CN117498629A - Motor - Google Patents

Abstract

The invention provides a motor. A motor having a rotor rotating about a central axis extending up and down, the motor comprising: a shaft formed of a magnetic body and extending along the central axis; a bearing rotatably supporting the shaft; a housing located below the rotor and holding the bearing; a columnar attracting magnet disposed so as to face a lower end surface of the shaft in an axial direction; a attracting magnet holder that is held by the housing and accommodates the attracting magnet, the attracting magnet holder including: a plate-like bottom portion that expands radially from the center axis; a cylindrical portion extending upward from a radially outer edge of the bottom portion; and a flange portion extending radially outward from an upper end portion of the tubular portion, the flange portion being inclined with respect to the bottom portion.

Description

Motor

The present application is a divisional application of chinese patent application with application number 201910232984.9, application date 2019, 3-month, 26, and the name of "motor and blower".

Technical Field

The present invention relates to a motor.

Background

A radiator fan having a motor structure is disclosed in patent document 1. The heat radiation fan described in japanese laid-open patent publication 2010-281241 includes a frame, a substrate, a power connection line, and a fan wheel. Preferably, a bottom plate is formed on the inner side of the side wall portion of the frame, and a plurality of locking claws are provided in the accommodating space of the bottom plate. When the substrate is disposed in the accommodation space of the frame and contacts the bottom plate, the respective locking claws are locked and coupled to the outer periphery of the substrate.

However, in the heat radiation fan described in japanese laid-open patent publication 2010-281241, for example, when a substrate having a large thickness is held, the angle of the locking claw with respect to the bottom plate tends to be large when the locking claw is deformed. Therefore, stress concentrates on the locking claw.

Disclosure of Invention

The invention provides a motor which is easy to assemble and can stably hold a circuit board.

An exemplary motor of the present invention has a rotor rotating about a central axis extending up and down, comprising: a base portion located below the rotor; and a circuit board disposed above the base portion, the base portion having a plurality of substrate holding portions that hold the circuit board, the substrate holding portions including: a through hole penetrating in an axial direction; a 1 st extension portion extending downward from a lower surface of the base portion; a 2 nd extension portion extending from a lower side to an upper side of the base portion in the through hole, the 2 nd extension portion being opposed to the 1 st extension portion with a gap therebetween; a connection portion connecting a lower portion of the 1 st extension portion and a lower portion of the 2 nd extension portion; and a claw portion extending from an upper end portion of the 2 nd extension portion in a direction intersecting the central axis, at least a portion of a lower surface of the claw portion being in contact with an upper surface of the circuit board.

In the above embodiment, the blower includes the motor and the impeller fixed to the shaft.

According to the motor of the exemplary embodiment of the present invention, the assembly is easy, and the circuit board can be stably held.

The above and other features, elements, steps, features and advantages of the present invention will be more clearly understood from the following detailed description of the preferred embodiments of the present invention with reference to the accompanying drawings.

Drawings

Fig. 1 is a perspective view of an air blowing device according to the present invention.

Fig. 2 is an exploded perspective view of the blower according to the present invention.

Fig. 3 is a longitudinal sectional view of the blower device taken along a plane including the central axis.

Fig. 4 is an enlarged cross-sectional view of a portion of the housing in which the attracting magnet holder is disposed.

Fig. 5 is a cross-sectional perspective view of a vertical section of the attracting magnet holder, attracting magnet, and thrust plate.

Fig. 6 is an exploded perspective view of the attracting magnet holder, attracting magnet, and thrust plate.

Fig. 7 is an enlarged cross-sectional view of another example of the magnetic attraction portion.

Fig. 8 is a perspective view of another example of the magnetic attraction portion.

Fig. 9 is an enlarged cross-sectional view of another example of the magnetic attraction portion.

Fig. 10 is a plan view of the base portion on which the circuit board is mounted.

Fig. 11 is an enlarged perspective view of the base portion in a state where the circuit board is removed.

Fig. 12 is a cross-sectional perspective view of the vicinity of the enlarged substrate holding portion.

Fig. 13 is a perspective view of the stator as seen from below.

Fig. 14 is a bottom view of the stator shown in fig. 13.

Fig. 15 is a perspective view of the guide portion after enlargement from above.

Fig. 16 is a perspective view of the guide portion after enlargement from below.

Fig. 17 is an enlarged cross-sectional view of the stator including the guide portion and the base portion.

Fig. 18 is an enlarged cross-sectional view of a stator and a base portion including another example of the guide portion.

Detailed Description

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the present specification, the direction parallel to the central axis J of the blower a is referred to as an "axial direction", the direction perpendicular to the central axis J of the blower a is referred to as a "radial direction", and the direction along an arc centered on the central axis J of the blower a is referred to as a "circumferential direction". Similarly, the impeller 20 is also simply referred to as "axial direction", "radial direction", and "circumferential direction" in a state of being assembled in the blower a, in a direction that coincides with the axial direction, the radial direction, and the circumferential direction of the blower a. In the present specification, the air blowing device a has an axial direction in the up-down direction. The vertical direction is only a name used for explanation, and does not limit the positional relationship and direction in the use state of the blower a.

Hereinafter, an air blower according to an exemplary embodiment of the present invention will be described. Fig. 1 is a perspective view of an air blowing device according to the present invention. Fig. 2 is an exploded perspective view of the blower according to the present invention. Fig. 3 is a longitudinal sectional view of the blower device taken along a plane including the central axis. The blower a includes a motor 10 and an impeller 20.

The impeller 20 rotates about a central axis J extending up and down. The motor 10 is disposed below the impeller 20 to rotate the impeller 20.

The impeller 20 is an impeller of a so-called centrifugal fan that generates an air flow toward the radial outside by rotating. When the impeller 20 rotates, air is sucked from a radially central portion of the upper surface, and the sucked air is sent out radially outward. The impeller 20 is, for example, a molded product of resin. As the resin constituting the impeller 20, engineering plastics can be mentioned. Engineering plastics are resins excellent in mechanical properties such as strength and heat resistance. The impeller 20 may be formed of a material such as metal.

As shown in fig. 1, 2 and 3, the impeller 20 includes an impeller base 21, an impeller hub 22, a plurality of blades 23, and a support frame 24. The impeller base 21 has a disk shape. The impeller hub 22 extends upward from a radially central portion of the impeller base 21. The impeller base 21 has a circular ring shape, and a radially inner edge is connected to a radially outer edge of the impeller hub 22. That is, the impeller base 21 is connected to a radial outer edge of a hub inclined portion 222 of the impeller hub 22, which will be described later.

A plurality of (11 in this case) blades 23 are arranged at equal intervals in the circumferential direction on the upper surface of the impeller base 21 at positions radially outside the impeller hub 22, as shown in fig. 1. The radially inner side of the vane 23 is located at a position on the front side of the radially outer side of the vane 23 in the rotation direction of the impeller 20 (indicated by an arrow line C in fig. 1). Thereby, the impeller 20 rotates in the rotation direction C, and an air flow directed radially outward is generated. The support frame 24 is annular and is connected to the radially outer edges of the upper ends of the plurality of blades 23. The support frame 24 is fixed to the plurality of blades 23. The support frame 24 is a reinforcing member that connects the plurality of blades 23 to reinforce the blades 23.

The impeller hub 22 includes a hub top plate portion 221, a hub inclined portion 222, a hub barrel portion 223, and a boss portion 224. The hub top plate 221 has a disk shape extending in the radial direction. The radially outer edge of the hub top plate 221 is connected to the hub inclined portion 222. The hub inclined portion 222 has an annular cross section taken along a plane perpendicular to the central axis J, and is inclined radially outward as going axially downward. That is, the impeller hub 22 has a shape of an upper part of a truncated cone, which is a so-called truncated cone shape.

