JP6007084B2 - Electric motor and fan motor - Google Patents

Description

  The present invention relates to an electric motor and a fan motor used for cooling a radiator of an automobile, for example.

  As an electric motor used for a fan motor, for example, there is a motor in which a cylindrical bearing holder (bearing housing) is fixed to a motor plate, and a stator around which a coil is wound is fixed by external fitting. . Two ball bearings are held in the bearing holder, and the rotating shaft of the rotor is rotatably supported via these two ball bearings.

Here, a reduced diameter portion is formed by a step on the inner peripheral surface of the bearing holder, and ball bearings are held at both ends of the reduced diameter portion, respectively. And the outer ring | wheel of each ball bearing contact | abuts to the level | step-difference part formed in the both ends of the diameter reduction part. On the other hand, a stopper washer is attached to one end of the rotating shaft, and a male screw portion is engraved on the other end.
Then, by screwing a lock nut into the male screw portion, the inner rings of the two ball bearings are pressed inward in the axial direction. On the other hand, the stepped portions formed at both ends of the reduced diameter portion restrict the movement of the outer ring of the ball bearing in the axial direction. Thereby, positioning of two ball bearings and a rotating shaft with respect to a bearing holder is performed (for example, refer to patent documents 1).

JP-A-8-31594

  By the way, in the above-described conventional technology, by tightening the lock nut, forces in opposite directions are applied to the outer ring and the inner ring of the two ball bearings, respectively. For this reason, depending on the tightening force of the lock nut, there is a problem that the slidability of a plurality of ball members provided between the inner ring and the outer ring inside the ball bearing is deteriorated and the function of the ball bearing may be impaired.

  Therefore, the present invention has been made in view of the above-described circumstances, and an electric motor and a fan that can reliably fix the ball bearing and the rotating shaft to the bearing holder without impairing the function of the ball bearing. A motor is provided.

In order to solve the above-described problems, an electric motor according to the present invention includes a stator in which coils are wound around a plurality of teeth, respectively, and two ball bearings fitted in the radial center of the stator. A bearing holder, a rotating shaft rotatably supported with respect to the stator via the two ball bearings, a rotor yoke provided on the rotating shaft and formed to cover the stator, An electric motor comprising a plurality of magnetic poles disposed on the rotor yoke so as to face the stator, wherein the electric motor is externally fitted to the bearing shaft and between the inner rings of the two ball bearings. together they are arranged providing a tubular spacer member for holding the relative position of the two ball bearings, regulating portion for regulating the movement to at least one of the bearing holder of the two ball bearings Provided between the two ball bearings, the axial length of said spacer member, a first ball bearing of said two ball bearings, a second ball of said two ball bearings in the regulating unit It is characterized by being set longer than the distance between the end surface on the bearing side .

By comprising in this way, the movement of the ball bearing with respect to a bearing holder can be controlled, preventing the force of a reverse direction being added to the inner ring | wheel and outer ring | wheel of two ball bearings, respectively. As a result, the ball bearing and the rotary shaft can be reliably prevented from coming off from the bearing holder without impairing the function of the ball bearing.
Moreover, the movement of the ball bearing can be regulated by effectively utilizing the dead space in the bearing holder. That is, by providing the restricting portion, it is possible to prevent the shaft length of the bearing holder from becoming long.

The electric motor according to the present invention is characterized in that the restricting portion is a convex portion formed to project from an inner peripheral surface of the bearing holder.
In this case, the bearing holder is formed by forming a metal plate into a cylindrical shape, and the restricting portion may be a cut-and-raised portion formed by cutting a part of the peripheral wall of the bearing holder radially inward. Good.

  With this configuration, the ball bearing and the rotary shaft can be reliably prevented from coming off from the bearing holder with a simple structure without impairing the function of the ball bearing.

  The electric motor according to the present invention is characterized in that the restricting portion is formed so as not to contact an inner ring of the two ball bearings.

  By comprising in this way, it can prevent that a control part contacts the inner ring | wheel of a ball bearing, and inhibits rotation of this inner ring | wheel.

  The electric motor according to the present invention is characterized in that the restricting portion is provided on a part of an inner peripheral surface of the bearing holder.

By comprising in this way, a ball bearing and a rotating shaft can be efficiently fixed with respect to a bearing holder with the minimum control part.
In addition, it is possible to prevent the roundness of the inner peripheral surface of the bearing holder from deteriorating as compared with the case where the restricting portion is provided over the entire inner peripheral surface of the bearing holder.

