JP2016226179A - motor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a motor for suppressing deformation and breakage of a circuit board even when load is applied from a wire connecting section to the circuit board.SOLUTION: A motor includes: a shaft arranged along a center axis extending in a vertical direction; a rotor unit to be rotated together with the shaft; a bracket having a cylindrical unit surrounding an outer peripheral surface of the shaft and a base section located under the cylindrical unit and expanded to the radial outside; a bearing unit; a stator unit; and a circuit board located between the stator unit and the base section in the vertical direction. The circuit board includes a wire connecting section to which an outer wire is connected and first to third fixing sections fixed on the base section, the first to third fixing sections are located on the outside outer than an outer end of the stator unit and on the inside inner than an outer end of a rotor holder in the radial direction, and in a peripheral direction, the first fixing section is located in the vicinity of one edge of the wire connecting section, the second fixing section is located in the vicinity of the other edge of the wire connecting section and the third fixing section is located on one side further than the first fixing section and the other side further than the second fixing section.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a motor.

  Patent Document 1 describes a method for fixing a printed wiring board (circuit board) in a motor.

JP 2013-223394 A

  The circuit board may be provided with a wiring connection portion to which external wiring is connected. There is a possibility that a load is applied in the thickness direction of the circuit board at the wiring connection portion, and the circuit board is deformed and damaged. Further, when the rotation sensor is provided on the circuit board, the deformation of the circuit board may affect the detection accuracy of the rotation sensor.

  One aspect of the present invention is to provide a motor that suppresses deformation and breakage of a circuit board even when a load is applied to the circuit board from a wiring connection portion.

  One aspect of the motor of the present invention has a shaft disposed along a central axis extending in the vertical direction, a cylindrical rotor holder, and a rotor magnet fixed to the inner peripheral surface of the rotor holder, and rotates together with the shaft. A rotor part, a cylindrical part surrounding the outer peripheral surface of the shaft, a bracket located below the cylindrical part and extending radially outward, an inner peripheral surface of the cylindrical part and an outer periphery of the shaft in the radial direction A bearing portion located between the stator portion and the stator portion and the stator portion surrounding the outer peripheral surface of the cylindrical portion; and the central axis located between the stator portion and the base portion in the vertical direction; A circuit board having orthogonal board surfaces, the circuit board comprising: a wiring connection part to which external wiring is connected; a first fixing part fixed to the base part; a second fixing part; A third fixing portion, and in the radial direction, the first fixing portion, the second fixing portion, and the third fixing portion are located outside an outer end of the stator portion and further than an outer end of the rotor holder. In the circumferential direction, the first fixing part is located near one edge of the wiring connection part, the second fixing part is located near the other edge of the wiring connection part, and the third fixing part Is located on one side of the first fixed part and on the other side of the second fixed part.

  According to one aspect of the present invention, there is provided a motor that suppresses deformation and breakage of a circuit board even when a load is applied to the circuit board from a wiring connection portion.

FIG. 1 is a cross-sectional view of the motor according to the first embodiment. FIG. 2 is an exploded view of a part of the motor according to the first embodiment. FIG. 3 is a plan view of the circuit board according to the first embodiment and a bracket for fixing the circuit board. FIG. 4 is a perspective view of the stator portion of the first embodiment and peripheral members assembled with the stator portion. FIG. 5 is a perspective view of the positioning member of the first embodiment. FIG. 6 is a perspective view of the stator portion of the second embodiment and peripheral members assembled with the stator portion.

  Hereinafter, a motor according to an embodiment of the present invention will be described with reference to the drawings. The scope of the present invention is not limited to the following embodiments, and can be arbitrarily changed within the scope of the technical idea of the present invention. Moreover, in the following drawings, in order to make each structure easy to understand, the actual structure may be different from the scale, number, or the like in each structure.

  In the drawings, an XYZ coordinate system is appropriately shown as a three-dimensional orthogonal coordinate system. In the XYZ coordinate system, the Z-axis direction is the vertical direction. The X-axis direction is the left-right direction in FIG. 1 among the directions orthogonal to the Z-axis direction. The Y-axis direction is a direction orthogonal to both the X-axis direction and the Z-axis direction.

  Unless otherwise specified, in the following description, the radial direction centered on the central axis J extending in the vertical direction (Z-axis direction) is simply referred to as “radial direction”, and the circumferential direction centered on the central axis J That is, the circumference of the central axis J is simply referred to as “circumferential direction”. The vertical direction (Z-axis direction) corresponds to the axial direction of the central axis J.

In this specification, “extending in the vertical direction” means not only strictly extending in the vertical direction (Z-axis direction) but also extending in a direction inclined by less than 45 ° with respect to the vertical direction. Including.
Further, in this specification, “extending in the radial direction” means strictly less than 45 ° with respect to the radial direction, in addition to extending in the radial direction, that is, the direction perpendicular to the vertical direction (Z-axis direction). It also includes the case of extending in the direction inclined in the range of.

  FIG. 1 is a cross-sectional view showing a motor 1 of the present embodiment. FIG. 2 is an exploded view of a part of the motor 1. The motor 1 is an outer rotor type brushless motor.

As shown in FIG. 1, the motor 1 includes a shaft 10, a rotor part 20, a bracket 50, an upper bearing part (bearing part) 41, a lower bearing part 42, a stator part 30, and a positioning member 70. The circuit board 60 is provided.
The shaft 10 and the rotor part 20 are fixed to each other and rotate around the central axis J as a unit. Moreover, the bracket 50, the stator part 30, the positioning member 70, and the circuit board 60 are mutually fixed. The bracket 50 is provided with a bearing holding hole 59 that holds the upper bearing portion 41 and the lower bearing portion 42. The bracket 50 supports the shaft 10 via the upper bearing portion 41 and the lower bearing portion 42.
The motor 1 generates a magnetic field in the stator unit 30 when a drive current input from an external device is supplied to the stator unit 30, and rotates the rotor unit 20 and the shaft 10 around the central axis J by the magnetic field.
Hereinafter, each component will be described in detail.

[shaft]
As shown in FIG. 1, the shaft 10 is a columnar shaft disposed along a central axis J that extends in the vertical direction (Z-axis direction). The center of the shaft 10 coincides with the central axis J. The shaft 10 is rotatably supported by the bracket 50 via the upper bearing portion 41 and the lower bearing portion 42.

