is prevented from being increased while ensuring the axial length of the stator case 50 required for reliably dissipating the heat.
(12) The circuit case member 51 retains the circuit substrate 60 such that the circuit substrate 60 is located in the vicinity of the stator case 50. Furthermore, the circuit case member 51 includes the through hole 57, which extends in the axial direction of the rotary shaft 7. The heat sink 54 is provided to close the through hole 57. With this configuration, the heat sink 54, which closes the through hole 57 of the circuit case member 51, is exposed in the vicinity of the stator case 50, near which the circuit substrate 60 is retained. Thus, heat generated at the circuit components is efficiently transferred to the heat sink 54. As a result, heat of the circuit components is efficiently dissipated.
(13) The heat sink 54 is located inward than the outer shape of the circuit case member 51 as viewed in the axial direction of the rotary shaft 7. Thus, the size of the heat sink 54, which is made of metal that has a higher specific gravity as compared to plastic, is reduced. Therefore, load such as imposed load that the heat sink 54 applies to the plastic circuit case member 51 is efficiently reduced. Also, since the circuit case member 51 is formed of plastic, deterioration by heat from the motor case is concerned. Thus, reducing the imposed load of the heat sink 54 on the circuit case member 51 is effective in terms of reducing deterioration of the circuit case member 51.
(14) The introduction bores 60c are formed in the circuit substrate 60, and are connected to the connecting portions drawn out from the coil 6b of the motor stator 6, which are the coil connecting ends 6c. The axes of the introduction bores 60c are configured to extend through the through hole 57 of the circuit case member 51. With this configuration, in the state in which the heat sink 54 is not mounted on the through hole 57 of the circuit case member 51, the connection between the introduction bores 60c of the circuit substrate 60 and the coil connecting ends 6c can be visually checked via the through hole 57 of the circuit case member 51. As a result, operability is improved.
(15) The circuit case member 51 includes the accommodating recess 53. The accommodating recess 53 is recessed in a direction away from the circuit substrate 60 to accommodate the circuit components, which include tall-height components such as the capacitors 61 and the coil 62. The heat sink 54 is arranged side-by-side with the accommodating recess 53 in a direction orthogonal to the rotary shaft 7. Thus, the size of the circuit case member 51 is prevented from being increased in the axial direction by providing the heat sink 54. This contributes to size reduction of the electric pump in the axial direction.
(16) The circuit case member 51 is formed of a flexible plastic material. Thus, the circuit case member 51 having flexibility absorbs vibration of the stator case 50. Thus, vibration is prevented from being transmitted from the motor stator 6 to the circuit substrate 60 via the circuit case member 51.
(17) The circuit substrate 60 is fixed to the circuit case member 51 by thermal staking. Thus, the circuit case member 51 and the circuit substrate 60 are fixed without using fasteners such as bolts. As a result, the structure is simplified.
The above described embodiments may be modified as follows.
According to the second embodiment, the circuit substrate 60 is fixed to the circuit case member 51 by thermal staking. However, the circuit substrate 60 may be fixed to the circuit case member 51 by bolts or an adhesive.
According to the second embodiment, the accommodating recess 53 and the heat sink 54 are arranged in proximity in the direction orthogonal to the rotary shaft 7 in the circuit case member 51. However, besides this, for example, the heat sink 54 may be located axially outward than the bottom wall 53a of the accommodating recess 53, that is, on the opposite side from the stator case 50.
According to the second embodiment, the circuit substrate 60 is arranged inside the large diameter portion 50b of the stator case 50. However, besides this, for example, the circuit substrate 60 may be arranged inside the circuit case member 51.
Types of the circuit components mounted on the circuit substrate 60 are not limited to the above-mentioned second embodiment, but may be modified as required in accordance with the configuration.
In each of the above embodiments, the electric pump is for circulating the vehicle oil. However, the electric pump may be used in other applications.
1 . . . pump housing, 1a . . . shaft support hole, 1b . . . pump chamber recess (pump chamber component), 3, 31, 50 . . . stator case (motor case), 3e . . . clinch pieces configuring part of retaining structure, 4, 51 . . . circuit case member, 4e . . . clinch receiving portions configuring part of retaining structure. 4g . . . guiding and retaining grooves (guiding and retaining portions), 5 . . . heat sink cover, 5a . . . circuit accommodating recess, 5b . . . large recess, 5c . . . small recess, 5d, 54b . . . dissipation fins, 6 . . . motor stator, 6c . . . coil connecting ends (connecting portions), 7 . . . rotary shaft, 8 . . . pump rotor (pump operating portion), 9 . . . motor rotor, 21, 61 . . . capacitors (circuit components), 22, 63 . . . power transistors (circuit components), 23, 60 . . . circuit substrate, 24 . . . silicone rubber (elastic member), 53 . . . accommodating recess, 54 . . . heat sink, 57 . . . through hole, 60c . . . introduction bores, 62 . . . coil (circuit component), 64 . . . control IC (circuit component), P . . . pump chamber.
Number | Date | Country | Kind |
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2012-007363 | Jan 2012 | JP | national |
2012-207333 | Sep 2012 | JP | national |
The present application is a divisional application of U.S. patent application Ser. No. 13/738,702, filed Jan. 10, 2013, which claims priority to Japanese Patent Application No. 2012-007363, filed Jan. 17, 2012 and Japanese Patent Application No. 2012-207333, filed Sep. 20, 2012, the disclosures of which are hereby incorporated by reference herein in their entireties.
Number | Date | Country | |
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Parent | 13738702 | Jan 2013 | US |
Child | 15639728 | US |