As shown in fig. 3, a lower surface concave portion 220 recessed upward is formed in the lower surface of the impeller hub 22. The boss portion 224 is disposed inside the lower surface recess 220. The boss 224 is a protrusion provided at the radial center of the lower surface of the hub top plate 221 and protruding downward.

A hole portion 225 is provided in the center (on the central axis J) of the lower surface of the boss portion 224. The hole 225 has a cylindrical shape extending along the central axis J, and the center of the hole 225 coincides with the central axis J. An upper end portion of a shaft 12 of the motor 10, which will be described later, is fixed to the hole 225. That is, the impeller 20 is fixed to the shaft 12. The impeller 20 and the shaft 12 are fixed by the shaft 12 being fixed to the hole 225. The impeller 20 rotates the shaft 12 around the central axis J as a rotation axis. In the present embodiment, the shaft 12 and the impeller 20 are fixed by insert molding, but the present invention is not limited thereto. For example, the fixing may be performed by press fitting, adhesion, welding, or the like. The upper end of the shaft 12 may be screwed by a bolt penetrating the upper surface of the impeller hub 22 in the axial direction. The method of fixing the impeller 20 to the shaft 12 can be widely used as a method of firmly fixing the impeller 20 to the shaft 12.

The boss portion 223 has a cylindrical shape extending downward from the lower surface of the boss plate 221. The center of the hub portion 223 coincides with the center axis J. A magnet holder 152 described later is fixed to the inner surface of the hub portion 223. The magnet holder 152 holds the rotor magnet 151. The magnet holder 152 is fixed to the hub portion 223, and the center of the rotor magnet 151 coincides with the center axis J. In the present embodiment, the magnet holder 152 and the hub 223 are fixed by insert molding. The method of fixing the magnet holder 152 to the hub 223 is not limited to insert molding, and a method of fixing the magnet holder 152 to the hub 223 can be widely used.

As shown in fig. 2 and 3, the motor 10 is disposed below the impeller 20 in the axial direction. The motor 10 includes a base portion 11, a shaft 12, a bearing 13, a stator 14, and a rotor 15. The motor 10 is a so-called outer rotor type brushless motor, and a rotor 15, which is radially opposite to a radially outer surface of the stator 14, rotates around a central axis. Also, the motor 10 has a circuit board 30.

As shown in fig. 2 and 3, the base portion 11 is a plate-like member disposed below the rotor 15. That is, the base portion 11 is located below the rotor 15. The base portion 11 includes a plate portion 111, a housing 112, and 3 arm portions 113. When the base portion 11 is viewed from above, the plate portion 111 is located at the radial center of the base portion 11. The housing 112 is cylindrical and extends upward along the central axis J from a radially central portion of the upper surface of the plate 111. That is, the base portion 11 includes a housing 112, and the housing 112 has a cylindrical shape extending upward from the upper surface and is fixed with the stator 14. A stator 14 is fixed to the radially outer surface of the casing 112.

The 3 arm portions 113 extend radially outward from the radially outer edge of the plate portion 111. The 3 arm portions 113 are arranged at equal intervals in the circumferential direction. A vibration isolation member 114 that suppresses transmission of vibration to the blower a is attached to a radial end of the arm 113. The blower a is mounted to the installation target device by bringing the vibration isolation member 114 into contact with the installation target device. The vibration isolation member 114 may be attached as needed. The base portion 11 is a molded resin body, and the plate portion 111, the housing 112, and the arm portion 113 are molded from the same member. 1 arm 113 of the plurality of arms 113 has a lead-out portion 1131 for holding a lead described later.

The base portion 11 has a holding recess 115 recessed from the upper surface of the housing 112 along the central axis J. A bearing 13 and a shaft 12 are mounted in the holding recess 115. The holding recess 115 includes: a bearing holding portion 1151 that holds the bearing 13; and a small diameter portion 1152 connected to a lower end portion of the bearing holding portion 1151 and having an inner diameter smaller than an inner diameter of the bearing holding portion 1151. The lower end portion of the bearing 13 and the bottom surface of the bearing holding portion 1151 sandwich and hold a later-described anti-slip ring 19 in the axial direction.

The shaft 12 is formed of a magnetic material and has a cylindrical shape extending along the central axis J. The shaft 12 is formed of, for example, iron. The shaft 12 includes a drop-off prevention groove 121 and a lower surface protrusion 122. The drop-off preventing groove 121 is a groove recessed in the radial direction and extending in the circumferential direction. A drop-off preventing ring 19 described later is fitted into the drop-off preventing groove 121. The drop-off prevention ring 19 is sandwiched and fixed by the lower surface of the bearing 13 and the bottom surface of the bearing holding portion 1151. Further, a lower surface convex portion 122 is formed on the lower surface of the shaft 12. The lower surface convex portion 122 is a curved surface having an inclination approaching the center as going axially downward. The center of the lower surface convex portion 122 in the radial direction is in contact with a thrust plate 163 described later.

The shaft 12 rotates with the lower surface convex portion 122 in contact with the thrust plate 163. In order to reduce the resistance during rotation, the contact surface between the lower surface convex portion 122 and the thrust plate 163 is preferably small in area. On the other hand, for example, in the case of one-point contact, at least one of the lower surface convex portion 122 and the thrust plate 163 may be deformed. Therefore, the lower surface convex portion 122 is preferably in a shape capable of reducing the contact area with the thrust plate 163 and suppressing stress concentration at the contact portion. Examples of such a shape include a smooth, or in other words, differentiable curved surface such as a spherical surface or a paraboloid of revolution. In addition, in addition to these, a shape capable of reducing contact resistance and suppressing stress concentration of the contact portion can be widely adopted.

The bearing 13 is cylindrical and is pressed into the holding recess 115. Thereby, the bearing 13 is fixed to the holding recess 115. I.e. the bearing 13 is fixed to the housing 112. The bearing 13 supports the shaft 12. The bearing 13 is a fluid bearing, and a lubricating oil (not shown) film is provided between the inner surface of the bearing 13 and the outer surface of the shaft 12. The frictional resistance between the inner surface of the bearing 13 and the outer surface of the shaft 12 becomes low due to the oil film. That is, the shaft 12 is rotatably supported by the bearing 13. In other words, the shaft 12 is rotatably supported by the base portion 11 to which the bearing 13 is fixed. In addition, at least the inner surface of the bearing 13 has a structure that circulates (supplies) oil in a gap between the inner surface thereof and the outer surface of the shaft 12. Examples of such a structure include a porous body.

The shaft 12 is rotatably supported by a bearing 13. The impeller 20 is fixed to the shaft 12 at a position above the bearing 13, specifically, at a position above the casing 112. A portion of the lower end side of the shaft 12 protrudes downward from the bearing 13. The portion of the shaft 12 protruding below the bearing 13 is disposed inside the small diameter portion 1152.

The motor 10 has a slip-off prevention ring 19 that inhibits the shaft 12 from slipping off. The drop-off prevention ring 19 is sandwiched and fixed between the lower end surface of the bearing 13 and the bottom surface of the bearing holding portion 1151. The anti-slip ring 19 is annular, and the shaft 12 penetrates the anti-slip ring 19. In other words, the drop-preventing ring 19 is axially opposite the drop-preventing groove 121 of the shaft 12. The inner diameter of the through hole of the drop-out preventing ring 19 is larger than the outer diameter of the drop-out preventing groove 121. The inner diameter of the through hole of the drop-off prevention ring 19 is smaller than the outer diameter of the portion of the shaft 12 vertically adjacent to the drop-off prevention groove 121. Therefore, when the shaft 12 moves upward, the side wall of the drop-off prevention groove 121 contacts the drop-off prevention ring 19 in the axial direction. Thereby, the shaft 12 is prevented from coming off in the axial direction.