[Rotor part]
The rotor unit 20 is fixed to the shaft 10 and rotates around the central axis J together with the shaft 10. The rotor unit 20 includes a cylindrical rotor holder 24, a rotor magnet 25 fixed to the inner peripheral surface 24 c of the rotor holder 24, and a rotor hub 26.

  The rotor holder 24 includes a cylindrical tube portion 24a extending in the vertical direction and a top plate portion 24b extending radially inward from the upper end of the tube portion 24a. A central hole 24d penetrating in the vertical direction is provided at the center of the top plate portion 24b.

  The rotor magnet 25 is bonded and fixed to the inner peripheral surface 24c of the cylinder portion 24a and is held by the rotor holder 24. The rotor magnet 25 is a permanent magnet that arranges different magnetic poles in the circumferential direction of the rotor holder 24.

The rotor hub 26 connects the central hole 24d of the top plate portion 24b (that is, the radially inner end of the rotor holder 24) and the shaft 10.
The rotor hub 26 includes a cylindrical shaft holding portion 26a, a flange portion 26b extending radially outward from the outer periphery of the shaft holding portion 26a, and a hub caulking portion 26c formed by deformation by caulking.
The shaft 10 is press-fitted into the shaft holding portion 26a. The lower end in the axial direction of the shaft holding portion 26 a (that is, the lower end in the axial direction of the rotor hub 26) is located on the lower side in the axial direction than the upper end of the core back 32 of the stator portion 30. By extending the rotor hub 26 to the lower side in the axial direction than the upper end of the core back 32, the fastening length between the rotor hub 26 and the shaft 10 can be increased. Thereby, the rotor hub 26 and the shaft 10 can be firmly fastened.
The upper surface of the flange portion 26 b is in contact with the lower surface of the top plate portion 24 b of the rotor holder 24. The hub caulking portion 26c is molded outward in the radial direction and contacts the upper surface of the top plate portion 24b. The flange portion 26b and the hub caulking portion 26c sandwich the top plate portion 24b up and down to fix the rotor hub 26 and the rotor holder 24.

[bracket]
As shown in FIGS. 1 and 2, the bracket 50 includes an upper cylindrical portion (cylindrical portion) 51, a lower cylindrical portion 52, and a base portion 53 that extends radially outward from the outer peripheral surface of the lower cylindrical portion 52. Have.
The upper cylindrical portion 51 and the lower cylindrical portion 52 have a cylindrical shape extending along the central axis J. The upper cylinder portion 51 and the lower cylinder portion 52 surround the outer peripheral surface of the shaft 10. The lower cylinder part 52 has an outer diameter larger than that of the upper cylinder part 51 and is located below the upper cylinder part 51. A first surface 52a is provided at the boundary between the upper cylindrical portion 51 and the lower cylindrical portion 52 as a step surface facing upward. That is, the bracket 50 has a first surface 52 a that spreads radially outward from the lower end of the upper cylindrical portion 51.

As shown in FIG. 1, the inner peripheral surface of the upper cylindrical portion 51 and the inner peripheral surface of the lower cylindrical portion 52 communicate with each other to form a bearing holding hole 59 that penetrates in the vertical direction. In the middle of the bearing holding hole 59 in the vertical direction, an inner projecting portion 59a that projects inward in the radial direction and narrows the inner diameter is provided.
In the bearing holding hole 59, the upper bearing portion 41 is inserted above the inner protruding portion 59a. A wave washer (not shown) is inserted into the gap in the vertical direction between the inner projecting portion 59a and the upper bearing portion 41 to apply preload to the upper bearing portion 41.
In the bearing holding hole 59, the lower bearing portion 42 is bonded and fixed to the lower side of the inner protruding portion 59a. In the assembly process, the lower bearing portion 42 is inserted into the bearing holding hole 59 after an adhesive is applied to the inner peripheral surface of the bearing holding hole 59. The lower surface 59b of the inner protrusion 59a is in contact with the upper surface of the outer ring of the lower bearing portion 42.

As shown in FIG. 1, the base portion 53 is located below the upper cylindrical portion 51 and extends radially outward from the outer peripheral surface of the lower cylindrical portion 52.
As shown in FIG. 2, the base part 53 has a flat plate part 53a, an edge part 53b, three first pedestal parts 53d, three second pedestal parts 53c, and three ribs 53f.

The flat plate portion 53a is a circular plate as viewed in the up-down direction. The plate surface of the flat plate portion 53a is orthogonal to the central axis J.
The edge part 53b protrudes upward from the periphery of the flat plate part 53a.

  As shown in FIG. 2, the three first pedestal portions 53d protrude upward from the flat plate portion 53a. Further, the three first pedestal portions 53d each have a shape projecting radially outward from the outer peripheral surface of the lower cylindrical portion 52. The three first pedestals 53d are respectively arranged at positions that are rotationally symmetric with respect to the central axis J. First holes 54 are provided in the upper surfaces of the three first pedestals 53d. That is, the base portion 53 has a first hole 54. The first hole 54 extends downward from the upper surface of the first pedestal 53d. A lower protrusion 72 of a positioning member 70 described later is inserted into the first hole 54.

  As shown in FIG. 2, the three second pedestals 53 c protrude upward from the flat plate 53 a. Each of the three second pedestals 53c has a shape projecting radially inward from the inner surface of the edge 53b. The second pedestal portion 53c is located on the radially outer side than the first pedestal portion 53d. The upper end in the axial direction of the second pedestal 53c coincides with the upper end in the axial direction of the edge 53b, and constitutes a second surface 53e on which the circuit board 60 is mounted. The three second pedestal portions 53c are provided with boss portions 56a, 57a, 58a extending upward. By mounting the circuit board 60 on the second surface 53e, the boss portions 56a, 57a, and 58a are inserted into the three fixing holes 66 provided in the circuit board 60, respectively. Further, the boss portions 56a, 57a, 58a form a first fixing portion 56, a second fixing portion 57, and a third fixing portion 58 by caulking, and fix the circuit board 60 to the second surface 53e (see FIG. 3). . That is, the second pedestal portion 53 c overlaps with the first fixing portion 56, the second fixing portion 57, and the third fixing portion 58 and is fixed to the circuit board 60 when viewed from the vertical direction. At this time, the lower surface of the circuit board 60 contacts the second surface 53e which is the upper end of the second pedestal portion 53c.

