JP2019044679A - Electric oil pump - Google Patents

Abstract

To provide an electric pump capable of inhibiting the possibility that vibration may cause damage of an electronic component.SOLUTION: An electric pump 1 includes a motor section 10 having a shaft and a pump section 40 located at a front side of the motor section 10. The motor section 10 includes: a rotor 20; a stator 22; a motor housing 13 accommodating the rotor and the stator; and an inverter section 70 located at a rear side of the motor housing 13. The pump section 40 includes: a pump rotor 47 mounted to a front side of the shaft 11; and a pump housing 51 accommodating the pump rotor 47. The motor housing 13 includes a motor fixation section 15 fixed to the pump section 40, and the motor fixation section 15 is disposed at an inverter section side at an outer side of the motor housing 13. The pump housing 51 includes a fixed pump fixation section 65, and the motor fixation section 15 is disposed at a motor housing 13 side and an inverter section 70 side relative to a fixation position Q fixed to the pump fixation section 65.SELECTED DRAWING: Figure 1

Description

  The present invention relates to an electric oil pump.

  For example, Patent Document 1 discloses an electric oil pump in which an inverter unit having a circuit board and an electric pump are integrated. The electric oil pump has an oil pump portion and an inverter portion. The electric oil pump is housed and fixed in a pump housing hole provided in the transmission housing. More specifically, the oil pump portion is inserted into the pump receiving hole, and the inverter portion is disposed on the motor portion side of the oil pump portion and extends in a direction along the outer surface of the transmission housing. The part is fixed to the transmission housing via bolts.

JP, 2013-092126, A

  Although the electric oil pump described in Patent Document 1 is fixed in the transmission, the electric oil pump may be fixed to the outside of the transmission. When the electric oil pump is fixed to the outside of the transmission, the inverter unit is in a cantilevered state with respect to the fixing position of the electric oil pump to the transmission. Therefore, when the vibration generated by the engine or the like propagates to the electric oil pump via the transmission, the inverter unit at a position away from the fixed position may vibrate more than the vibration transmitted to the electric oil pump. Therefore, the ribs of the electronic component (for example, capacitor) mounted on the circuit board may be disconnected.

  An object of the present invention is to provide an electric oil pump capable of suppressing the possibility of damage to electronic parts mounted on a circuit board in the inverter part due to vibration when the electric oil pump having the inverter part is fixed.

  According to an exemplary first aspect of the present invention, there is provided a motor unit having a shaft centering on an axially extending central axis, and one axial side of the motor unit, the motor unit being driven by the motor unit via the shaft. A pump unit for discharging oil, wherein the motor unit accommodates a rotor fixed to the other axial side of the shaft, a stator positioned radially outward of the rotor, and the rotor and the stator A motor housing, and an inverter unit positioned on the other axial side of the motor housing and fixed to the motor housing, and the pump unit is a shaft that protrudes from the motor unit in one axial direction And a pump housing having a receiving portion for receiving the pump rotor, the motor housing includes Pump fixing portion fixed to the pump portion, the motor fixing portion is disposed outside the side surface of the motor housing and disposed on the inverter portion side, and the pump housing is fixed to the pump fixing portion The motor fixing portion is an electric oil pump disposed closer to the motor housing and closer to the inverter than a fixing position fixed to the pump fixing portion.

  According to the first aspect of the present invention, there is provided an electric oil pump capable of suppressing the possibility of damage to electronic parts mounted on a circuit board in the inverter part due to vibration when fixing the electric oil pump having the inverter part. Can be provided.

It is a sectional view of an electric oil pump concerning a 1st embodiment. FIG. 2 is a perspective view of a motor unit having a motor fixing unit according to the first embodiment. It is a sectional view of the modification of the electric oil pump concerning a 1st embodiment. It is a top view which shows the modification of arrangement | positioning of an electronic component when the circuit board which concerns on 1st Embodiment is transparently viewed toward the motor part side, and is seen. It is a perspective view of a modification of arrangement of electronic parts when a circuit board concerning a 1st embodiment is seen visually from the slanting front side toward a rear side.

  Hereinafter, an electric oil pump according to an embodiment of the present invention will be described with reference to the drawings. Moreover, in the following drawings, in order to make each structure intelligible, the scale, the number, etc. in an actual structure and each structure may be made different.

  In the drawings, an XYZ coordinate system is shown as a three-dimensional orthogonal coordinate system as appropriate. In the XYZ coordinate system, the Z axis direction is a direction parallel to the other axial direction of the central axis J shown in FIG. The X-axis direction is a direction parallel to the short direction of the electric oil pump shown in FIG. 1, that is, the left-right direction in FIG. The Y-axis direction is orthogonal to both the X-axis direction and the Z-axis direction.