As described above, since the outer surface of the shaft 12 and the inner surface of the bearing 13 are lubricated by oil, the shaft 12 is easily moved not only in the circumferential direction with respect to the bearing 13 but also in the axial direction with respect to the bearing 13. Therefore, the motor 10 includes the magnetic attraction portion 16 that prevents the shaft 12 from moving upward, i.e., from coming off. The magnetic attraction unit 16 will be described in detail below with reference to the drawings. Fig. 4 is an enlarged cross-sectional view of a portion of the enlarged casing where the attracting magnet holder is disposed. Fig. 5 is a cross-sectional perspective view of a vertical section of the attracting magnet holder, attracting magnet, and thrust plate. Fig. 6 is an exploded perspective view of the attracting magnet holder, attracting magnet, and thrust plate.

As shown in fig. 4 to 6, the magnetic attraction portion 16 includes a attraction magnet holder 161, an attraction magnet 162, and a thrust plate 163. The attracting magnet holder 161 includes a bottom portion 165, a cylindrical portion 166, and a flange portion 167. The bottom 165 has a disk shape perpendicular to the central axis J. The bottom 165 is formed into a circular plate shape, but is not limited to a circular plate, and may be formed into a polygonal shape when viewed from the axial direction. The bottom 165 can be formed in a shape conforming to the shape of the attracting magnet 162 housed therein. The cylindrical portion 166 has a cylindrical shape extending upward along the central axis J from the radially outer edge of the bottom portion 165. The flange 167 is annular and extends radially outward from the upper end of the cylindrical portion 166. The flange 167 is not limited to an annular shape.

The bottom 165, the cylindrical portion 166, and the flange portion 167 of the attracting magnet holder 161 are integral members. That is, the bottom portion 165, the cylindrical portion 166, and the flange portion 167 are an integral member. The attracting magnet holder 161 is formed by, for example, press working, drawing working, or the like, on a metal plate. As the metal plate constituting the attracting magnet holder 161, for example, an iron plate can be cited. Since the attracting magnet holder 161 is formed by press working a metal plate, the attracting magnet holder 161 is easily manufactured.

In the case of manufacturing the attracting magnet holder 161 by press working a metal plate, the metal plate is placed in a die (female die), and a portion serving as the bottom 165 is pushed into the die by a tool (punch). At this time, stress concentrates on the connection portion of the bottom portion 165 with the barrel portion 166. In order to suppress the influence of the stress on the entire bottom portion 165, a tool having an annular surface for pressing the metal plate is used. Thus, the bottom upper surface 1650, which is an upper surface of the bottom 165, includes a 1 st surface 1651 and a 2 nd surface 1652.

The 1 st surface 1651 is deformed by stress and residual stress at the time of press working. On the other hand, since stress is applied to the deformation of the 1 st surface 1651, it is not easily transmitted to the 2 nd surface 1652, and the 2 nd surface 1652 is not substantially deformed. Thus, the 2 nd surface 1652 is a plane perpendicular to the central axis J.

As shown in fig. 4, the 1 st surface 1651 is disposed on a radially outer edge of the bottom 165. Further, the 1 st surface 1651 is connected to a lower end portion of the cylindrical portion 166. The 1 st surface 1651 is in the shape of a ring. The 2 nd surface 1652 is disposed radially inward of the 1 st surface 1651. Since the 1 st surface 1651 is deformed by the application of force during press working, the thickness is smaller than that of the original metal plate. On the other hand, since the 2 nd surface 1652 is not deformed by applying a large force, it has a thickness substantially equal to that of the original metal plate. Therefore, the 2 nd surface 1652 is located above the 1 st surface 1651. Since the 1 st surface 1651 is thinner than the 2 nd surface 1652, the metal plate before press working may be additionally processed. In the present embodiment, the lower surface of the attracting magnet 162 is in contact with the 2 nd surface 1652 of the bottom upper surface 1650. Therefore, in the attracting magnet holder 161, the 2 nd surface 1652 is required to have higher machining accuracy than the 1 st surface 1651. For example, in the case of press working the attracting magnet holder 161, the flatness of the 2 nd surface 1652 on the bottom upper surface 1650 is set to be smaller than the flatness of the 1 st surface 1651, so that the attracting magnet holder 161 can be easily manufactured.

The attracting magnet 162 has a cylindrical shape, and the upper surface 1621 and the lower surface 1622 are perpendicular to the center line of the cylinder. In other words, the upper surface 1621 and the lower surface 1622 are perpendicular to the centerline and parallel to each other. The magnetic poles of the upper surface 1621 and the lower surface 1622 of the attracting magnet 162 are different in the axial direction. The attracting magnet 162 is housed inside the cylinder 166. Here, the attracting magnet holder 161 is made of iron and made of a magnetic material. Therefore, the lower surface 1622 of the attracting magnet 162 is fixed to the 2 nd surface 1652 by magnetic force. A part of the circumferential outer surface of the attracting magnet 162 is fixed in contact with the inner surface of the cylinder 166 by a magnetic force.

The axial length of the attracting magnet 162 is shorter than the axial length of the cylindrical portion 166. Therefore, the upper surface 1621 of the attracting magnet 162 is located below the upper end of the cylindrical portion 166. That is, the attracting magnet 162 is housed inside the cylinder 166. Thereby, the cylindrical portion 166 functions as a back yoke of the attracting magnet 162, and strengthens the magnetic force of the attracting magnet 162.

The lower surface 1622 of the attracting magnet 162 contacts the 2 nd surface. Thereby, the center line of the attracting magnet 162 is parallel to the center axis J. The term "center line" is parallel to the central axis J, and includes the case where the center line coincides with the central axis J. The upper surface 1621 of the attracting magnet 162 is perpendicular to the center axis J. In the present embodiment, the lower surface 1622 of the attracting magnet 162 is in contact with the 2 nd surface 1652 of the bottom upper surface 1650.

The thrust plate 163 is disposed above the upper surface 1621 of the attracting magnet 162. In the present embodiment, the thickness of the thrust plate 163 is smaller than the thickness of the cylindrical portion 166. The thrust plate 163 may be of a thickness such that the magnetic flux from the upper surface 1621 of the attracting magnet 162 can penetrate therethrough to pull the lower end portion of the shaft 12. The upper surface 1621 of the attracting magnet 162 faces the lower surface convex portion 122 of the shaft 12 via the thrust plate 163 in the axial direction.

Thereby, the lower surface of the shaft 12 is attracted by the magnetic force of the attracting magnet 162, and the lower surface of the shaft 12 is in contact with the thrust plate 163. That is, the shaft 12 is sucked axially downward. At this time, the lower surface convex portion 122 of the shaft 12 is located below the upper surface of the flange portion 167. That is, the outer peripheral surface of the shaft 12 is radially opposed to the inner peripheral surface of the cylindrical portion 166. Thereby, the magnetic flux from the attracting magnet 162 passes through the cylindrical portion 166 and penetrates to the lower end surface of the shaft 12. Therefore, the attraction force of the attraction shaft 12 downward by the attraction magnet 162 can be improved. Therefore, when the motor 10 rotates, the shaft 12 can be prevented from floating upward due to buoyancy, and the operation efficiency of the motor 10 can be improved.

The shaft 12 is attracted by the attracting magnet 162 and rotates with the lower surface thereof in contact with the thrust plate 163. The thrust plate 163 may be formed of a magnetic material. In this case, the force of the suction shaft 12 by the magnetic force of the suction magnet 162 can be increased.