  As shown in FIG. 2, the second pedestal portion 53c is provided with a base hole 53g penetrating in the vertical direction from the second surface 53e. As will be described later, rotation sensors 63a, 63b, and 63c are mounted on the upper surface (substrate surface 62a) of the circuit board 60. The base hole 53g is provided at a position overlapping the rotation sensors 63a, 63b, and 63c when viewed from the axial direction. For this reason, the lower surface of the circuit board 60 is in contact with the second pedestal portion 53c in a region surrounding the rotation sensors 63a, 63b, and 63c when viewed in the vertical direction. The second pedestal 53c can stably support the rotation sensors 63a, 63b, and 63c from the lower surface side of the circuit board 60, and maintains the detection accuracy of the rotation sensors 63a, 63b, and 63c.

  As described above, the circuit board 60 is fixed to the base portion 53 on the second surface 53e of the second pedestal portion 53c. Therefore, as shown in FIG. 1, a space B is provided between the lower surface of the substrate body 62 and the flat plate portion 53a as a gap in the vertical direction. A coil wire 35 a is fixed to the lower surface of the substrate body 62 by soldering. By providing the space B, the vertical dimension for solder can be sufficiently secured. A mounting component having a relatively large height such as a capacitor or an inverter may be mounted on the lower surface of the board body 62. In this case, the space B ensures the vertical dimension of these mounted components.

  As shown in FIG. 2, the rib 53f protrudes upward from the flat plate portion 53a. The three ribs 53f extend radially from the outer peripheral surface of the lower cylindrical portion 52 toward the second pedestal portion 53c, and connect the lower cylindrical portion 52 and the second pedestal portion 53c. The rib 53f can increase the strength of the base portion 53. Particularly, the rib 53f connects the lower cylindrical portion 52 and the second pedestal portion 53c, thereby effectively deforming the base portion 53 such that the second surface 53e of the second pedestal portion 53c moves in the vertical direction. Can be suppressed. Thereby, the base part 53 can maintain the detection accuracy of the rotation sensors 63a, 63b, and 63c mounted on the circuit board 60 on the second pedestal part 53c.

[Upper bearing and lower bearing]
The upper bearing portion 41 and the lower bearing portion 42 rotatably support the shaft 10 with respect to the bracket 50. As shown in FIG. 1, the upper bearing portion 41 is located between the inner peripheral surface of the upper cylindrical portion 51 and the outer peripheral surface of the shaft 10 in the radial direction. Similarly, the lower bearing portion 42 is located between the inner peripheral surface of the lower cylindrical portion 52 and the outer peripheral surface of the shaft 10 in the radial direction. The shaft 10 is press-fitted into the inner rings of the upper bearing portion 41 and the lower bearing portion 42. The outer ring of the upper bearing portion 41 is fitted into the bearing holding hole 59 by a clearance fit, and preload is applied to the upper side by a wave washer (not shown). Further, the outer ring of the lower bearing portion 42 is bonded and fixed to the bearing holding hole 59.

[Circuit board]
The circuit board 60 constitutes a motor drive circuit by mounting various electronic components. As shown in FIG. 1, the circuit board 60 has a board surface 62 a orthogonal to the central axis J. The circuit board 60 is located between the stator part 30 and the base part 53 of the bracket 50 in the vertical direction.

  FIG. 3 is a plan view of the circuit board 60 and the bracket 50 for fixing the circuit board 60. As shown in FIG. 3, the circuit board 60 includes a board body 62, a wiring connection part 65 provided on the board surface 62 a of the board body 62, three rotation sensors 63 a, 63 b, 63 c, and a first fixing part 56, A second fixing portion 57 and a third fixing portion 58 are provided.

The substrate body 62 includes a circular portion 62b having a circular shape when viewed from the top and bottom, and a rectangular portion 62c extending in a rectangular shape radially outward from a part of the circular portion 62b.
A central hole 69 is provided in the center of the circular portion 62 b of the substrate body 62. The lower cylindrical portion 52 is inserted into the central hole 69. The center hole 69 is provided with three through holes 61 as notches extending outward in the radial direction. The through hole 61 penetrates in the vertical direction. Further, the through hole 61 overlaps the first hole 54 provided in the base portion 53 of the bracket 50 when viewed from the vertical direction. A lower protrusion 72 of a positioning member 70, which will be described later, is inserted into the through hole 61.

  The substrate main body 62 is provided with six coil wire through holes 68 arranged around the central hole 69 and penetrating in the axial direction. A coil wire 35 a extending from the coil 35 of the stator portion 30 is inserted into the coil wire through hole 68. The coil wire 35a is guided to the lower surface of the substrate body 62 and fixed by soldering.

  The substrate body 62 is provided with three fixing holes 66 penetrating in the vertical direction in the vicinity of the peripheral edge. The three fixing holes 66 constitute the first fixing portion 56, the second fixing portion 57, and the third fixing portion 58 by inserting and crimping the boss portions 56 a, 57 a, 58 a of the base portion 53. In addition, although the 1st fixing | fixed part 56 of this embodiment, the 2nd fixing | fixed part 57, and the 3rd fixing | fixed part 58 are caulking parts, the fixing | fixed part by other fixing means, such as screw fixation, may be sufficient.

  A wiring connection portion 65 is provided in the rectangular portion 62 c of the substrate body 62. The wiring connection portion 65 has a width in the circumferential direction. A plurality of external wires 9 are soldered and connected to the wiring connection portion 65. An external device is connected to the circuit board 60 via the external wiring 9, and power and control signals are supplied from the external device.

  The rotation sensors 63a, 63b, and 63c are attached to the substrate surface 62a that is the upper surface of the substrate body 62. The rotation sensor 63a is located immediately below the rotor magnet 25 and faces the rotor magnet 25 in the vertical direction. The three rotation sensors 63a, 63b, and 63c are arranged side by side at equal intervals along the circumferential direction (that is, 120 ° intervals with the central axis J as the center). With this configuration, the accuracy of the three rotation sensors 63a, 63b, and 63c can be maintained. The circumferential angles of the three rotation sensors 63a, 63b, and 63c do not necessarily have to be equal to each other, but it is preferable that at least two circumferential angles are equal. For example, it is preferable that the circumferential angle between the rotation sensor 63a and the rotation sensor 63b is equal to the circumferential angle between the rotation sensor 63b and the rotation sensor 63c. The rotation sensors 63a, 63b, and 63c are, for example, hall elements.