An electric motor according to the present invention, the first ball bearing, while the press-fitted into the bearing holder, said second ball bearing is characterized in that the insertion into the bearing holder.

  With this configuration, the ball bearing and the rotary shaft can be reliably prevented from coming off from the bearing holder with a simple structure.

A fan motor according to the present invention includes an electric motor and a fan blade that is attached to the electric motor and rotates with the rotation of the electric motor, and the electric motor has coils wound around a plurality of tooth portions, respectively. The stator is fixed to the center of the stator in the radial direction, and two ball bearings are fitted therein, and the two ball bearings are supported to be rotatable with respect to the stator. A rotating shaft; a rotor yoke provided on the rotating shaft and formed to cover the stator; and a plurality of magnetic poles disposed on the rotor yoke so as to face the stator, wherein the rotating shaft is in a horizontal direction. are arranged along the said bearing holder is a fan motor obtained by forming a metal plate into a cylindrical shape, the bearing holder is fitted to said rotary shaft, before Together are arranged between the inner rings of the two ball bearings are provided a cylindrical spacer member which holds the relative position of the two ball bearings, to form a drain hole in a part of the peripheral wall, the water drain hole the cut and raised portion which is cut and raised radially inward when forming, configured as the regulating portion for regulating the movement to at least one of the bearing holder of the two ball bearings, the cut-and-raised portion, the It is provided between two ball bearings, and the axial length of the spacer member is set so that the first ball bearing out of the two ball bearings and the second ball bearing out of the two ball bearings in the cut and raised portion. It is characterized by being set longer than the distance between the end surface on the two-ball bearing side .

By configuring in this way, it is possible to prevent the application of forces in opposite directions to the inner ring and the outer ring of the two ball bearings by using the cut-and-raised portion cut when the drain hole is formed. However, the movement of the ball bearing relative to the bearing holder can be restricted. Thus, without increasing the number of manufacturing steps, it is possible to prevent the function of the ball bearing from being impaired and to reliably prevent the ball bearing and the rotary shaft from coming off the bearing holder.
Moreover, the movement of the ball bearing can be regulated by effectively utilizing the dead space in the bearing holder. That is, by providing the cut-and-raised portion, it is possible to prevent the shaft length of the bearing holder from becoming long.

  The fan motor according to the present invention is characterized in that the cut and raised portion is formed so as not to contact the inner rings of the two ball bearings.

  By comprising in this way, it can prevent that a cut-and-raised part contacts the inner ring | wheel of a ball bearing, and inhibits rotation of this inner ring | wheel.

  In the fan motor according to the present invention, the first ball bearing of the two ball bearings is press-fitted and fixed to the bearing holder, while the second ball bearing of the two ball bearings is attached to the bearing holder. The holding portion is a cylindrical spacer member that is externally fitted to the rotary shaft and is disposed between the inner rings of the two ball bearings, and the axial length of the spacer member is It is characterized by being set longer than the distance between the first ball bearing and the end surface of the cut and raised portion on the second ball bearing side.

  With this configuration, it is possible to provide a fan motor that can reliably prevent the ball bearing and the rotary shaft from coming off from the bearing holder with a simple structure.

ADVANTAGE OF THE INVENTION According to this invention, the movement of the ball bearing with respect to a bearing holder can be controlled, preventing that the force of a reverse direction is added to the inner ring | wheel and outer ring | wheel of two ball bearings, respectively. As a result, the ball bearing and the rotary shaft can be reliably prevented from coming off from the bearing holder without impairing the function of the ball bearing.
Moreover, the movement of the ball bearing can be regulated by effectively utilizing the dead space in the bearing holder. That is, by providing the restricting portion, it is possible to prevent the shaft length of the bearing holder from becoming long.

In addition, by using the raised part that is raised when forming the drain hole, the ball against the bearing holder is prevented from applying forces in opposite directions to the inner ring and the outer ring of the two ball bearings, respectively. The movement of the bearing can be restricted. Thus, without increasing the number of manufacturing steps, it is possible to prevent the function of the ball bearing from being impaired and to reliably prevent the ball bearing and the rotary shaft from coming off the bearing holder.
Furthermore, the movement of the ball bearing can be regulated by effectively using the dead space in the bearing holder. That is, by providing the cut-and-raised portion, it is possible to prevent the shaft length of the bearing holder from becoming long.