In the attracting magnet holder 161, the flange 167 is fixed to the inside of the casing 112. The base portion 11 is a molded body of resin, and the housing 112 is also molded of resin. Further, the flange portion 167 is covered with the resin of the molded housing 112.

Further, as a method of disposing the flange 167 in the resin, for example, insert molding can be given. A magnet holder 161 is attached to a mold for molding the base portion 11. Then, the space in which at least the flange 167 of the attracting magnet holder 161 is disposed is filled with resin. The filled resin is cured to form the base portion 11. Thereby, the attracting magnet holder 161 is fixed to the housing 112. In this way, the attracting magnet holder 161 can be fixed to the housing 112 and to the base portion 11 by resin molding 1 time. The attracting magnet holder 161 can be easily fixed to the housing 112, and the motor 10 can be easily manufactured.

In the present embodiment, the attracting magnet holder 161 is configured to cover the entire flange portion 167 with resin, but if the attracting magnet holder can be firmly fixed, a part of the flange portion 167 may be covered with resin. In contrast, the portion covered with the resin is not limited to the flange portion 167, and the outer surface of the bottom portion 165 or the cylindrical portion 166 may be covered with the resin. In the attracting magnet holder 161, the flange 167 has an annular shape, that is, a circular outer shape when viewed from the axial direction, but is not limited thereto. For example, the shape may be polygonal such as oval, square, or diamond.

By having the magnetic attraction portion 16 shown above, the motor 10 is easily assembled. The cylindrical portion 166 functions as a back yoke for attracting the magnet 162. This can improve the attraction force of the attraction shaft 12 downward by the attraction magnet 162. Therefore, when the motor 10 rotates, the shaft 12 can be prevented from floating upward due to buoyancy, and the operation efficiency of the motor 10 can be improved.

Fig. 7 is an enlarged cross-sectional view of another example of the magnetic attraction portion. The shape of the flange 167a of the attracting magnet holder 161a shown in fig. 7 is different from the flange 167 of the attracting magnet holder 161. Other aspects of the attracting magnet holder 161a are similar to those of the attracting magnet holder 161. Therefore, in the attracting magnet holder 161a, the same portions as those of the attracting magnet holder 161 are denoted by the same reference numerals, and detailed description of the same portions is omitted.

Regarding the direction perpendicular to the center axis J, the posture of the thrust plate 163 and the posture of the shaft 12 depend on the posture of the attracting magnet 162. As shown in fig. 7, in the attracting magnet holder 161a, the flange 167a is not in contact with the shaft 12 main body. The thrust plate 163 and the attracting magnet 162, which are in direct contact with the shaft 12, are not in contact. Therefore, even if the flange portion 167a is inclined with respect to the direction perpendicular to the central axis J, unlike the 2 nd surface 1652 of the bottom portion 165 that is in contact with the lower surface 1622 of the attracting magnet 162, the posture of the shaft 12 when rotating is not affected. Therefore, the flange 167a may not be parallel to the direction perpendicular to the central axis J. As shown in fig. 7, in the present modification, the flange 167a is inclined with respect to the 2 nd surface 1652 of the bottom 165.

The attracting magnet holder 161a is formed by press working a metal plate, similarly to the attracting magnet holder 161 described above. As described above, in the attracting magnet holder 161a, the accuracy of the angle with respect to the direction perpendicular to the central axis J required for the flange portion 167a is lower than the accuracy of the angle required for the 2 nd surface 1652. Therefore, the attracting magnet holder 161a is easily manufactured.

As shown in fig. 7, in the attracting magnet holder 161a, the flange 167a can be shaped so as to be directed upward as it goes radially outward. By forming the flange portion 167a in this shape, the bending angle of the flange portion 167a during press working can be reduced as compared with a case where the flange portion 167a is formed in parallel with the 2 nd surface 1652 of the bottom portion 165. This can reduce stress concentrated on the connection portion between the flange portion 167a and the tube portion 166. For example, when the flange 167a is fixed to the casing 112 by insert molding, residual stress accumulated in the flange 167a of the attracting magnet holder 161a may be released depending on other conditions such as temperature. Even in this case, since the residual stress accumulated in the flange portion 167a is small, the stress acting on the casing 112 can be reduced.

Fig. 8 is a perspective view of another example of the magnetic attraction portion. The shape of the flange 167b of the attracting magnet holder 161b shown in fig. 8 is different from the flange 167 of the attracting magnet holder 161. Other aspects of the attracting magnet holder 161b are the same as those of the attracting magnet holder 161. Therefore, in the attracting magnet holder 161b, the same portions as those of the attracting magnet holder 161 are denoted by the same reference numerals, and detailed description of the same portions is omitted.

In the attracting magnet holder 161b shown in fig. 8, the flange portion 167b has flange protrusions 1671 having different axial positions of adjacent portions in a part of the circumferential direction. The upper surface of the flange protrusion 1671 protrudes in the axial direction more than other portions of the upper surface of the flange portion 167 b. The lower surface of the flange protrusion 1671 is recessed in the axial direction as compared with the other portions of the lower surface of the flange portion 167 b. The flange portion 167b undulates in the circumferential direction by having a flange protrusion 1671.

When the flange 167b is disposed in the resin of the casing 112, the flange protrusion 1671 serves as a resistance force to restrict the movement of the attracting magnet holder 161b in the circumferential direction. In fig. 7, the flange protrusion 1671 is shown as an upwardly protruding portion, but is not limited thereto. For example, the metal plate may have a portion protruding downward. The flange 167b may have a shape in which upwardly convex portions and downwardly convex portions periodically alternate. The shape of the flange 167b is not limited to the shape in which the upwardly convex portion and the axially downwardly convex portion periodically alternate, and may have an irregular uneven surface. Further, a thicker portion and a thinner portion of the flange portion 167b may be combined, and undulation may be provided on the upper surface and the lower surface of the flange portion 167 b.

Fig. 9 is an enlarged cross-sectional view of another example of the magnetic attraction portion. An inner surface of the cylindrical portion 166c of the attracting magnet holder 161c shown in fig. 9 is opposed to a radially outer surface of the lower end portion of the shaft 12. Other aspects of the attracting magnet holder 161c are the same as those of the attracting magnet holder 161. Therefore, in the attracting magnet holder 161c, the same portions as those of the attracting magnet holder 161 are denoted by the same reference numerals, and detailed description of the same portions is omitted.

As shown in fig. 9, the inner surface of the cylindrical portion 166c of the attracting magnet holder 161c is radially opposed to the outer surface of the shaft 12 over the entire inner surface. That is, the outer peripheral surface of the shaft 12 faces the inner peripheral surface of the cylindrical portion 166c with a gap therebetween in the radial direction. With this configuration, the shaft 12 can be prevented from coming into contact with the cylindrical portion 166c during rotation. Further, by making the axial length of the cylindrical portion 166c longer than the axial length of the cylindrical portion 166, the contact area between the attracting magnet holder 161c and the resin constituting the base portion increases, and the attracting magnet holder 161c can be firmly fixed to the base portion 11.

The base portion 11 has a plurality of substrate holding portions 17. The circuit board 30 is held by the substrate holding portion 17. The circuit board 30 and the substrate holding portion 17 will be described in detail with reference to the drawings. Fig. 10 is a plan view of the base portion on which the circuit board is mounted. Fig. 11 is an enlarged perspective view of the base portion in a state where the circuit board is removed. Fig. 12 is a cross-sectional perspective view of the vicinity of the enlarged substrate holding portion.