  Further, in the following description, the positive side (+ Z side) in the Z-axis direction is described as "rear side", and the negative side (-Z side) in the Z-axis direction is described as "front side". The rear side and the front side are names used merely for the purpose of explanation and do not limit the actual positional relationship or direction. Moreover, unless otherwise noted, the direction parallel to the central axis J (Z-axis direction) is simply described as “axial direction”, the radial direction centered on the central axis J is simply described as “radial direction”, and the central axis J A circumferential direction centering around the center axis, that is, around the axis (the θ direction) of the central axis J is simply referred to as “circumferential direction”.

  In the present specification, “extending in the axial direction” means not only extending strictly in the axial direction (Z-axis direction), but also extending in a direction inclined at less than 45 ° with respect to the axial direction. Including. Furthermore, in the present specification, “extending radially” means 45 ° with respect to the radial direction, in addition to the case of extending in the radial direction strictly, that is, perpendicular to the axial direction (Z-axis direction). It also includes the case of extending in an inclined direction in the range below.

First Embodiment
<Overall configuration>
FIG. 1 is a cross-sectional view of the electric oil pump according to the first embodiment. The electric oil pump 1 of the present embodiment has a motor unit 10 and a pump unit 40, as shown in FIG. The motor unit 10 and the pump unit 40 are disposed along the axial direction. The motor unit 10 has a shaft 11 disposed along a central axis J extending in the axial direction. The pump unit 40 is located on one side (front side) of the motor unit 10 in the axial direction, and is driven by the motor unit 10 via the shaft 11 to discharge oil. Hereinafter, each component will be described in detail.

<Motor unit 10>
As illustrated in FIG. 1, the motor unit 10 includes a motor housing 13, a rotor 20, a shaft 11, a stator 22, and an inverter unit 70.

  The motor unit 10 is, for example, an inner rotor type motor, and the rotor 20 is fixed to the outer peripheral surface of the shaft 11, and the stator 22 is located radially outside the rotor 20.

(Motor housing 13)
As shown in FIG. 1, the motor housing 13 has a stator holding portion 13a, an inverter holding portion 13b, a pump body holding portion 13c, and a motor fixing portion 15. The motor housing 13 is made of metal. The motor housing 13 has a bottomed cylindrical shape having a bottom 13 d on the side of the inverter unit 70.

(Stator holding portion 13a)
The stator holding portion 13a extends in the axial direction and has a through hole 13a1 inside. The shaft 11, the rotor 20, and the stator 22 of the motor unit 10 are disposed in the through hole 13a1. The outer side surface of the stator 22, that is, the outer side surface of the core back portion 22a described later is fitted to the inner side surface of the stator holding portion 13a. Thereby, the stator 22 is accommodated in the stator holding portion 13a.

(Inverter holding unit 13b)
The inverter holding portion 13 b is a portion connected to the rear end of the stator holding portion 13 a. In the present embodiment, the inverter holding portion 13b has a rear end 13b1 of the stator holding portion 13a and a disk-like bottom 13d extending radially inward from the rear end 13b1. A communication hole 13d1 penetrating in the axial direction is provided at a central portion of the bottom 13d. The communication hole 13 d 1 communicates with the through hole 71 provided in the inverter unit 70 to communicate the inside of the motor unit 10 with the inside of the inverter unit 70.

  The bottom portion 13d has a plurality of screw holes 13d2 axially penetrating at intervals in the circumferential direction on the radially outer side of the communication hole 13d1. In the present embodiment, the axial thickness (thickness) of the screw hole 13d3 of the bottom 13d in which the screw hole 13d2 is provided is greater than the thickness of the radially outer portion 13d4 of the bottom 13d. This increases the axial thickness of the screw hole 13d3 in order to secure the necessary minimum axial length of the screw hole 13d2. The screw hole portion 13d3 may be formed by forming a cylindrical flange portion protruding in the axial direction by burring a sheet metal and providing an internal thread portion on the inner surface of the flange portion.

(Pump body holding portion 13c)
The pump body holding portion 13c has a tubular shape with an open front side, and is continuously connected to the front end of the stator holding portion 13a. The inside of the pump body holding portion 13c has a hole 13c1 extending in the axial direction. The inner diameter of the hole 13c1 has a size slightly larger than the outer diameter of the rear side of the pump body 52 of the pump portion 40 described later. The rear side of the pump body 52 is fitted to the inner side surface of the hole 13c1.

  A motor side flange portion 13c3 protruding in the radial direction is provided on the outer side surface 13c2 of the pump body holding portion 13c. The motor side flange portion 13c3 is disposed to face a pump side flange portion 52a provided on a pump body 52 described later, and is fixed to the pump side flange portion 52a by fastening means such as a bolt 42 or the like. Thus, the pump unit 40 is fixed to the motor housing 13.