It is a longitudinal cross-sectional view of the fan motor in 1st Embodiment of this invention. It is the A section enlarged view of FIG. It is a longitudinal cross-sectional view of the bearing holder in 2nd Embodiment of this invention.

(First embodiment)
(Fan motor)
Next, a first embodiment of the present invention will be described with reference to FIGS.
FIG. 1 is a longitudinal sectional view of the fan motor, and FIG. 2 is an enlarged view of part A of FIG. Note that an arrow F in FIG. 1 indicates the front side of the vehicle. In the following description, the direction indicated by the arrow F will be referred to as “front”, and the direction opposite to the direction indicated by the arrow F will be referred to as “rear” (the same applies to the following second embodiment).

  As shown in FIGS. 1 and 2, the fan motor 1 is used for cooling the radiator of the vehicle, and is installed on the rear side of the vehicle body of a radiator (not shown) (located on the right side of the fan motor 1 in the figure). The fan motor 1 includes an electric motor 2 that is a drive unit and a fan body 3 that is rotationally driven by the electric motor 2.

(Electric motor)
The electric motor 2 is a so-called outer rotor type brushless motor, and includes a stator 11 in which a plurality of coils 10 for excitation are wound around a plurality of teeth 18b projecting radially outward of a stator core 18 described later. A bracket 12 that supports the stator 11, a rotor 14 that is rotatably supported by the bracket 12, and a control unit 15 that feeds back the rotation of the rotor 14 and controls energization of the coil 10. And the fan motor 1 is arrange | positioned at the vehicle body (not shown) so that the rotating shaft 13 of the rotor 14 may follow a front-back direction.
In the following description, in a state where the fan motor 1 is attached to the vehicle body, the vertical lower side (lower side in FIG. 1) of the fan motor 1 is simply referred to as lower side, and the vertical upper side of the fan motor 1 (upper side in FIG. 1). Is simply referred to as “above” (the same applies to the second embodiment below).

(bracket)
The bracket 12 is formed in a substantially disk shape, and a plurality of fixed arms 12a that are fastening portions are extended to the outer peripheral edge thereof. The fixed arm 12a is fastened and fixed to a fan shroud 16 that surrounds the fan body 3 and guides the air flow. The fan shroud 16 is fixedly installed on the rear side of the radiator.
In addition, a substantially cylindrical water intrusion restriction wall 25 is integrally formed on the outer peripheral portion on the front side of the bracket 12. The water intrusion restriction wall 25 forms a labyrinth portion 91 in cooperation with a rotor yoke 28 and a fan boss 34 which will be described later, and is configured so that water does not easily enter the space between the electric motor 2 and the fan body 3. It is a thing.

  Further, on the front side of the bracket 12, there are a first cylindrical wall 26 having a diameter smaller than the water intrusion restriction wall 25 and a second cylindrical wall 27 having a diameter smaller than the first cylindrical wall 26. It is integrally molded. These cylindrical walls 26 and 27 form a labyrinth portion 92 in cooperation with a stator core 18 and a rotor yoke 28 which will be described later, and are configured so that water does not easily enter the electric motor 2. That is, water droplets that are about to flow from the upper outer peripheral side of the bracket 12 to the center side where the electrical joint and the control unit 15 are arranged are dropped along the outer peripheral surfaces of the cylindrical walls 26 and 27. It has become.

  Further, a boss portion 50 is provided on the inner side of the cylindrical wall 27 on the front side of the bracket 12 so as to protrude forward at a substantially central position in the radial direction. The boss portion 50 is formed in a substantially cylindrical shape, and an inner peripheral surface 51 is formed so as to gradually increase in diameter toward the front from the reduced diameter portion 51a formed on the proximal end side. The inclined portion 51b is formed, and the enlarged diameter portion 51c is formed at the front end of the inclined portion 51b and has a diameter larger than that of the reduced diameter portion 51a.

  Furthermore, a stator base portion 52 on which the stator core 18 of the stator 11 is placed is formed at the front end of the boss portion 50. The stator pedestal portion 52 is formed by cutting out the outer peripheral portion of the portion corresponding to the enlarged diameter portion 51c of the boss portion 50 over the entire periphery. A ring portion 53 is formed on the inner peripheral edge of the stator base portion 52 by cutting the outer peripheral portion of the enlarged diameter portion 51c over the entire periphery. The stator pedestal 52 is formed with a plurality of female screw portions 54 for fixing the stator core 18.