As shown in fig. 10, the circuit board 30 is held by the substrate holding portion 17, and the substrate holding portion 17 is provided in the plate portion 111 of the base portion 11. That is, the circuit board 30 is disposed above the base portion 11. The circuit board 30 is disposed in a board mounting portion 116, which is a region radially outside the casing 112, of the board portion 111. That is, the circuit board 30 is disposed radially outward of the housing 112. The portion of the housing 112 adjacent to the substrate mounting portion 116 has a notch surface 1121 cut into a planar shape. The notch surface 1121 is a surface perpendicular to the radial direction. That is, the casing 112 has a planar notch surface 1121 perpendicular to the radial direction at the radial outer edge.

Here, the circuit board 30 will be described. The circuit board 30 includes an inner planar surface 301 and an outer planar surface 302. The inner flat surface 301 and the outer flat surface 302 are flat surfaces, and the inner flat surface 301 and the outer flat surface 302 extend in a direction perpendicular to the radial direction. When the circuit board 30 is mounted on the substrate mounting portion 116, the inner flat surface 301 is a side surface on the central axis J side, and faces the notch surface 1121 of the housing 112 in the radial direction. That is, the circuit board 30 has a flat inner flat surface 301 on the side surface on the center axis J side. When the circuit board 30 is disposed on the substrate mounting portion 116, the inner flat surface 301 is made to follow the notch surface 1121. That is, the inner flat surface 301 is opposed to the notch surface 1121 in the radial direction. This makes it possible to easily mount the circuit board 30 on the substrate holding portion 17. The circuit board 30 can be disposed so as to be offset from the central axis J. The outer flat surface 302 is a side surface of the circuit board 30 opposite to the central axis J. That is, the circuit board 30 has a flat outer flat surface 302 on the side opposite to the center axis J. In the present embodiment, the inner flat surface 301 is parallel to the outer flat surface 302. The length of the inner flat surface 301 in the direction perpendicular to the central axis is longer than the length of the outer flat surface 302 in the direction perpendicular to the central axis in plan view. The inner flat surface 301 and the outer flat surface 302 are connected by a curved surface.

The circuit board 30 has a substrate through hole 303 penetrating in the axial direction. The circuit board 30 is provided with 2 substrate through holes 303. The base portion 11 has a plurality of bosses 117 extending upward from the upper surface. The base portion 11 has 2 bosses 117. The boss 117 penetrates the substrate through-hole 303. This can restrict movement of the circuit board 30 in the circumferential direction and the radial direction. In order to limit the movement of the circuit board 30 in the circumferential direction and the radial direction, it is preferable that the substrate through-holes 303 and the bosses 117 have at least 2.

As shown in fig. 10, the circuit board 30 includes a connection portion 31, an external connection portion 32, and a detection portion 33 on the upper surface thereof. The circuit board 30 has a wiring pattern formed of a conductive material such as aluminum or copper, for example. The connection portion 31 and the external connection portion 32 are part of the pattern wiring. That is, the connection portion 31 and the external connection portion 32 are connection terminals. A lead wire 146 (see fig. 17 and the like described below) led out from a coil 143 described below is connected to the connection portion 31. That is, the lead wire 146 is connected to the connection portion 31. By connecting the connection portion 31 and the lead wire 146, a current from the driving circuit can be supplied to the coil 143.

The external connection unit 32 is connected to, for example, a lead Wr for connection to an external device such as an external power supply. The lead Wr connected to the external connection portion 32 is hooked to the lead drawing portion 1131 and drawn out to the outside. The detection unit 33 includes a sensor mounted on the upper surface of the circuit board 30, and detects the rotation of the rotor 15. As a sensor for detecting the rotation of the rotor 15, for example, a hall element or the like can be cited. The detection unit 33 is preferably disposed near the rotor 15. Therefore, the detection portion 33 is disposed on the inner flat surface 301 side, which is the radially inner side of the circuit board 30. That is, the detection unit 33 is provided on the inner flat surface 301 side of the upper surface of the circuit board 30, and detects the rotational position of the rotor 15.

The circuit board 30 is held by the substrate holding portion 17 after being placed on the substrate mounting portion 116 of the board portion 111. Thereby, the circuit board 30 is fixed to the substrate mounting portion 116. Next, the substrate holding unit 17 will be described in detail.

As shown in fig. 10 to 12, the board holding portion 17 includes a 1 st extension 171, a 2 nd extension 172, a connecting portion 173, and a claw portion 174. The substrate holding portion 17 is provided on the base portion 11, and is formed of the same member as the base portion 11.

The 1 st extension 171 extends downward from the lower surface of the base portion 11. The base portion 11 has a base through hole 118 penetrating the base portion in the up-down direction. That is, the substrate holding portion 17 has a through hole 118 penetrating in the axial direction. Further, the 1 st extension 171 extends downward from the lower surface of the base portion 11. The base through-hole 118 is rectangular in shape when viewed in the axial direction. The 1 st extension 171 is in the shape of a tube with a rectangular cross section extending downward from all the edge portions of the four sides of the rectangular shape forming the base through hole 118. Thus, forming the cylindrical shape can improve the strength of the 1 st extension 171. In addition, in the case where sufficient strength can be obtained, the 1 st extension 171 may be a wall extending axially downward from an edge portion of one side of the base through hole 118, for example, instead of a cylindrical shape.

The 2 nd extension 172 extends from the lower side to the upper side of the base portion 11 in the base through hole 118, and faces the 1 st extension 171 with a gap therebetween. That is, the connection portion 173 connects the lower portion of the 1 st extension 171 and the lower portion of the 2 nd extension 172. The 2 nd extension 172 penetrates the base through hole 118 from below to above. That is, the 2 nd extension 172 extends from the lower side to the upper side of the base portion 11 in the through hole 118, and faces the 1 st extension 171 with a gap therebetween.

The connection portion 173 connects the lower portion of the 1 st extension 171 and the lower portion of the 2 nd extension 172. After the 1 st extension 171 is temporarily extended downward, the end thereof is connected to the 2 nd extension 172 via the connection 173, whereby the axial length of the 2 nd extension 172 can be lengthened. This can suppress an increase in the deformation angle of the 2 nd extension 172 when the circuit board 30 is mounted, and can reduce stress concentrated on the 2 nd extension 172. For example, even when the circuit board 30 having a large thickness is used, the distance from the upper surface of the base portion 11 to the upper end of the claw portion 174 does not need to be increased because the circuit board temporarily extends downward from the base portion 11. This can suppress an increase in size of the motor 10, and the board holding portion 17 can stably hold the circuit board 30.

The length of the 2 nd extension 172 is shorter than the length of the connection portion 173 in the longitudinal direction of the base through hole 118. That is, the width of the 2 nd extension 172 is smaller than the width of the connection 173. In this way, the 2 nd extension 172 is easier to deform than the connection 173. The connection portion 173 is connected to 3 sides of the 1 st extension 171, but is not limited thereto, and may be connected to at least a part thereof. In the substrate holding portion 17, the connection portion 173 protrudes from a wall portion forming the long side of the 1 st extension 171, and is also connected to a wall portion adjacent to the wall portion. That is, the connection portion 173 is connected to 1 long side of the 1 st extension 171 and short sides of both ends thereof. This can improve the strength of the 1 st extension 171 and the connection 173.

The claw 174 extends from the upper end of the 2 nd extension 172 in a direction intersecting the central axis J. That is, the claw 174 extends from the upper end portion of the 2 nd extension 172 in a direction intersecting the central axis J. In the present embodiment, the claw 174 extends from the upper end of the 2 nd extension 172 toward the opposite side to the connection portion 173, but is not limited thereto. For example, the claw 174 may extend from the upper end of the 2 nd extension 172 toward the connection portion 173. The pawl 174 includes a pawl lower surface 1741 and a pawl upper surface 1742. The claw portion lower surface 1741 is a lower surface of the claw portion 174, and contacts the upper surface of the circuit board 30. That is, at least a portion of the lower surface of the claw 174 is in contact with the upper surface of the circuit board 30. The claw portion lower surface 1741 intersects the central axis J. The claw lower surface 1741 is disposed at a position higher than the upper surface of the substrate mounting portion 116 by an amount corresponding to the thickness of the circuit board 30. In the claw portion 174, the claw portion lower surface 1741 is a surface perpendicular to the central axis J, but is not limited thereto. The claw portion lower surface 1741 may be disposed at a position higher than the upper surface of the board mounting portion 116 by an amount larger than the thickness of the circuit board 30. By doing so, a gap can be formed between the circuit board 30 and the claw portion lower surface 1741, and the circuit board 30 can be easily mounted.