  The circuit board 60 is fixed to the base portion 53 by the first fixing portion 56, the second fixing portion 57, and the third fixing portion 58. The first fixing portion 56, the second fixing portion 57, and the third fixing portion 58 are positioned outside the outer end (outer end surface 31 a) of the stator portion 30 and inside the outer end 24 e of the rotor holder 24 in the radial direction. To do.

  By disposing the first fixing portion 56, the second fixing portion 57, and the third fixing portion 58 outside the outer end (outer end surface 31a) of the stator portion 30, the inner region serves as a wiring pattern region of the substrate surface 62a. Widely secured. In addition, in the assembling process, after the stator part 30 is assembled to the bracket 50, the caulking process for forming the first fixing part 56, the second fixing part 57, and the third fixing part 58 can be performed. For this reason, it is easy to simplify the assembly process.

  Further, by arranging the first fixing portion 56, the second fixing portion 57, and the third fixing portion 58 inside the outer end 24e of the rotor holder 24, the radial dimension of the circular portion 62b of the substrate body 62 can be reduced. This can contribute to the miniaturization of the motor 1.

  Further, the first fixing portion 56, the second fixing portion 57, and the third fixing portion 58 are disposed outside the outer end surface 31 a of the stator portion 30 and inside the outer end 24 e of the rotor holder 24. It is arranged in the immediate vicinity of 25. Accordingly, the rotation sensors 63a, 63b, and 63c are arranged on the virtual circle VC that passes through the first fixed portion 56, the second fixed portion 57, and the third fixed portion 58. The substrate body 62 is pressed against the second surface 53e of the base portion 53 by the first fixing portion 56, the second fixing portion 57, and the third fixing portion 58, so that the first fixing portion 56, the second fixing portion 57, and The height accuracy of the substrate surface 62a is likely to be stable on the virtual circle VC through which the third fixing portion 58 passes. By arranging the rotation sensors 63a, 63b, and 63c on the virtual circle VC, the accuracy of the rotation sensors 63a, 63b, and 63c can be maintained.

Different rotation sensors 63a, 63b, and 63c are located in the vicinity of the first fixing portion 56, the second fixing portion 57, and the third fixing portion 58 in the circumferential direction. In the vicinity of the first fixing portion 56, the second fixing portion 57, and the third fixing portion 58, the substrate body 62 is pressed against the second surface 53e of the base portion 53, and the height accuracy of the substrate surface 62a is stabilized. The accuracy of the rotation sensors 63a, 63b, and 63c can be maintained.
Of the three rotation sensors 63 a, 63 b, 63 c, one (at least one) is in any one of the circumferential directions of the first fixed portion 56, the second fixed portion 57, and the third fixed portion 58. It may be located near the direction. The three rotation sensors 63a, 63b, and 63c measure the rotation by mutually complementing the detection results. Since at least one of the three rotation sensors 63a, 63b, and 63c is positioned in the vicinity of any one of the first fixing portion 56, the second fixing portion 57, and the third fixing portion 58, the rotation sensors 63a, 63b, There is a certain effect of increasing the accuracy of the detection result of 63c.
In this specification, the rotation sensor 63a, 63b, 63c and the first fixing portion 56, the second fixing portion 57 and the third fixing portion 58 and the “neighboring” with respect to the circumferential position means that the other circumferential position relative to one is It means that it is provided in a range of 15 ° or less around the central axis J.

The first fixing portion 56 is located in the vicinity of the one edge 65 a that is the edge on one side of the wiring connection portion 65 in the circumferential direction. The second fixing portion 57 is located in the vicinity of the other edge 65 b that is the other edge of the wiring connection portion 65 in the circumferential direction. Thereby, even if a load is applied from the wiring connection portion 65 in the thickness direction of the substrate body 62, deformation and breakage of the substrate body 62 can be suppressed. The one side in the circumferential direction means the side in the left rotation direction in FIG. 3, and the other side in the circumferential direction means the side in the right rotation direction in FIG.
In this specification, the “neighboring” regarding the circumferential position of the first fixing portion 56 or the second fixing portion 57 and the one edge 65a or the other edge 65b of the wiring connection portion 65 is the other circumferential position relative to one. It means that it is provided in a range of 30 ° or less around the central axis J.

  In the circumferential direction, the third fixing portion 58 is the first on the one side (the left rotation direction in FIG. 3) from the first fixing portion 56 and the other side (the right rotation direction in FIG. 3) from the second fixing portion 57. Located in area A1. As shown in FIG. 3, the first straight line L1 connecting the first fixed portion 56 and the central axis J to the substrate surface 62a of the substrate body 62 and the second straight line L2 connecting the second fixed portion 57 and the central axis J. Is assumed. 1st area | region A1 is an area | region which does not contain the wiring connection part 65 among the two area | regions divided by the 1st straight line L1 and the 2nd straight line L2. The third fixing portion 58 provided in the first region A1 is sufficiently separated from the wiring connection portion 65 and fixes the substrate body 62 together with the first fixing portion 56 and the second fixing portion 57 in a balanced manner.

  Moreover, it is preferable that the 3rd fixing | fixed part 58 is located in 2nd area | region A2 on the opposite side of the wiring connection part 65 with respect to the central axis J seeing from an up-down direction. As shown in FIG. 3, a third straight line L <b> 3 is assumed on the substrate surface 62 a of the substrate body 62. The third straight line L3 is a straight line that passes through the central axis J and is parallel to a straight line that connects the one edge 65a and the other edge 65b in the circumferential direction of the wiring connection portion 65. The second region A2 is a region that does not include the wiring connection portion 65, out of the two regions on the substrate surface 62a defined by the third straight line L3. By providing the third fixing portion 58 in the second region A2, each fixing portion can be arranged in a balanced manner with respect to the central axis J. Therefore, the first fixing portion 56, the second fixing portion 57, and the third fixing portion 58 can fix the substrate body 62 to the base portion 53 without applying an excessive load to the substrate body 62. Therefore, even if the 1st fixing | fixed part 56, the 2nd fixing | fixed part 57, and the 3rd fixing | fixed part 58 are the cases where the board | substrate body 62 with thin plate | board thickness is used, the damage of the board | substrate body 62 accompanying fixation can be suppressed.

[Stator part]
As shown in FIG. 1, the stator part 30 surrounds the outer peripheral surface 51b of the upper side cylinder part 51 from radial direction. The stator unit 30 has a stator core 34 and a coil 35. Further, the stator part 30 has an insulating part 39 located between the stator core 34 and the coil 35.