(Motor fixing part 15)
FIG. 2 is a perspective view of a motor unit 10 having a motor fixing unit 15 according to the present embodiment. The motor fixing portion 15 is fixed to the pump portion as shown in FIGS. 1 and 2. The motor fixing portion 15 has a fixing surface portion 15a disposed to face the outer side surface 13e of the motor housing 13 and a projection 15b protruding from the fixing surface portion 15a. The fixed surface portion 15 a is in the form of a plate that curves along the outer side surface 13 e of the motor housing 13. The fixed surface portion 15a has a welded portion 15a1 at the outer peripheral edge. The welding portion 15a1 is a portion for welding the fixing surface portion 15a to the outer side surface 13e of the motor housing 13 by welding. For this reason, the fixed surface portion 15a is firmly fixed to the outer side surface 13e of the motor housing 13 via the welded portion 15a1. The fixing surface portion 15a is not limited to being fixed to the outer surface 13e of the motor housing 13 by welding. The fixed surface portion 15a may be fixed to the outer side surface 13e of the motor housing 13 by fastening means such as a bolt.

  The protrusion 15 b protrudes radially outward from one circumferential end of the fixed surface 15 a. In the present embodiment, the protrusion 15 b is a plate having a pair of flat side surfaces 15 b 1 on both sides in the circumferential direction. A hole 15b2 is provided on the tip end side in the protrusion direction of the protrusion 15b. A bolt 16 is passed through the hole 15 b 2 and fixed to a pump fixing portion 65 provided on the pump portion 40 side. The details of the pump fixing portion 65 will be described later.

  The motor fixing portion 15 is located outside the side surface of the motor housing 13 and disposed on the inverter portion 70 side. Furthermore, the motor fixing portion 15 is disposed closer to the motor housing 13 and closer to the inverter portion 70 than the fixing position Q to be fixed to the pump fixing portion 65. In this embodiment, the center P of the fixing hole 65a of the pump fixing portion 65 is disposed on an imaginary line L0 extending in a direction perpendicular to the axial direction through the center of gravity G0 of the electric oil pump 1, and the motor fixing portion The position of the center S of the hole 15 b 2 of the protrusion 15 b is located closer to the motor housing 13 and the inverter 70 than the center P of the fixing hole 65 a of the pump fixing portion 65. Therefore, the motor fixing portion 15 can be fixed to the pump fixing portion 65 in a state in which the motor fixing portion 15 approaches the inverter portion 70 side. Further, since the pump fixing portion 65 is located on the virtual line L0 passing through the center of gravity G0 of the electric oil pump 1, the vibration transmitted to the pump fixing portion 65 can suppress an increase in the vibration propagating to the electric oil pump 1 . The fixed position Q is an area in which the pump fixing portion 65 is fixed to a transmission or the like by the head of a bolt passed through the fixing hole portion 65a. For this reason, the fixing position Q includes a region where the head of the bolt on the radial direction outer side of the fixing hole portion 65 a and the fixing hole portion 65 a contacts the pump fixing portion 65. Therefore, the center of the fixed position Q is the center P.

  Further, in the motor fixing portion 15, the position of the center S of the hole portion 15b2 of the projecting portion 15b is orthogonal to the axial direction through the center of gravity G1, G2, G3 of any of the motor portion 10, the rotor 20, and the stator 22. It may be disposed at a position closer to the inverter unit 70 than the virtual lines L1, L2, and L3 extending in the direction. The centers of gravity G1, G2, and G3 are located closer to the inverter unit 70 than the center of gravity G0. Therefore, the position of the center S of the hole 15b2 is disposed on the side closer to the inverter unit 70 than the imaginary lines L1, L2, and L3 extending in the direction orthogonal to the axial direction through the centers of gravity G1, G2, and G3. Thus, the motor fixing portion 15 can be disposed at a position closer to the inverter portion 70 side. When the motor fixing portion 15 is fixed to the pump fixing portion 65, an elastic body capable of absorbing vibration is disposed between the motor fixing portion 15 and the fixing projection 67 of the pump fixing portion 65, and the motor fixing portion 15 may be fastened and fixed to the pump fixing portion 65.

(Rotor 20)
The rotor 20 has a rotor core 20a and a rotor magnet 20b. The rotor core 20 a is fixed to the shaft 11 so as to surround the shaft 11 around the axis (θ direction). The rotor magnet 20b is fixed to the outer surface along the circumference (θ direction) of the axis of the rotor core 20a. The rotor core 20 a and the rotor magnet 20 b rotate with the shaft 11. The rotor 20 may be an embedded magnet type in which a permanent magnet is embedded in the rotor 20. Compared with a surface magnet type in which permanent magnets are provided on the surface of the rotor 20, the embedded magnet type rotor 20 can reduce the possibility that the magnet will be peeled off by the centrifugal force, and the reluctance torque is actively used. can do.

(Stator 22)
The stator 22 surrounds the rotor 20 around an axis (θ direction), and rotates the rotor 20 around the central axis J. The stator 22 has a core back portion 22a, teeth portions 22c, a coil 22b, and an insulator (bobbin) 22d.