The claw portion upper surface 1742 is an upper surface of the claw portion 174, and is located above the claw portion lower surface 1741. The pawl upper surface 1742 is an inclined surface that faces downward in a direction away from the 1 st extension 171.

As shown in fig. 10, the base portion 11 includes 3 substrate holding portions 17. 2 substrate holders 17 out of the 3 substrate holders 17 hold the inner flat surface 301 side of the circuit board 30, and 1 substrate holder 17 holds the outer flat surface 302 side of the circuit board 30. In the following description, the substrate holding portion 17 for holding the inner flat surface 301 side is defined as an inner substrate holding portion 17m, and the substrate holding portion 17 for holding the outer flat surface 302 side is defined as an outer substrate holding portion 17n, as needed.

The side surface of the inner substrate holding portion 17m, from which the claw portion 174 extends, faces the inner flat surface 301 in a direction intersecting the central axis J. That is, the side surface of the 2 nd extension 172 faces the inner flat surface 301 in the direction intersecting the central axis J. The side surface of the outer substrate holding portion 17n, from which the claw portion 174 of the 2 nd extension portion 172 extends, faces the inner flat surface 301 in a direction intersecting the central axis J. That is, the 2 nd extension 172 of at least one substrate holding portion 17n among the plurality of substrate holding portions 17n is opposed to the outer flat surface 302 in a direction intersecting the central axis J.

In this way, by holding the inner flat surface 301 side of the circuit board 30 by the 2 inner substrate holding portions 17m and holding the outer flat surface 302 side of the circuit board 30 by the outer substrate holding portions 17n, the circuit board 30 can be restrained from moving in the direction away from the center axis J.

Next, a step of mounting the circuit board 30 on the substrate mounting portion 116 will be described. The boss 117 is passed through the substrate through hole 303 of the circuit board 30. Thereby, the circuit board 30 is positioned with respect to the substrate mounting portion 116 in the circumferential direction as well as in the radial direction. Then, by moving the circuit board 30 downward, the claw upper surface 1742 of the inner substrate holding section 17m contacts the lower edge of the inner flat surface 301. The claw portion upper surface 1742 of the outer substrate holding portion 17n contacts the lower edge portion of the outer flat surface 302. When the circuit board 30 is moved further downward, the claw upper surface 1742 of the inner substrate holding portion 17m is pressed against the inner flat surface 301, and the 2 nd extension 172 is elastically deformed toward the 1 st extension 171 side. The claw upper surface 1742 of the outer substrate holding portion 17n is pressed by the outer flat surface 302, and the 2 nd extension 172 is elastically deformed toward the 1 st extension 171 side.

Then, when the lower surface of the circuit board 30 is in contact with the upper surface of the substrate mounting portion 116, the claw portions 174 of the inner substrate holding portion 17m and the outer substrate holding portion 17n are located at positions above the upper surface of the circuit board 30. Thereby, the 2 nd extension 172, which is elastically deformed, returns to the original position, and the claw lower surface 1741 of the claw 174 contacts the upper surface of the circuit board 30. Thus, the movement of the circuit board 30 in the axial direction upward can be restricted by the inner substrate holding portion 17m and the outer substrate holding portion 17 n.

By mounting the circuit board 30 on the substrate mounting portion 116, the movement of the circuit board 30 in the axial direction, the radial direction, and the circumferential direction can be restricted. In this state, the lead wire 146 (see fig. 17 described later) is fixed to the connection portion 31, and the lead wire Wr is fixed to the external connection portion 32. That is, the circuit board 30 is connected to the lead Wr connected to the external device.

The lead Wr connected to the external connection unit 32 is connected to an external device such as an external power supply. In the case where the lead wire Wr is loose, in order to prevent the lead wire Wr from contacting the rotor 15, it is necessary to increase the distance between the lead wire Wr and the rotor 15. However, if the distance between the lead wire Wr and the rotor 15 is increased, the motor 10 is increased in size. In order to miniaturize the motor 10, the lead wire Wr is preferably drawn out in a state where a certain degree of tension is applied. In the present embodiment, the lead Wr is hooked to the lead drawing portion 1131 and drawn out. Therefore, when the lead Wr is drawn out, the circuit board 30 is pulled in the direction in which the lead Wr extends. In the present embodiment, the direction in which the lead Wr of the external connection portion 32 is arranged is set to be a direction intersecting the direction in which the claw portion 174 of the inner substrate holding portion 17m is extended and the direction in which the claw portion 174 of the outer substrate holding portion 17n is extended. That is, the direction in which the claw 174 extends intersects with the direction in which the lead Wr extends. By providing the external connection portion 32 in this way, even if the circuit board 30 is pulled by the lead Wr, deformation of the 2 nd extension portion 172 of the inner substrate holding portion 17m and the outer substrate holding portion 17n can be suppressed. Thus, the circuit board 30 can be firmly held by the inner substrate holding portion 17m and the outer substrate holding portion 17 n.

The substrate mounting portion 116 includes 2 inner substrate holding portions 17m and 1 outer substrate holding portion 17n, but is not limited thereto. For example, 3 or more substrate holders 17 may be provided. That is, the base portion 11 includes a plurality of substrate holding portions 17 for holding the circuit board 30. In addition, in the case where the accuracy of positioning by the boss 117 is high, the board 30 is not likely to shake, and thus the number of substrate holding portions 17 may be 1. In this case, the substrate holding portion 17 may be disposed on the inner flat surface 301 side or on the outer flat surface 302 side. Portions of the circuit board 30 near the side surfaces other than the inner flat surface 301 and the outer flat surface 302 may be held. In this case, the side surface facing the substrate holding portion 17 is preferably a flat surface.

The rotor 15 includes a rotor magnet 151 and a magnet holder 152. The rotor magnet 151 has a cylindrical shape, and the magnetic pole faces of the N poles and the magnetic pole faces of the S poles are alternately arranged in the circumferential direction. As the rotor magnet 151, for example, a rotor magnet formed by alternately magnetizing an N pole and an S pole in the circumferential direction in a cylindrical body integrally molded of a resin containing a magnetic powder is exemplified. The rotor magnet 151 may be formed of a plurality of magnet pieces. In this case, the magnets may be alternately arranged with N poles and S poles in the circumferential direction.

The magnet holder 152 is formed of a magnetic material, and has a rotor magnet 151 fixed to an inner surface thereof. The magnet holder 152 includes a cover 153 and a holder barrel 154. The cover 153 is annular. The holder cylinder 154 extends downward from the radially outer edge of the cover 153. The magnet holder 152 is fixed to the inside of the hub 223 of the impeller 20. Thus, the center of the rotor magnet 151 coincides with the center axis J.

Next, the stator 14 will be described in detail. Fig. 13 is a perspective view of the stator as seen from below. Fig. 14 is a bottom view of the stator shown in fig. 13. As shown in fig. 3 and the like, the stator 14 is fixed to the casing 112. As shown in fig. 13 and 14, the stator 14 includes a stator core 141, an insulator 142, and a coil 143. The stator core 141 is a laminated body in which electromagnetic steel plates are laminated in the axial direction (up-down direction in fig. 3). The stator core 141 is not limited to a laminate of laminated electromagnetic steel sheets, and may be an integral component such as a sintered product or a cast product of powder, for example.