(Stator)
The stator core 18 is formed by laminating a large number of magnetic steel plates and has a substantially annular core body 18a. The core main body 18 a is placed on the stator pedestal 52. A part of the inner peripheral surface of the core body 18 a is externally fitted to the ring portion 53. Further, a plurality of through holes 55 are formed in the core body 18 a at locations corresponding to the female screw portions 54 of the stator pedestal portion 52. The core body 18 a is fastened and fixed to the stator base portion 52 by inserting the bolts 56 into the respective through holes 55 from the front side and screwing them into the female screw portions 54.

The core body 18a is integrally formed with a plurality of teeth 18b projecting radially outward in the radial direction. A coil 10 is wound around each tooth 18b.
The tip of the tooth 18 b extends to reach between the first cylindrical wall 26 and the second cylindrical wall 27 formed on the bracket 12. A labyrinth portion 92 is formed by the teeth 18 b formed in this way and the cylindrical walls 26 and 27.

(Bearing holder)
Furthermore, a bearing holder 60 for rotatably supporting the rotating shaft 13 of the rotor 14 is fitted inside the boss portion 50. The bearing holder 60 is obtained by subjecting a metal plate to deep drawing, a stepped cylindrical portion 61 formed in a two-stepped step shape, and an outer flange bent at the front end of the stepped cylindrical portion 61. Part 62.
The stepped cylindrical portion 61 is fitted into the reduced diameter cylindrical portion 61 a fitted into the reduced diameter portion 51 a of the inner peripheral surface 51 of the boss portion 50 and the enlarged diameter portion 51 c of the inner peripheral surface 51 of the boss portion 50. The enlarged diameter cylindrical portion 61b and a stepped portion 61c that connects the reduced diameter cylindrical portion 61a and the enlarged diameter cylindrical portion 61b.

The outer diameter of the reduced diameter cylindrical portion 61 a is set to a size that is inserted into the reduced diameter portion 51 a of the boss portion 50. Further, the outer diameter of the enlarged diameter cylindrical portion 61 b is set to a size that is inserted into the enlarged diameter portion 51 c of the boss portion 50.
When the bearing holder 60 is attached to the boss portion 50, the front end (front side) of the reduced diameter cylindrical portion 61a is connected to the connecting portion between the inclined portion 51b and the enlarged diameter portion 51c of the inner peripheral surface 51 of the boss portion 50. positioned. On the other hand, the rear end (rear side) of the reduced diameter cylindrical portion 61 a slightly protrudes from the rear end (rear side) of the boss portion 50. Further, the enlarged diameter cylindrical portion 61b extends from the front end (front side) of the reduced diameter cylindrical portion 61a to the front end surface (front side) of the stator core 18. The outer flange portion 62 is in contact with the core body 18 a on the front side of the stator core 18.

  A plurality of through holes 63 are formed in the outer flange portion 62 at locations corresponding to the through holes 55 of the core body 18a. Bolts 56 are also inserted into the through holes 63. That is, the core body 18 a and the outer flange portion 62 are fastened together with the stator base portion 52 of the boss portion 50 by the bolt 56.

Further, a projection (boss) is formed radially inwardly by pressing at a part of the upper portion near the stepped portion 61c of the reduced diameter cylindrical portion 61a, whereby the convex portion 64 is formed on the inner peripheral surface of the bearing holder 60. Is formed. Further, near the step portion 61c of the reduced diameter cylindrical portion 61a, a drain hole 65 is formed in a part of the lower portion.
A rear-side ball bearing (second ball bearing) 93 for rotatably supporting the rear end of the rotary shaft 13 is inserted into the reduced diameter cylindrical portion 61a behind the convex portion 64 and the drain hole 65. Has been. Further, a front side ball bearing (first ball bearing) 94 for rotatably supporting the front side of the rotating shaft 13 is press-fitted into the enlarged diameter cylindrical portion 61b. Thereby, it will be in the state by which the convex part 64 and the drainage hole 65 were provided between the two ball bearings 93 and 94, respectively.

Here, the drain hole 65 formed in the reduced diameter cylindrical portion 61 a has a role of draining water that has entered the bearing holder 60. Further, the convex portion 64 formed in the reduced diameter cylindrical portion 61a has a role of restricting movement of the rear side ball bearing 93 in the axial direction.
That is, when the rear side ball bearing 93 tries to move toward the front side ball bearing 94 (toward the front side), the outer ring 93b of the rear side ball bearing 93 comes into contact with the convex portion 64, and the rear side ball bearing 93 The movement to the front side ball bearing 94 side is regulated.