  The core back portion 22 a has a cylindrical shape concentric with the shaft 11. The teeth portion 22 c extends from the inner surface of the core back portion 22 a toward the shaft 11. A plurality of teeth portions 22c are provided, and are arranged at equal intervals in the circumferential direction of the inner side surface of the core back portion 22a. The coil 22b is provided around the insulator (bobbin) 22d, and the conductive wire 22e is wound. The insulator (bobbin) 19 is attached to each tooth portion 22c.

(Shaft 11)
The shaft 11 extends along the central axis J and penetrates the motor unit 10, as shown in FIG. The front side (−Z side) of the shaft 11 protrudes from the motor unit 10 and extends into the pump unit 40. The rear side (+ Z side) of the shaft 11 protrudes from the rotor 20 and becomes a free end. For this reason, the rotor 20 is in a cantilever support state in which the front side of the shaft 11 is supported by a slide bearing 45 described later.

(Inverter unit 70)
The inverter unit 70 has a bottomed container-like inverter housing 73 having a housing portion 73 a which is open on the rear side and is recessed on the front side and extends in the X-axis direction, and a cover portion 90.

  In the housing portion 73a, the rear side opening of the housing portion 73a is covered by the cover portion 90. The circuit board 75, the connector side terminal 77, the bus bar 79 (see FIG. 4), the terminal portion 81, and the like are accommodated in the accommodating portion 73a.

  The connector side terminal 77 is disposed on the left side in the X axis direction in the housing portion 73 a, one end side is electrically connected to the coil end 22 b 1 of the motor portion 10 via the bus bar 79, and the other end side is electrically connected to the circuit board 75 Connected The terminal portion 81 is disposed on the right side in the X-axis direction in the housing portion 73 a, one end side is electrically connected to an external connector not shown, and the other end side is electrically connected to the circuit board 75.

  The circuit board 75 outputs a motor output signal. The circuit board 75 is disposed on the rear side of the housing portion 73a and extends in a direction intersecting the axial direction. In the present embodiment, the circuit board 75 extends in the X-axis direction orthogonal to the axial direction. Printed wiring, not shown, is provided on the front side surface 75 a of the circuit board 75. Further, a plurality of electronic components are mounted on the front side surface 75 a of the circuit board 75. In the illustrated embodiment, an electronic component 83 (for example, a capacitor 83a, a choke coil 83b, etc.) whose leads are electrically connected to the circuit board 75 is mounted. Further, by using a copper inlay substrate as the circuit substrate 75, it is possible to dissipate the heat generated by the heating element (not shown) through the cover portion.

  As shown in FIG. 1, on the front side of the inverter housing 73, a fixing portion 73b fixed to the bottom 13d of the motor housing 13 is provided. In the present embodiment, the fixing portion 73b has a disk shape centering on the central axis J in the axial direction view, and the bottom portion via the plurality of bolts 74 in a state of being mounted on the bottom portion 13d of the motor housing 13 Fastened to 13d. The fixing portion 73b is disposed radially inward of the bottom portion 13d.

  A plurality of bus bars 79 are disposed on the rear surface of the fixing portion 73b. In the present embodiment, three bus bars 79 are arranged at intervals in the circumferential direction (see FIG. 4). The connector side terminal 77 and the coil end 22b1 are connected to each of the three bus bars 79.

  The inverter housing 73 has a wall 73 c extending from the peripheral edge of the fixed portion 73 b to the front side. A fitting hole 73c1 for fitting the rear side of the motor housing 13 is provided inside the wall 73c. For this reason, the fixing portion 73b is fixed to the bottom portion 13d of the motor housing 13 in a state where the rear side of the motor housing 13 is fitted in the fitting hole portion 73c1, whereby the inverter portion 70 is predetermined relative to the motor housing 13. The inverter unit 70 can be fixed to the motor housing 13 while maintaining the posture.

<Pump part 40>
The pump unit 40 is located on one side in the axial direction of the motor unit 10, specifically, on the front side (−Z side). The pump unit 40 is driven by the motor unit 10 via the shaft 11. The pump unit 40 has a pump rotor 47 and a pump housing 51. The pump housing 51 has a pump body 52 and a pump cover 57. Each component will be described in detail below.

(Pump body 52)
The pump body 52 is fixed in the front side (−Z side) of the motor housing 13 on the front side (−Z side) of the motor unit 10. The pump body 52 has a recess 54 recessed from the surface on the rear side (+ Z side) to the front side (−Z side). A seal member 59 is accommodated in the recess 54. The rear side outer surface 52 b of the pump body 52 is provided with an annular recess 60 which is recessed radially inward. A seal member 61 (for example, an O-ring) is inserted into the recess 60.

  The pump body 52 has a through hole 55 penetrating along the central axis J. In the through hole 55, both axial ends are open and the shaft 11 is passed, the opening on the rear side (+ Z side) is open to the recess 54, and the opening on the front side (−Z side) is on the front side end of the pump body 52 Open. The through hole 55 functions as a slide bearing 45 that rotatably supports the shaft 11.