The stator core 141 has an annular core back 144 and a plurality of teeth 145. The housing 112 is secured to the inner surface of the annular core back 144. The core back 144 and the housing 112 may be fixed to each other.

The plurality of teeth 145 extend radially outward from the outer peripheral surface of the core back 144 toward the magnets (not shown) of the rotor 15. That is, the teeth 145 extend radially outward from the core back 144. Thus, the plurality of teeth 145 are circumferentially arranged. The coil 143 is formed by winding a wire around each tooth 145 through an insulator 142.

The insulator 142 is formed of, for example, resin or the like, and covers at least the teeth 145. The insulator 142 insulates the stator core 141 including the teeth 145 and the coil 143. The insulator 142 is not limited to resin, and a material that can insulate the stator core 141 and the coil 143 can be widely used.

As described above, the coil 143 is formed by winding the wire around the teeth 145 via the insulator 142. The wire constituting the coil 143 has a winding start portion and a winding end portion. The winding start portion and the winding end portion of the wire are lead wires 146 led out from the coil 143. The lead wires 146 are connected to the connection portions 31 of the circuit board 30. The wire is wound across a plurality of coils 143. Thus, the stator 14 has 2 lead wires 146. In the present embodiment, the motor 10 is a single-phase motor, and therefore, has 2 lead wires 146, but the present invention is not limited thereto. For example, in the case where the motor 10 is a three-phase motor, 3 lead wires 146 may be provided.

The connection portion 31 is connected to a driving circuit (not shown) mounted on the circuit board 30, and current is supplied from the driving circuit to the coil 143 via the lead wire 146. The motor 10 is a brushless motor. When a current is supplied to the plurality of coils 143 at a predetermined timing, the coils 143 attract or repel the rotor magnets 151, and the rotor 15 rotates. The stator 14 has a guide portion 18 for guiding a lead wire 146 led out from a coil 143.

Next, the guide portion 18 will be described in detail with reference to the drawings. Fig. 15 is a perspective view of the guide portion after enlargement from above. Fig. 16 is a perspective view of the guide portion after enlargement from below. Fig. 17 is an enlarged cross-sectional view of the stator including the guide portion and the base portion.

As shown in fig. 15, 16, and 17, the guide portion 18 is disposed below the insulator 142. The guide portion 18 is disposed radially outward of the coil 143. The guide 18 is formed of the same member as the insulator 142. The guide portion 18 includes a 1 st wall portion 181, a 2 nd wall portion 182, and a bent portion 183. The 1 st wall portion 181 extends downward from the lower surface of the insulator. The 1 st wall portion 181 extends in the circumferential direction. The 1 st wall portion 181 has curved surfaces 184 at both ends in the circumferential direction. The radially outer surface 1811 of the 1 st wall portion 181 is smoothly connected with the radially inner surface 1812. In other words, the curved surface 184 is a curved surface that can be differentially connected. The curved surface 184 itself is also a differentiable curved surface.

The bent portion 183 is connected to the lower end portion of the 1 st wall portion 181, and extends radially outward. Here, the bending portion 183 is perpendicular to the central axis J. The bent portion 183 faces the base portion 11 and the circuit board 30 with a gap therebetween in the axial direction. The 2 nd wall 182 is connected to the radially outer edge of the bent portion 183 and extends axially upward. The 1 st wall portion 181 and the 2 nd wall portion 182 are opposed to each other with a gap 185 therebetween in the radial direction. Further, the 1 st wall portion 181 has a larger radial thickness than the 2 nd wall portion 182. The 1 st wall portion 181 may be subjected to a force by winding the lead wire 146. With this structure, the strength of the 1 st wall portion 181 can be improved.

The lead wire 146 is in contact with the radially outer surface 1811 and the radially inner surface 1812 of the 1 st wall portion 181. In the present embodiment, the lead wire 146 is wound around the 1 st wall portion 181 of the guide portion 18 for 1 or more weeks. At this time, the lead wires 146 contact the curved surface 184. Thus, when the lead wire 146 extends between the radially outer surface 1811 and the radially inner surface 1812, stress is less likely to concentrate, and the load on the lead wire 146 can be reduced. The distal ends of the lead wires 146 wound around the 1 st wall portion 181 are fixed to the connection portions 31 provided in the circuit board 30. Further, a fixing method of the lead wire 146 to the connection portion 31 may be welding.

The lead wire 146 led out from the coil 143 is once wound around the guide portion 18 and connected to the connection portion 31. When assembling the motor 10, the pre-assembled stator 14 is fixed to the housing 112. The coil 143 is formed by winding a wire around the teeth 145 in the stator 14 before being fixed to the case 112. At this time, the lead wire 146 is wound around the guide portion 18, and the lead wire 146 and the coil 143 are less likely to be loosened. This facilitates the work for manufacturing the motor 10. Further, by winding the lead wire 146 around the guide portion 18, the force acting on the lead wire 146 can be received by the guide portion 18. This can suppress the lead wire 146 from moving when it is fixed to the connection portion 31.

When fixing the lead wires 146 and the connection portions 31, the lead wires 146 may be pulled in a direction in which the connection portions 31 are arranged. That is, a downward force may act on the lead wire 146. The bent portion 183 is connected to the lower end portion of the 1 st wall portion 181, and extends radially outward. Therefore, even if downward force acts, the lead wire 146 contacts the upper surface of the bent portion 183. That is, the movement of the lead wire 146 when fixed to the connection portion 31 can be suppressed.

A part of the guide portion 18 is disposed at a position axially opposite to the rotor magnet 151. The lead wire 146 guided by the guide portion 18 is disposed below the rotor 15 so as to be separated from the rotor 15. Therefore, the lead wires 146 can be suppressed from contacting the rotor 15.

The connecting portion 31 is located radially outward of the radially outer edge of the bent portion 183. The connection portion 31 is located radially outward of the magnet holder 152 of the rotor 15. With this arrangement, the lead wire 146 and the connection portion 31 can be fixed in a state where the shaft 12 fixed to the rotor 15 is attached to the base portion 11, and the work efficiency can be improved. Further, even when the shaft 12, the rotor 15, and the impeller 20 are fixed by insert molding, for example, the distance between the connecting portion 31 and the insulator 142 can be increased. Therefore, a tool or the like for fixing the lead wire 146 and the connection portion 31 can be easily arranged, and the work efficiency can be improved.

The insulator 142 has 2 guide portions 18, but is not limited thereto. For example, in a case where a plurality of lead wires 146 can be wound, the number of the guide portions 18 may be 1. For example, when the number of the lead wires 146 is plural, the number of the guide portions 18 may be the same as the number of the lead wires 146.

Fig. 18 is an enlarged cross-sectional view of a stator and a base portion including another example of the guide portion. As shown in fig. 18, the guide portion 18a includes a 1 st wall portion 181 and a bent portion 183. That is, the guide portion 18a is configured such that the 2 nd wall portion 182 is omitted from the guide portion 18, and the other portions are the same as the guide portion 18. Therefore, the same portions of the guide portion 18a as those of the guide portion 18 are denoted by the same reference numerals, and detailed description of the same portions is omitted.

For example, when the lead wire 146 is wound around the 1 st wall portion 181 a plurality of times to prevent the lead wire 146 from falling off, the loosening of the lead wire 146 can be suppressed even if the 2 nd wall portion 182 is omitted. Even if a downward force acts on the lead wire 146, the lead wire 146 contacts the upper surface of the bent portion 183. That is, the movement of the lead wire 146 when fixed to the connection portion 31 can be suppressed.