  The protrusion height H1 of the convex portion 64 from the reduced diameter cylindrical portion 61a is a height that contacts only the outer ring 93b of the rear side ball bearing 93 (in other words, a height at which the convex portion 64 does not contact the inner ring 93a. And a height that does not contact a plurality of ball members disposed between the inner ring and the outer ring of the ball bearing, or a cage that holds the plurality of ball members and a cover body that protects the ball members. If both the inner ring 93a and the outer ring 93b of the rear side ball bearing 93 come into contact with the convex portion 64, the inner ring 93a and the outer ring 93b are caused by the sliding frictional resistance generated between the rear side ball bearing 93 and the convex portion 64. It is because it becomes difficult to rotate each separately. In such a case, the function of the rear side ball bearing 93 is impaired.

  A wave washer 95 is disposed on the rear end surface (rear) of the rear side ball bearing 93, and a wave washer support 96 is disposed rearward of the wave washer 95. The wave washer support 96 is for preventing the wave washer 95 from falling off the bearing holder 60, and is press-fitted and fixed inside the reduced diameter cylindrical portion 61a.

(Rotor)
The rotating shaft 13 of the rotor 14 is rotatably supported by the bearing holder 60 configured as described above. The rotary shaft 13 is formed in a stepped shape, and is a shaft main body 21 that is rotatably supported by two ball bearings 93 and 94, and a rotor yoke support portion that is formed with a diameter increased by a step in front of the shaft main body 21. 22, a fan support portion 23 having a diameter reduced by a step in front of the rotor yoke support portion 22, and a male screw portion (not shown) having a diameter reduced by a step in front of the fan support portion 23.

  The rear of the shaft main body 21 protrudes rearward from the rear side ball bearing 93, and a male screw portion (not shown) is engraved on the protruding portion. Then, by screwing the nut 97 into the male thread portion, the nut 97 comes into contact with the inner ring 93a of the rear side ball bearing 93 on the outer side in the axial direction. Further, the step surface 22 a of the rotor yoke support portion 22 abuts against the inner ring 94 a of the front side ball bearing 94. Then, the rear side ball bearing 93 and the front side ball bearing 94 are pressed toward each other.

  A cylindrical collar (spacer member) 70 is externally fitted to the shaft body 21 between the rear side ball bearing 93 and the front side ball bearing 94. Both ends of the collar 70 are in contact with the inner side in the axial direction of the inner ring 93a of the rear side ball bearing 93 and the inner side in the axial direction of the inner ring 94a of the front side ball bearing 94, respectively. Thereby, the displacement of the rear side ball bearing 93 and the front side ball bearing 94 is restricted, and the shaft body 21 is rotatably supported by the rear side ball bearing 93 and the front side ball bearing 94. Thus, the collar 70 has a role as the holding portion 71 that holds the relative positions of the two ball bearings 93 and 94.

Here, the length of the collar 70 is L1, and the end surface on the rear side ball bearing 93 side of the front side ball bearing 94 press-fitted into the enlarged diameter cylindrical portion 61b and the convex portion 64 formed on the reduced diameter cylindrical portion 61a. When the distance between 64a is L2, the total length L1 and the distance L2 are
L1> L2 (1)
It is set to satisfy.

  A rotor yoke 28 constituting the rotor 14 is supported on the rotor yoke support portion 22 of the rotary shaft 13. The rotor yoke 28 is formed in a bottomed cylindrical shape, and a fitting portion 32 is formed at the radial center of the bottom portion 28a. The rotor yoke support portion 22 is press-fitted into the fitting portion 32 with the opening 28b of the rotor yoke 28 facing the bracket 12 side. That is, the rotor yoke 28 is formed so as to cover the stator 11 from the front surface (front).

Here, the formation method of the fitting part 32 is demonstrated concretely.
First, burring is performed on the bottom portion 28a of the rotor yoke 28 to form a burring portion 32a that rises toward the bracket 12 side. Thereafter, a cylindrical jig (not shown) is inserted into the burring portion 32a. The diameter of the cylindrical jig is set to be slightly smaller than the diameter of the rotor yoke support 22.