  The stator core 34 has an annular core back 32 and twelve teeth 31 extending outward in the radial direction of the core back 32. A coil wire 35 a is wound around each of the 12 teeth 31 to form a coil 35.

FIG. 4 shows a perspective view of the stator portion 30, the bracket 50 to which the stator portion 30 is assembled, and peripheral members. In FIG. 4, the coil 35 is not shown.
As shown in FIG. 5, the inner peripheral surface 32 a of the core back 32 is provided with three convex portions 33 that protrude radially inward. Each convex part 33 is arrange | positioned at the circumferential direction equal intervals.

  The radially inner end 33c of the convex portion 33 has an arc shape along the outer peripheral surface 51b of the upper cylindrical portion 51 when viewed from the vertical direction. The radially inner end 33 c of the convex portion 33 is in contact with the outer peripheral surface 51 b of the upper cylindrical portion 51. Thereby, the radial position of the stator core 34 with respect to the bracket 50 is determined.

  As shown in FIG. 1, the lower surface 33 a of the convex portion 33 is in contact with a first surface 52 a located between the upper cylindrical portion 51 and the lower cylindrical portion 52. Further, a crimped portion 51 a that contacts the upper surface 33 b of the convex portion 33 is provided at the upper end of the upper cylindrical portion 51, and the stator core 34 is fixed to the bracket 50. The height direction position of the stator core 34 with respect to the bracket 50 is determined by the lower surface 33a of the convex portion 33 coming into contact with the first surface 52a.

  The convex portion 33 is provided with a second hole 36 penetrating in the vertical direction. That is, the stator core 34 has a second hole 36. As shown in FIG. 1, an upper projection 71 of a positioning member 70 described later is inserted into the second hole 36. As a result, the circumferential position of the stator core 34 with respect to the bracket 50 is determined. The convex portion 33 hardly generates a magnetic path when the coil 35 is energized. For this reason, by providing the second hole 36 in the convex portion 33, the influence on the output can be reduced, and the stator core 34 can be positioned in the circumferential direction. The second hole 36 may be a through hole. In the present embodiment, as shown in FIG. 2, the second hole 36 is a through hole.

According to the present embodiment, the provision of the convex portion 33 facilitates the common use of components of the upper bearing portion 41, the lower bearing portion 42, and the bracket 50. In general, in motor design, the outer diameter and inner diameter of the upper cylinder part are designed according to the inner diameter of the core back according to the required output, and the bearing part is selected according to the inner diameter of the upper cylinder part. It was. For this reason, it is necessary to prepare different brackets and bearings for each motor. On the other hand, according to the present embodiment, by providing the convex portion 33 on the inner peripheral surface 32a of the core back 32, the upper bearing portion 41, the lower bearing portion 42, and the bracket 50 can be made variously with different inner diameters of the core back 32. Can be used in common in motors with various outputs Thereby, the cost of the motor 1 can be reduced.
Further, the provision of the convex portion 33 on the inner peripheral surface 32 a of the core back 32 means that the lightening has been performed as compared with the case where the entire inner peripheral surface of the core back 32 is in contact with the upper cylindrical portion 51. means. Therefore, by providing the convex portion 33, the motor 1 can be reduced in weight.

  In the present embodiment, three convex portions 33 are provided at equal intervals in the circumferential direction. For this reason, since the motor 1 is provided with three contact points between the convex portion 33 and the upper cylindrical portion 51 of the bracket 50 at equal intervals in the circumferential direction, the radial positioning of the stator core 34 with respect to the bracket 50 is stabilized. In addition, the motor 1 can reduce the weight as compared with a motor provided with four or more convex portions 33. However, three convex portions 33 are not necessarily provided, and four or more convex portions 33 may be provided. In particular, when the number of the convex portions 33 is preferable for reducing the vibration of the motor 1, four or more convex portions 33 may be provided. For example, in the present embodiment, the stator core 34 has twelve slots, and the rotor magnet 25 has fourteen magnetic poles, so that the protrusions are relatively prime to the number of slots and the number of magnetic poles. The number may be 5 or 11 or the like. With this configuration, it is possible to prevent the plurality of convex portions 33 from resonating with the slots of the stator core 34 and the magnetic poles of the rotor magnet 25.

As shown in FIG. 4, the stator core 34 has two core portions (an upper core portion 34 </ b> A and a lower core portion 34 </ b> B) that are stacked in the axial direction and fixed to each other. The convex portion 33 is provided on at least one of the upper core portion 34A and the lower core portion 34B. The convex portion 33 is provided only on the lower core portion 34B, and is not provided on the upper core portion 34A. The upper core portion 34A has the same shape as the lower core portion 34B, except that the upper core portion 34A does not have the convex portion 33.
Since the convex portion 33 is provided on at least one of the upper core portion 34 </ b> A and the lower core portion 34 </ b> B, the axial length of the convex portion 33 is shorter than the axial length of the core back 32. Although a magnetic path is generated in the core back 32 when the coil 35 is energized, a magnetic path is hardly generated in the convex portion 33, and even if the axial length is shortened, the influence on the output is small. For this reason, since the axial direction length of the convex part 33 is short, it can contribute to the weight reduction of the motor 1 without affecting an output.
Further, as shown in FIG. 1, since the convex portion 33 is provided only on the lower core portion 34 </ b> B, the upper end of the convex portion 33 is positioned below the upper end of the core back 32 in the axial direction. Therefore, the axial position of the caulking portion 51a of the upper cylindrical portion 51 is disposed below the upper end of the core back 32, and the axial length of the upper cylindrical portion 51 is shortened, thereby contributing to the weight reduction of the motor 1. . In addition, in the upper region of the upper cylindrical portion 51, the lower end in the axial direction of the rotor hub 26 can be extended downward, and the fastening length between the rotor hub 26 and the shaft 10 can be increased.
In the present embodiment, the stator core 34 is exemplified as having two core parts (the upper core part 34A and the lower core part 34B), but may have three or more core parts. When the stator core 34 has three or more core parts, the convex part 33 should just be provided in at least one of the core parts. In this case, it is preferable that the core part laminated at the bottom has the convex part 33.