Next, a method of assembling the blower a will be described. In the blower a, the flange 167 of the attracting magnet holder 161 is fixed to the casing 112 by insert molding. The attracting magnet holder 161 opens upward, that is, toward the holding recess 115 of the housing 112. The attracting magnet 162 is inserted into the attracting magnet holder 161. At this time, the lower surface 1622 of the attracting magnet 162 is in contact with the 2 nd surface 1652 of the bottom 165 of the attracting magnet holder 161.

The lower surface 1622 and the 2 nd surface 1652 are fixed by magnetic force. At this time, the magnetic force also acts between the cylindrical portion 166 and the side surface of the attracting magnet 162. Thereby, a part of the attracting magnet 162 is in contact with the inside of the cylinder 166. The upper surface 1621 of the attracting magnet 162 is located below the flange 167. That is, the attracting magnet 162 is housed in the cylinder 166. Thereby, the cylindrical portion 166 functions as a back yoke of the attracting magnet 162, and can strengthen the magnetic force of the attracting magnet 162. Then, the thrust plate 163 is disposed on the upper surface of the attracting magnet 162. The thrust plate 163 is housed inside the cylinder 166.

Then, after the anti-slip ring 19 is inserted into the holding recess 115, the bearing 13 is pressed into the holding recess 115 from above the anti-slip ring 19. Thereby, the drop-off preventing ring 19 is sandwiched and fixed between the lower end portion of the bearing 13 and the bottom surface of the bearing holding portion 1151.

The circuit board 30 is mounted on the substrate mounting portion 116 of the base portion 11. At this time, the boss 117 is passed through the substrate through hole 303 of the circuit board 30, and the vicinity of the inner flat surface 301 and the outer flat surface 302 is held by the substrate holding portion 17, so that the circuit board 30 is fixed to the base portion 11. The lead Wr connected to the external power supply is connected to the external connection portion 32 of the circuit board 30 fixed to the base portion 11. Then, the lead Wr is hooked to the lead drawing portion 1131 of the arm 113.

Then, the insulator 142 is attached to the stator core 141, and the wire is wound around the teeth 145 through the insulator 142 to form the coil 143. At this time, the lead wire 146 led out from the coil 143 is wound around the guide portion 18. At this time, the distal ends of the lead wires 146 are led out to the radially outer side of the radially outer edge of the stator 14.

Then, the core back 144 of the stator 14 is disposed outside the casing 112, and the stator 14 is mounted on the base 11. At this time, the stator 14 is fixed to the casing 112. Then, the end portions of the lead wires 146 led out from the coil 143 are fixed to the connection portions 31 of the circuit board 30 by soldering. By disposing the connection portion 31 radially outward of the stator 14, the lead wires 146 can be easily fixed to the connection portion 31.

The upper end portion of the shaft 12 is fixed to the boss portion 224 of the impeller 20. Then, the rotor 15 including the rotor magnet 151 and the magnet holder 152 is mounted on the hub 223. Then, the shaft 12 is inserted into the holding recess 115 from above. At this time, the shaft 12 penetrates the bearing 13. Then, the lower surface convex portion 122 of the shaft 12 is pushed into the through hole of the slip-off preventing ring 19. The diameter of the through hole of the retaining ring 19 is smaller than the outer diameter of the shaft 12, but the lower end of the shaft 12 can pass through the hole when elastically deformed. Then, the drop-off prevention ring 19 is moved to a position overlapping the drop-off prevention groove 121 of the shaft 12 in the radial direction. At this time, the lower surface convex portion 122 is in contact with the thrust plate 163. When the shaft 12 is mounted to the bearing 13, the radially outer surface of the stator 14 is radially opposed to the inner surface of the rotor magnet 151.

In the blower a thus assembled, the shaft 12 is mounted in the holding recess 115 of the casing 112 via the bearing 13, whereby the radially outer edge of the stator 14 faces the rotor magnet 151 with a gap therebetween in the radial direction. Then, by flowing a current to the coil 143 via the lead wire 146, a magnetic force is generated between the coil 143 and the rotor magnet 151. The rotational force acts on the rotor 15 by the attractive and repulsive forces of the magnetic force. Thereby, the motor 10, i.e., the shaft 12, rotates around the center axis J. Then, the impeller 20 fixed to the shaft 12 rotates to generate an air flow.

The embodiments of the present invention have been described above, but various modifications and combinations of the embodiments are possible within the scope of the gist of the present invention.

According to the present invention, the air conditioner can be used, for example, as a motor for rotating an impeller of the air blower.

Claims (14)

1. A motor has a rotor rotating about a central axis extending up and down,

the motor includes:

a shaft formed of a magnetic body and extending along the central axis;

a bearing rotatably supporting the shaft;

a housing located below the rotor and holding the bearing;

a columnar attracting magnet disposed so as to face a lower end surface of the shaft in an axial direction;

a attracting magnet holder held by the housing and accommodating the attracting magnet,

the attracting magnet holder includes:

a plate-like bottom portion that expands radially from the center axis;

a cylindrical portion extending upward from a radially outer edge of the bottom portion;

a flange portion extending radially outward from an upper end portion of the tube portion,

the flange portion is inclined with respect to the bottom portion.

2. The motor according to claim 1, wherein,

An axially upper surface of the flange portion and at least a portion of an axially lower surface of the flange portion are parallel.

3. The motor according to claim 1, wherein,

the thickness of the connecting portion between the flange portion and the cylindrical portion is equal to or smaller than the thickness of the flange portion.

4. The motor according to claim 1, wherein,

a fillet is provided on a radially outer side surface of a connecting portion between the flange portion and the tube portion.

5. The motor according to claim 1, wherein,

and a round corner is arranged at the connecting part of the bottom and the cylinder part.

6. The motor according to claim 1, wherein,

the flange portion has an upward shape as it goes radially outward.

7. The motor according to claim 1, wherein,

a thrust plate is disposed on the upper portion of the upper surface of the attracting magnet, and the thrust plate is directly opposed to the upper portion of the upper surface of the attracting magnet.

8. The motor of claim 7, wherein the motor is configured to control the motor,

the thrust plate has a thickness smaller than that of the cylindrical portion.

9. A motor has a rotor rotating about a central axis extending up and down,

The motor includes:

a shaft formed of a magnetic body and extending along a central axis;

a bearing rotatably supporting the shaft;

a housing located below the rotor and holding the bearing;

a columnar attracting magnet disposed so as to face a lower end surface of the shaft in an axial direction;

a attracting magnet holder held by the housing and accommodating the attracting magnet,

the attracting magnet holder includes:

a plate-like bottom portion that expands radially from the center axis;

a cylindrical portion extending upward from a radially outer edge of the bottom portion,

the motor has an annular anti-slip ring,

the anti-slip ring is axially directly opposite the bearing,

the inner diameter of the through hole of the anti-drop ring is smaller than the outer diameter of the shaft,

the slip-off prevention ring is axially clamped by the bearing and the housing.

10. The motor of claim 9, wherein the motor is configured to control the motor,

the lower end portion of the shaft coincides with the cylindrical portion in the radial direction.

11. The motor of claim 9, wherein the motor is configured to control the motor,

the attracting magnet occupies more than half of the cylindrical portion, and an upper surface of the attracting magnet is located below an upper end portion of the cylindrical portion.

12. The motor of claim 9, wherein the motor is configured to control the motor,

the anti-slip ring is a single component.

13. The motor of claim 9, wherein the motor is configured to control the motor,

the outer diameter of the anti-slip ring is the same as the outer diameter of the outermost side of the bearing.

14. The motor of claim 9, wherein the motor is configured to control the motor,

the outside diameter of the attracting magnet is larger than the diameter of the through hole of the anti-slip ring.