  A pump side flange 52 a is provided at the radially outer end of the pump body 52. A plurality of pump side flanges 52a are provided at intervals in the circumferential direction.

(Pump cover 57)
As shown in FIG. 1, the pump cover 57 is directed toward the motor unit 10 from the pump cover main body 57 a attached to one side in the axial direction of the pump body 52 and the radial one end of the pump cover main body 57 a. And an extending pump cover arm 57b. The pump cover main body portion 57 a has a housing portion 53 for housing the pump rotor 47 and having a side surface and a bottom surface located on the front side (−Z side) of the motor portion 10. The housing portion 53 opens on the rear side (+ Z side) and is recessed on the front side (−Z side). The shape of the accommodation portion 53 as viewed from the axial direction is circular.

  The pump cover main body portion 57 a covers the pump body 52 from the front side (−Z side) to provide the housing portion 53 with the pump body 52.

  A pump cover side flange portion 57a1 is provided at the radially outer end portion of the pump cover main body portion 57a. A plurality of pump cover side flange portions 57a1 are provided at intervals in the circumferential direction. The pump cover side flange portion 57a1 is provided with a female screw on which the bolt 42 can be screwed.

  The motor-side flange portion 13c3 and the pump-side flange portion 52a are disposed on the pump cover-side flange portion 57a1 so that the motor-side flange portion 13c3 and the pump-side flange portion 52a pass through. The motor portion 10 can be fixed to the pump portion 40 by being fastened to the female screw provided on the flange portion 57a1.

  The pump cover arm 57 b extends from the radially outer end of the pump cover body 57 a along the outer surface 13 e of the motor housing 13 to the rear of the motor unit 10. The pump cover arm 57b is formed in a rectangular parallelepiped shape to enhance rigidity. At the rear end of the pump cover arm 57b, a pump fixing portion 65 is provided. In the present embodiment, the pump fixing portion 65 is fixed to, for example, a transmission. The pump fixing portion 65 is box-like, and has a fixing hole portion 65 a penetrating in the Y-axis direction. A fastening means such as a bolt is inserted into the fixing hole portion 65a, and the pump fixing portion 65 is firmly fixed to an object to be fixed such as a transmission.

  At the rear end of the pump fixing portion 65, a fixing protrusion 67 projecting toward the motor portion 10 is provided. A female screw portion is provided at the tip end of the fixing protrusion 67 in the protruding direction. The motor fixing portion 15 is fixed to the fixing protrusion 67 by screwing a bolt inserted into the hole 15 b 2 of the protrusion 15 b to the female screw portion of the fixing protrusion 67. Here, the motor fixing portion 15 is disposed in the vicinity of the pump fixing portion 65. In the illustrated embodiment, the motor fixing portion 15 is disposed closer to the motor portion 10 and to the inverter portion 70 than the center of the fixing hole portion 65 a of the pump fixing portion 65.

  For this reason, the motor unit 10 is firmly fixed to the pump fixing unit 65 via the motor fixing unit 15 disposed in the vicinity of the pump fixing unit 65.

  In the first embodiment described above, an example in which the housing 53 for housing the pump rotor 47 is provided on the pump cover 57 has been described, but the present invention is not limited to this. The housing 53 may be provided on the pump body 52.

(Pump rotor 47)
The pump rotor 47 is attached to the shaft 11. More specifically, the pump rotor 47 is attached to the front side (−Z side) of the shaft 11. The pump rotor 47 has an inner rotor 47a attached to the shaft 11, and an outer rotor 47b surrounding the radially outer side of the inner rotor 47a. The inner rotor 47a is annular. The inner rotor 47a is a gear having teeth on the radially outer surface.

  The inner rotor 47 a is fixed to the shaft 11. More specifically, the end on the front side (−Z side) of the shaft 11 is press-fitted into the inner rotor 47 a. The inner rotor 47 a rotates with the shaft 11 around the axis (θ direction). The outer rotor 47 b has an annular shape surrounding the radially outer side of the inner rotor 47 a. The outer rotor 47 b is a gear having teeth on the radially inner side.

  The inner rotor 47a and the outer rotor 47b mesh with each other, and the outer rotor 47b rotates as the inner rotor 47a rotates. That is, the pump rotor 47 is rotated by the rotation of the shaft 11. In other words, the motor unit 10 and the pump unit 40 have the same rotation axis. Thereby, it can suppress that the electrically-driven oil pump 1 enlarges to an axial direction.