As shown in FIG. 4 with emphasis by a dot pattern, the insulating portion 39 is provided on the outer surface of the stator core 34. The insulating part 39 is located between the stator core 34 and the coil 35. Therefore, the insulating portion 39 ensures insulation between the stator core 34 and the coil 35. The insulating portion 39 of the present embodiment is a powder coating applied to the outer surface of the stator core 34. The insulating portion 39 is applied and fixed in a state where the outer end surface 31a in the radial direction of the tooth 31 and the inner peripheral surface 32a and the convex portion 33 of the core back 32 are masked. Therefore, the outer end surface 31a of the tooth 31, the inner peripheral surface 32a of the core back 32, and the outer surface of the convex portion 33 are not covered with the insulating portion 39, and the metal surface is exposed. As shown in FIG. 1, the outer end surface 31 a of the tooth 31 faces the rotor magnet 25 of the rotor unit 20 through a minute gap. By not providing the insulating portion 39 on the outer end surface 31a, interference between the outer end surface 31a and the rotor magnet 25 can be suppressed. Further, as shown in FIG. 1, the lower surface 33 a of the convex portion 33 is in contact with the first surface 52 a of the bracket 50 and determines the position of the stator core 34 in the axial direction with respect to the bracket 50. Similarly, the radially inner end 33 c of the convex portion 33 is in contact with the outer peripheral surface 51 b of the upper cylindrical portion 51 and determines the radial position of the stator core 34 with respect to the bracket 50. The metal surface is exposed without providing the insulating portion 39 on the outer surface of the convex portion 33. That is, the metal surface is exposed at the radially inner end of the convex portion 33. With this configuration, the positioning accuracy of the stator core 34 in the vertical direction and the radial direction can be increased.
The stator portion 30 may have an insulator made of a resin material instead of the insulating portion 39. Even in this case, it is preferable that the insulator does not cover the radially inner end 33 c of the convex portion 33 of the stator core 34 and the lower surface 33 a of the convex portion 33.

[Positioning member]
As shown in FIG. 1, the positioning member 70 is positioned between the stator portion 30 and the circuit board 60 in the up-down direction. The positioning member 70 positions the stator core 34, the circuit board 60, and the bracket 50 in the circumferential direction.

  FIG. 5 is a perspective view of the positioning member 70. The positioning member 70 includes an annular main body 73 that surrounds the central axis J, a plate-like portion 74 that extends radially outward from the outer peripheral surface of the main body 73, three upper protrusions 71, and three lower protrusions 72. Have.

  The upper protrusion 71 extends upward from the upper surface of the main body 73. The upper protrusion 71 is inserted into the second hole 36 of the stator core 34. The upper protrusion 71 is fitted into the second hole 36 to limit relative movement of the positioning member 70 and the stator core 34 in the circumferential direction.

  The lower protrusion 72 extends downward from the lower surface of the main body 73. The lower protrusion 72 is inserted into the through hole 61 of the circuit board 60 and the first hole 54 of the base portion 53. The lower protrusion 72 passes through the through hole 61 of the circuit board 60 and is inserted into the first hole 54 of the base portion 53. The lower protrusion 72 is inserted into the through hole 61 as a notch extending in the radial direction, thereby restricting relative movement of the positioning member 70 and the circuit board 60 in the circumferential direction. Similarly, the lower protrusion 72 is fitted in the first hole 54 and restricts the relative movement of the positioning member 70 and the bracket 50 in the circumferential direction.

  The lower protrusion 72 of the present embodiment passes through the through hole 61 of the circuit board 60 and is inserted into the first hole 54 of the base portion 53. Thereby, compared with the case where the through-hole 61 of the circuit board 60 and the 1st hole 54 of the base part 53 are fixed by a separate lower protrusion, the positioning member 70 is comprised simply and the circuit board 60 and the base The part 53 can be positioned in the circumferential direction.

  The three upper protrusions 71 are arranged at equal intervals along the circumferential direction around the central axis J (that is, at intervals of 120 ° with the central axis J as the center). Similarly, the three lower protrusions 72 are arranged at equal intervals along a circumferential circumferential direction centering on the central axis J. Although the circumferential direction positions of the upper protrusion 71 and the lower protrusion 72 in the present embodiment match each other, they do not necessarily have to match.

  As shown in FIG. 1, the upper protrusion 71 of the present embodiment is located on the radially inner side with respect to the lower protrusion 72. That is, the upper protrusion 71 is arranged close to the radial inner side. The second hole 36 into which the upper protrusion 71 is inserted is desirably arranged close to the radially inner side of the core back 32 in order to reduce the influence on the magnetic path. The influence of the second hole 36 on the output of the motor 1 can be reduced by arranging the second hole 36 together with the upper protrusion 71 in the radial direction.

  As shown in FIG. 5, the upper protrusion 71 of this embodiment has a cylindrical shape, and the second hole 36 has a circular shape that matches the cross-sectional shape of the upper protrusion 71. Similarly, in the present embodiment, the lower protrusion 72 has a cylindrical shape, and the first hole 54 has a circular shape that matches the cross-sectional shape of the lower protrusion 72. Further, the through hole 61 is a notch that surrounds the lower protrusion 72 from three directions. However, the shapes of the upper protrusion 71 and the lower protrusion 72, the first hole 54, the second hole 36, and the through hole 61 are not limited to the present embodiment. These are only required to limit the relative movement in the circumferential direction. For example, the first hole 54 and the second hole 36 may be long holes extending in the radial direction.

  The positioning member 70 preferably has three or more upper protrusions 71. The stator core 34 is preferably provided with three or more second holes 36 into which the upper protrusions 71 are respectively inserted. Similarly, the positioning member 70 preferably has three or more lower protrusions 72. In addition, it is preferable that three or more through holes 61 are provided in the circuit board 60, and three or more first holes 54 are provided in the base portion 53, and the lower protrusions 72 are respectively inserted therein. With this configuration, it is possible to achieve stable positioning in the circumferential direction around the central axis J at three or more points.

  The plate-like portion 74 is a flange provided on the entire circumference of the outer peripheral surface of the main body portion 73. The plate-like portion 74 has six notches (coil wire support portions) 75 provided at intervals in the circumferential direction. That is, the positioning member 70 has a plurality of notches (coil wire support portions) 75 positioned on the outer peripheral surface of the main body portion 73. The notches 75 are arranged at equal intervals in the circumferential direction with respect to the central axis J. The notch 75 opens toward the outer side in the radial direction on the outer peripheral edge of the plate-like portion 74. The notch 75 has a saddle shape when viewed from above and below. The notch 75 has a radial portion 75a extending radially inward from the outer peripheral edge of the plate-like portion 74, and a circumferential portion 75b extending from the inner end of the radial portion 75a to one side in the circumferential direction. Further, the circumferential portion 75b is provided with a retaining protrusion 75c that narrows the width of the notch to be equal to or smaller than the wire diameter of the coil wire 35a when viewed in the vertical direction. That is, the notch 75 has a retaining protrusion 75c.