  Further, as the inner rotor 47a and the outer rotor 47b rotate, the volume between the meshed portion of the inner rotor 47a and the outer rotor 47b changes. The area where the volume decreases is the pressure area, and the area where the volume increases is the negative pressure area. A suction port is disposed on the front side (−Z side) of the negative pressure region of the pump rotor 47. Further, on the front side (−Z side) of the pressurizing region Ap of the pump rotor 47, the discharge port is disposed. Here, the oil sucked into the accommodation portion 53 from the suction port 57c provided in the pump cover 57 is accommodated in the volume portion between the inner rotor 47a and the outer rotor 47b, and is sent to the pressurizing region. Thereafter, the oil is discharged from the discharge port 57d provided in the pump cover 57 through the discharge port.

<Operation and effect of electric oil pump 1>
Next, the operation and effects of the electric oil pump 1 will be described. As shown in FIG. 1, when the motor unit 10 of the electric oil pump 1 is driven, the shaft 11 of the motor unit 10 is rotated, and the outer rotor 47b is also rotated along with the rotation of the inner rotor 47a of the pump rotor 47. When the pump rotor 47 rotates, the oil sucked from the suction port 57c of the pump unit 40 moves in the storage unit 53 of the pump unit 40, and is discharged from the discharge port 57d through the discharge port.

(1) Here, the pump housing 51 of the electric oil pump 1 according to the present embodiment has the pump fixing portion 65 fixed, and the motor fixing portion 15 is positioned outside the side surface of the motor housing 13 It is disposed on the side of the inverter unit 70 and is disposed on the side of the motor housing 13 and the side of the inverter unit 70 with respect to the fixing position Q fixed to the pump fixing portion 65. For this reason, the motor unit 10 is firmly fixed to the fixing destination (for example, a transmission) via the motor fixing unit 15 and the pump fixing unit 65. In addition, although the inverter unit 70 is in a cantilevered state with respect to the fixed position Q fixed to the pump fixing unit 65, the motor fixing unit 15 is disposed on the motor housing 13 side and the inverter unit 70 side. Therefore, the motor fixing portion 15 can be brought close to the inverter portion 70. Therefore, when the vibration generated from the engine or the like is transmitted to the motor fixing portion 15 via the fixed object (for example, transmission) and is transmitted to the motor housing 13 and the inverter portion 70, the vibration is transmitted to the motor housing 13 An increase in vibration can be suppressed. Therefore, with respect to the propagation of the vibration to the inverter unit 70 fixed to the motor housing 13, the increase of the vibration can be suppressed.

(2) Further, the motor fixing portion 15 has a welded portion 15a1 fixed to the motor housing 13 by welding. Therefore, the motor fixing portion 15 can be easily provided on the motor housing 13.

(3) Also, as shown in FIG. 2, the motor fixing portion 15 has a fixing surface portion 15a and a projecting portion 15b, and the fixing surface portion 15a has a welding portion 15a1 at the outer peripheral edge. Therefore, as compared with the case where the projection 15 b is directly fixed to the motor housing 13 by welding, the welding length for welding the fixed surface portion 15 a to the motor housing 13 can be made longer. Therefore, the fixing strength of the motor fixing portion 15 to the motor housing 13 can be increased.

(4) Further, since the motor fixing portion 15 is fixed to the pump cover 57, the motor portion 10 can be fixed to the pump portion 40 via the pump cover 57.

(5) Further, since the pump cover arm 57b extends from the radial one end of the pump cover main body 57a toward the motor unit 10 side, the motor fixing portion with respect to the tip end of the pump cover arm 57b It is possible to place 15 at a position adjacent to it. Thus, the motor fixing portion 15 can be easily fixed to the pump cover arm 57b.

[Modification of First Embodiment] (Modification to Fix Motor 10 to Pump Body 52)
FIG. 3 is a cross-sectional view of a modification of the electric oil pump 1 according to the first embodiment. The motor fixing portion 15 according to the first embodiment shown in FIG. 1 is fixed to a pump cover arm 57 b extending from the pump cover 57. However, the present invention is not limited to this structure. For example, as shown in FIG. 3, the motor fixing portion 15 may be fixed to the pump body arm 93 b extending from the pump body 93 (Modification 1). In the description of the first modification, only differences from the first embodiment described above will be described, and the same parts as those in the first embodiment will be assigned the same reference numerals and descriptions thereof will be omitted.

  The pump housing 91 has a pump body 93 having a housing 94 and a pump cover 96 mounted on one side in the axial direction of the pump body 93. The pump body 93 includes a pump body main body 93a attached to the front side of the motor housing 13, and a pump body arm 93b extending toward the motor 10 from one radial end of the pump body main body 93a. Have. The front side of the housing portion 94 provided in the pump body main portion 93a is open and recessed toward the rear side. The through hole 55 has an opening on the rear side (+ Z side) open to the recess 54, and an opening on the front side (−Z side) open to the accommodation portion 94.

  The pump body arm 93 b extends from the radially outer end of the pump body 93 a along the outer surface 13 e of the motor housing 13 to the rear of the motor 10. The pump body arm 93b is formed in a rectangular parallelepiped shape to enhance rigidity. A pump fixing portion 65 is provided at the rear end of the pump body arm 93b.

  A fixing projection 67 is provided at the rear end of the pump fixing portion. The motor fixing portion 15 is fixed to a tip end portion in the protruding direction of the fixing projection portion 67 via a fastening means such as a bolt.

  In this modification, since the motor fixing portion 15 is fixed to the pump body 93, the motor portion 10 can be fixed to the pump portion 40 via the pump body 93. Further, since the pump body arm 93b extends from the radial one end of the pump body 93a toward the motor 10, the motor fixing portion 15 is in the vicinity of the tip of the pump body arm 93b. It can be placed at the Therefore, the motor fixing portion 15 can be easily fixed to the pump body arm 93 b.

  In addition, although the example which provided the accommodating part 53 which accommodates the pump rotor 47 in the pump body 93 was shown in the modification 1 of 1st Embodiment mentioned above, it does not restrict to this. The housing portion 94 may be provided on the pump cover 96. It may be provided to

[Other Modifications of First Embodiment] (Position of Electronic Component with Respect to Motor Fixing Part)
FIG. 4 is a plan view of a modified example of the circuit board 75 when the circuit board 75 according to the first embodiment is viewed transparently toward the motor unit 10 side. FIG. 5 is a perspective view of a modified example of the circuit board 75 in which the circuit board 75 according to the first embodiment is viewed from the oblique front side to the rear side. On the circuit board 75 according to the first embodiment shown in FIG. 1, electronic components 83 (for example, a capacitor 83a and a choke coil 83b) whose leads are electrically connected to the front side surface 75a are mounted. However, the positional relationship of the electronic component 83 with respect to other components is not specified. Therefore, the electronic component 83 may be disposed at a position where at least a portion of the electronic component 83 overlaps the motor fixing portion 15 when the circuit board 75 is viewed from the rear side to the front side (Modification 2) .

  As shown in FIG. 4, the electronic component 83 is disposed at a position where at least a portion of the electronic component 83 overlaps the motor fixing portion 15 when the circuit board 75 is viewed from the rear side to the front side. In the present embodiment, a portion on the positive side in the Y-axis direction of the capacitor 83 a is disposed at a position overlapping the protrusion 15 b of the motor fixing portion 15.

  Here, the motor unit 10 is in a cantilevered state with the motor fixing portion 15 as a fixing point. Therefore, when the circuit board 75 is viewed from the rear side to the front side, a moment according to the distance between the electronic component 83 and the motor fixing portion 15 acts on the electronic component 83. Then, when the vibration generated from the engine or the like is transmitted to the motor unit 10 via the transmission of the fixed object, the vibration is transmitted to the circuit board 75 via the motor unit 10. If this vibration repeatedly acts on the electronic component 83 mounted on the circuit board 75, stress is generated repeatedly on the leads of the capacitor 83a and the choke coil 83b of the electronic component 83, which may reduce the life of the lead. Therefore, in the second modification, the distance between the electronic component 83 in the Y-axis direction and the motor fixing portion 15 can be shortened by arranging at least a part of the electronic component 83 at a position overlapping the motor fixing portion 15. it can. Therefore, an increase in the moment acting on the electronic component 83 can be suppressed, and accordingly, a possibility that the life of the electronic component 83 is reduced can be suppressed.

  Further, for example, as shown in FIG. 4, the electronic component 83 is disposed radially outside the fixing portion 70 b of the inverter portion 70 in the surface portion (front side surface 75 a) of the circuit board 75 facing the motor portion 10 side. Alternatively, it may face the motor unit 10 (Modification 3).

  In this modification, the capacitor 83a and the choke coil 83b are mounted on the front side surface 75a of the circuit board 75 on the rear side of the motor fixing portion 15 at a position radially outward of the fixing portion 73b of the inverter portion 70. Turn to the motor unit 10 side. Since the capacitor 83a and the choke coil 83b are large components, if the capacitor 83a and the choke coil 83b are disposed radially inward of the fixed portion 73b, the capacitor 83a and the choke coil 83b may be in contact with the bolt 74. Therefore, when the capacitor 83a and the choke coil 83b are disposed on the rear side away from the bolt 74, the distance in the Z-axis direction between the capacitor 83a and the choke coil 83b and the motor fixing portion 15 increases, and the capacitor 83a and the choke This causes an increase in the moment acting on the coil 83b. Therefore, the capacitor 83a and the choke coil 83b are mounted at a position radially outward of the fixing portion 73b of the front side surface 75a of the circuit board 75 on the rear side of the motor fixing portion 15 and are directed to the motor portion 10 side. The distance in the Z-axis direction between the electronic component 83 and the motor fixing portion 15 can be shortened. Therefore, an increase in the moment acting on the electronic component 83 can be suppressed.