  The notch 75 supports a coil wire 35 a extending from the coil 35 of the stator unit 30 to the circuit board 60. Since the cutout 75 supports the coil wire 35a, the plurality of coil wires 35a can be easily routed in the assembly process.

  In the assembly process, the coil wire 35a is inserted into the radial portion 75a of the notch 75 from the outer peripheral side of the plate-like portion 74, and is further guided to the circumferential portion 75b. When the coil wire 35 a is guided to the circumferential portion 75 b, the coil wire 35 a gets over the retaining protrusion 75 c and is supported inside the notch 75. By providing the retaining protrusion 75 c, the coil wire 35 a can be hardly detached from the inside of the notch 75.

  The circumferential portion 75b of the notch 75 is provided at a position overlapping the coil wire through hole 68 provided in the substrate body 62 in plan view. The coil wire 35 a extending downward from the coil 35 is supported by the notch 75, passes through the coil wire through hole 68, and is fixed by soldering on the lower surface of the circuit board 60. Since the circumferential portion 75 b overlaps the coil wire through hole 68, the coil wire 35 a supported by the circumferential portion 75 b of the notch 75 extends linearly downward and is inserted into the coil wire through hole 68. Therefore, the slack of the coil wire 35a supported by the notch 75 can be suppressed.

  The positioning member 70 of the present embodiment is provided with a notch 75 as a coil wire support portion. However, the coil wire support portion is not limited to the notch 75 as long as it can support the coil wire 35a. For example, as the coil wire support portion, a claw that protrudes radially outward from the outer peripheral surface of the main body portion 73 and grips the coil wire 35a may be provided.

  As shown in FIG. 5, the axial length of the plate-like portion 74 is shorter than the axial length of the main body portion 73. Further, as shown in FIG. 1, the axial distance D1 between the plate-like portion 74 and the stator core 34 is longer than the axial distance D2 between the plate-like portion 74 and the circuit board 60. Thereby, the distance of the stator core 34 and the plate-shaped part 74 is ensured, and the ease of the operation | work which inserts the coil wire 35a in the notch 75 of the plate-shaped part 74 can be improved. Moreover, it can reduce that the coil 35 and the plate-shaped part 74 contact. In addition, the distance between the plate-like portion 74 and the circuit board 60 is reduced, and the coil wire 35a can be easily drawn from the notch 75 to the circuit board 60 without slack. Thereby, the ease of the soldering operation | work of the coil wire 35a to the circuit board 60 increases.

[Assembly procedure]
An example of the assembly procedure of the motor 1 of this embodiment will be described with reference to FIG.
First, the upper core portion 34A and the lower core portion 34B are stacked in the vertical direction, and fixed to each other by welding or the like to produce the stator core 34.
Next, powder coating is applied to the outer surface of the stator core 34 to form an insulating portion 39.
Next, the stator wire 30 is formed by winding the coil wire 35 a around the teeth 31 of the stator core 34 to form the stator portion 30.

  Next, the positioning member 70 is attached to the stator unit 30. Specifically, the upper protrusion 71 of the positioning member 70 is inserted into the second hole 36 of the stator core 34, and the coil wire 35a is inserted into the notch 75 of the positioning member 70 as shown in FIG.

  Next, the lower protrusion 72 of the positioning member 70 is inserted into the through hole 61 of the circuit board 60. Further, the tip end of the coil wire 35a is inserted into the coil wire through hole 68 (see FIG. 2) of the substrate body 62 and soldered on the lower surface of the substrate. At this time, since the coil wire 35a is supported by the notch 75, the coil wire 35a can be easily inserted into the coil wire through hole 68.

  Next, the bracket 50 is assembled. The upper cylindrical portion 51 of the bracket 50 is inserted into the stator portion 30. At this time, the outer peripheral surface 51 b of the upper cylindrical portion 51 is brought into contact with the radially inner end 33 c of the convex portion 33, and the lower surface 33 a of the convex portion 33 is brought into contact with the first surface 52 a of the bracket 50. At the same time, the lower protrusion 72 of the positioning member 70 is inserted into the first hole 54 of the base portion 53. In addition, at the same time, the boss portions 56a, 57a, 58a of the bracket 50 shown in FIG. 2 are inserted into the fixing holes 66 of the substrate body.

  Next, the tip of the upper cylindrical portion 51 of the bracket 50 is crimped to form a crimped portion 51a, and the bracket 50 and the stator portion 30 are fixed. The lower bearing portion 42 is assembled to the bracket 50 in advance.

Next, the front ends of the boss portions 56 a, 57 a, and 58 a of the bracket 50 are crimped to form the first fixing portion 56, the second fixing portion 57, and the third fixing portion 58. The boss portions 56a, 57a, 58a are disposed on the outer side of the outer end (outer end surface 31a) of the stator portion 30 when viewed in the vertical direction. For this reason, the caulking process can be easily performed by applying the caulking tool to the boss portions 56a, 57a, 58a from above. The bracket 50 and the circuit board 60 are fixed by forming the first fixing portion 56, the second fixing portion 57, and the third fixing portion 58 by caulking.
Through the above-described procedure, a half assembly on the stator side is produced.

On the other hand, a semi-assembled product on the rotor side is produced. An unmagnetized rotor magnet 25 is bonded and fixed to the rotor holder 24.
Next, the rotor hub 26 is assembled to the rotor holder 24 and fixed by caulking, and the shaft 10 is press-fitted into the rotor hub 26.
Next, the rotor magnet 25 is magnetized.
Next, the upper bearing portion 41 is press-fitted into the shaft 10.
The semi-assembled product on the rotor part side is manufactured through the above procedure.

Next, the rotor assembly side half assembly is assembled to the stator assembly side assembly. This assembly process is performed by press-fitting the shaft 10 into the lower bearing portion 42.
The assembly of the motor 1 is completed through the above procedure.

[Modification 1]
Next, a stator portion 130 of Modification 1 that can be used in the motor 1 described above will be described with reference to FIG. In addition, about the component of the same aspect as the above-mentioned embodiment, the same code | symbol is attached | subjected and the description is abbreviate | omitted.
FIG. 6 is a perspective view of the stator portion 130, the bracket 50 to which the stator portion 130 is assembled, and peripheral members. In FIG. 6, the illustration of the coil of the stator unit 130 is omitted. The stator part 130 has a stator core 134, a coil (not shown), and an insulating part 139 provided on the outer surface of the stator core 134, as in the above-described embodiment. The stator core 134 has an annular core back 132 and twelve teeth 131 extending radially outward of the core back 132. The inner peripheral surface 132a of the core back 132 is provided with three convex portions 133 that protrude radially inward.

  Compared to the above-described embodiment, the stator unit 130 of this modification is different in that the stator core 134 does not have a plurality of core units. The stator core 134 of this modification has the same shape as the lower core portion 34B of the above-described embodiment. Therefore, the stator core 134 of this modification can be described as a configuration in which only one layer of the core portion is laminated.

  In the motor employing the stator portion 130 of the present modification, the axial dimension of the stator core 134 is smaller than that of the above-described embodiment, so that the winding diameter of the coil wound around the teeth 131 is also smaller. Therefore, although the motor of this modification has a low output compared with the above-mentioned embodiment, since the stator core 134 is lightweight, it is also lightweight as a whole motor. Moreover, since the axial dimension of the stator part 130 is small, the motor of a modification can make an axial dimension small. According to this modification and the above-described embodiment, it is possible to easily configure a motor with adjusted output and weight while sharing parts such as the bracket 50 by changing the number of stacked core portions constituting the stator core. it can.

  Although the embodiments of the present invention have been described above, the configurations and combinations thereof are merely examples, and the addition, omission, replacement, and other modifications of the configurations are possible without departing from the spirit of the present invention. It is. Further, the present invention is not limited by the embodiment.

DESCRIPTION OF SYMBOLS 1 ... Motor, 9 ... External wiring, 10 ... Shaft, 20 ... Rotor part, 24 ... Rotor holder, 25 ... Rotor magnet, 26 ... Rotor hub, 30, 130 ... Stator part, 31, 131 ... Teeth, 32, 132 ... Core back 32a, 132a ... inner peripheral surface, 33, 133 ... convex portion, 33a ... lower surface, 33b ... upper surface, 33c ... radial inner end, 34, 134 ... stator core, 34A ... upper core portion, 34B ... lower core portion, 35 ... Coil, 35a ... Coil wire, 36 ... Second hole, 39, 139 ... Insulating part, 41 ... Upper bearing part (bearing part), 42 ... Lower bearing part, 50 ... Bracket, 51 ... Upper cylinder part ( (Cylinder part), 51a ... caulking part, 52 ... lower cylinder part, 52a ... first surface, 53 ... base part, 53a ... flat plate part, 53c ... second pedestal part, 53d ... first pedestal part, 53e ... second Surface, 54 ... first 56 ... first fixing portion, 57 ... second fixing portion, 58 ... third fixing portion, 59 ... bearing holding hole, 60 ... circuit board, 61 ... through hole, 62 ... substrate body, 63a, 63b, 63c ... rotation Sensor 65: Wiring connection part 65a ... One edge 65b ... Other edge 68 ... Coil wire through hole 70 ... Positioning member 71 ... Upper projection 72 ... Lower projection 73 ... Main body 74 ... Plate shape Part, 75 ... notch (coil wire support part), 75c ... retaining protrusion, J ... central axis

Claims (6)

A shaft disposed along a central axis extending in the vertical direction;
A rotor portion having a cylindrical rotor holder and a rotor magnet fixed to the inner peripheral surface of the rotor holder and rotating together with the shaft;
A bracket having an outer peripheral surface of the shaft and a base portion that is located on the lower side of the cylindrical portion and extends radially outward;
A bearing portion located between the inner peripheral surface of the cylindrical portion and the outer peripheral surface of the shaft in the radial direction;
A stator portion having a stator core and a coil and surrounding an outer peripheral surface of the cylindrical portion;
A circuit board located between the stator part and the base part in the vertical direction and having a board surface orthogonal to the central axis;
The circuit board includes a wiring connection portion to which external wiring is connected, and a first fixing portion, a second fixing portion, and a third fixing portion that are fixed to the base portion,
In the radial direction, the first fixing portion, the second fixing portion, and the third fixing portion are located outside the outer end of the stator portion and inside the outer end of the rotor holder,
In the circumferential direction, the first fixing portion is located near one edge of the wiring connection portion, the second fixing portion is located near the other edge of the wiring connection portion, and the third fixing portion is the first fixing portion. A motor located on one side of the part and on the other side of the second fixed part. The wiring connection portion has a width in the circumferential direction,
The motor according to claim 1, wherein the third fixing portion is located in a region on the opposite side of the wiring connection portion with respect to the central axis when viewed from the vertical direction.   The motor according to claim 1, wherein the circuit board includes a board main body and three rotation sensors that are attached to the board main body and are positioned immediately below the rotor magnet.   4. The motor according to claim 3, wherein at least one of the three rotation sensors is located in the vicinity of any one of the first fixed portion, the second fixed portion, and the third fixed portion.   The three rotation sensors are arranged at intervals of 120 °, and are respectively located in the vicinity of any one of the first fixing portion, the second fixing portion, and the third fixing portion in the circumferential direction. The motor described. An annular main body that is positioned between the stator and the circuit board in the vertical direction and surrounds the central axis, an upper protrusion that extends upward from the upper surface of the main body, and a lower that extends downward from the lower surface of the main body A positioning member having a side protrusion,
The positioning member has a plurality of coil wire support portions positioned at intervals in the circumferential direction on the outer peripheral surface,
The circuit board is provided with a plurality of coil wire through holes penetrating in the axial direction,
A coil wire extending downward from the coil is supported by the coil wire support portion, passes through the coil wire through hole, and is fixed by soldering on the lower surface of the circuit board.
The base portion includes a flat plate portion orthogonal to the central axis, and a first pedestal portion and a second pedestal portion that protrude upward from the flat plate portion,
The first pedestal portion is located radially inward of the second pedestal portion, and a first hole into which the lower protrusion is inserted is provided.
The second pedestal portion overlaps with the first fixing portion, the second fixing portion, and the third fixing portion when viewed from above and below, and is fixed to the circuit board,
A lower surface of the circuit board is in contact with an upper end of the second pedestal;
The motor according to any one of claims 1 to 5, wherein the stator core has a second hole into which the upper protrusion is inserted.

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