  In the electronic component 83 of either the capacitor 83a or the choke coil 83b, the end surface 83a1 of the electronic component 83 on the motor unit 10 side may face the motor fixing unit 15 (Modification 4). In the present embodiment, as shown in FIG. 5, the end surface 83a1 of the capacitor 83a on the motor unit 10 side faces the motor fixing unit 15 side. The choke coil 83b is disposed adjacent to the capacitor 83a on the plus side in the Y-axis direction and faces the front side.

  In this modification, by mounting the electronic component 83 having a large size and a heavy weight toward the motor fixing portion 15, the distance from the position where the motor fixing portion 15 is fixed to the pump portion 40 is extended. Instead, since the electronic component 83 can be mounted, an increase in vibration can be further suppressed with respect to the propagation of the vibration to the electronic component 83 of the inverter unit 70 fixed to the motor housing 13.

  Although the preferred embodiments of the present invention have been described above, the present invention is not limited to these embodiments, and various modifications and changes are possible within the scope of the present invention. These embodiments and modifications thereof are included in the scope and the gist of the invention, and at the same time, included in the claims and their equivalents.

DESCRIPTION OF SYMBOLS 1 electric oil pump 10 motor part 11 shaft 13 motor housing 13a outer surface 15 motor fixing part 15a fixing surface part 15b protrusion part 15a1 welding part 20 rotor 22 stator 40 pump part 47 pump rotor 51, 91 pump housing 52 pump body 57, 96 pump Cover 57a Pump cover main body 57b Pump cover arm 65 Pump fixing portion 70 Inverter 75 Circuit board 75a Front side (surface)
83 Electronic parts 83a Condenser 83a1 End face 83b Choke coil 91a Pump body body 91b Pump body arm 94 Housing J Central axis Q Fixed position

Claims (11)

A motor portion having a shaft centered on an axially extending central axis;
A pump unit positioned on one side in the axial direction of the motor unit and driven by the motor unit via the shaft to discharge oil;
Have
The motor unit is
A rotor fixed to the other axial side of the shaft;
A stator located radially outward of the rotor;
A motor housing that accommodates the rotor and the stator;
An inverter unit positioned on the other axial side of the motor housing and fixed to the motor housing;
Have
The pump unit is
A pump rotor attached to the shaft protruding from the motor section in one axial direction;
A pump housing having a housing portion for housing the pump rotor;
Have
The motor housing has a motor fixing portion fixed to the pump portion,
The motor fixing portion is disposed outside the side surface of the motor housing and on the inverter portion side.
The pump housing has a pump fixing portion fixed thereto,
The motor fixing portion is disposed on the motor housing side and the inverter portion side with respect to a fixing position fixed to the pump fixing portion.
Electric oil pump. The electric oil pump according to claim 1, wherein the motor fixing portion has a welding portion fixed to the motor housing by welding. The motor fixing portion is
A fixed surface portion disposed opposite to the outer surface of the motor housing;
And a protrusion protruding from the fixed surface portion,
The electric oil pump according to claim 2, wherein the fixed surface portion has the welded portion at an outer peripheral edge. The pump housing is
With pump body,
A pump cover attached to one axial side of the pump body and having the housing;
Have
The electric oil pump according to claim 1, wherein the motor fixing portion is fixed to the pump cover. The pump housing is
A pump body having the housing;
A pump cover attached to one axial side of the pump body;
Have
The electric oil pump according to claim 1, wherein the motor fixing portion is fixed to the pump body. The pump cover is
A pump cover main body attached to one axial side of the pump body;
A pump cover arm extending from the radial direction one end of the pump cover main body toward the motor unit;
Have
The electric oil pump according to claim 4, wherein a tip end portion of the pump cover arm portion is fixed to the motor fixing portion. The pump body is
A pump body main body attached to one axial side of the motor housing;
A pump body arm extending from the radial one end of the pump body toward the motor;
Have
The electric oil pump according to claim 5, wherein a tip end portion of the pump body arm portion is fixed to the motor fixing portion. The inverter unit has a circuit board extending in a direction intersecting the axial direction,
The circuit board has an electronic component in which a lead is electrically connected to the circuit board,
The motor according to claim 1, wherein the electronic component is disposed at a position where at least a part of the electronic component overlaps the motor fixing portion when the circuit board is viewed from the other side in the axial direction from the other side. Oil pump. The inverter portion has a fixing portion fixed to a bottom portion located on the other side in the axial direction of the motor housing,
The fixing portion is fixed to the bottom portion of the motor housing via a fixing member.
The electric oil according to claim 8, wherein the electronic component is disposed radially outside the fixing portion of the inverter portion in a surface portion facing the motor portion side of the circuit board and faces the motor portion side. pump. The electric oil pump according to claim 8, wherein the electronic component is at least one of a condenser and a choke coil. The electric oil pump according to claim 10, wherein an end face of the electronic part on the motor part side faces the motor fixing part side in any one of the capacitor and the choke coil.

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