Subsequently, the tip of the burring portion 32a is pressed in the axial direction to slightly buckle deform the burring portion 32a. Then, the thickness of the burring portion 32a becomes slightly thicker than the thickness of the bottom portion 28a, and the inner diameter of the burring portion 32a becomes substantially the same as the diameter of the jig, so that the fitting portion 32 is formed.
By forming the fitting portion 32 in this way, the thickness of the burring portion 32a is sufficiently ensured, and the pressure input to the rotor yoke support portion 22 can be sufficiently ensured. For this reason, the rotating shaft 13 and the rotor yoke 28 can be firmly fixed.

  A plurality of magnets 30 are provided on the inner peripheral surface of the circumferential wall 28c of the rotor yoke 28 so that the magnetic poles are in order along the circumferential direction. These magnets 30 are in a state of facing the outer peripheral surface of the teeth 18b of the stator 11 in the radial direction. Further, a reinforcing flange portion 33 is formed on the peripheral wall 28c of the rotor yoke 28 at the edge on the opening 28b side so as to be bent radially outward.

The edge on the opening 28b side of the rotor yoke 28 including the reinforcing flange 33 faces the water intrusion restriction wall 25 and the first cylindrical wall 26 of the bracket 12 in a state where the rotor 14 is assembled. A labyrinth portion 92 is formed by the water intrusion restriction wall 25, the first cylindrical wall 26, and the peripheral wall 28 c of the rotor yoke 28.
The reinforcing flange portion 33 also functions as a restriction wall that restricts water droplets that have dropped onto the outer peripheral surface of the peripheral wall 28c of the rotor yoke 28 from flowing into the opening 28b side of the peripheral wall 28c.

(Fan body)
The fan main body 3 is supported on the fan support portion 23 of the rotating shaft 13. The fan body 3 is obtained by integrally molding a bottomed cylindrical fan boss 34 and a fan blade 35 with resin. Then, the bottom wall 34 b of the fan boss 34 is attached to the fan support portion 23 with the opening 34 a of the fan boss 34 facing the bracket 12 side.

More specifically, the bottom wall 34b of the fan boss 34 is formed with an opening 36 at the radial center. A metal plate 37 is provided in the opening 36 so as to close the opening 36.
The metal plate 37 is integrated with the fan boss 34 by, for example, insert molding. The metal plate 37 constitutes a shaft fixing portion for directly fixing the fan main body 3 to the rotating shaft 13. A fitting hole 38 into which the fan support 23 of the rotating shaft 13 is fitted is formed at the radial center of the metal plate 37.

  Here, the fan support portion 23 is subjected to D-cut (one-sided) processing. Thereby, the fan support part 23 has a D-shaped cross section. On the other hand, the fitting hole 38 of the metal plate 37 is also formed in a D shape so as to correspond to the shape of the fan support portion 23. By forming the fan support portion 23 and the fitting hole 38 in this way, it is possible to prevent relative rotation between the fan support portion 23 and the metal plate 37 in a state where the metal plate 37 is fitted in the fan support portion 23. Can do.

Further, when the metal plate 37 is fitted into the fan support portion 23, the metal plate 37 is fitted after the washer 39 is attached to the fan support portion 23. By attaching the washer 39, a predetermined clearance can be secured between the rotor yoke 28 and the fan boss 34, and the fan boss 34 is prevented from contacting the rotor yoke 28.
Then, after attaching the washer 39 and the metal plate 37 to the fan support portion 23, the nut 40 is screwed into a male screw portion (not shown) formed at the front end (front) of the rotating shaft 13. Thereby, the washer 39 and the metal plate 37 are fastened together with the fan support part 23, and the rotating shaft 13 and the fan main body 3 are integrated.

  When the fan main body 3 is attached to the rotary shaft 13, the edge on the opening 34 a side of the peripheral wall 34 c of the fan boss 34 is located on the radially outer side of the water intrusion restriction wall 25. It is supposed to wrap. As described above, the labyrinth portion 91 is formed by the water intrusion restriction wall 25, the peripheral wall 34 c of the fan boss 34, and the peripheral wall 28 c of the rotor yoke 28.

(Fan motor assembly method)
Next, a method for assembling the fan motor 1 will be described.
First, the two ball bearings 93 and 94 and the collar 70 are assembled to the bearing holder 60 in a single product state. Specifically, first, the front side ball bearing 94 is press-fitted into the enlarged diameter cylindrical portion 61 b of the bearing holder 60. At this time, the front side ball bearing 94 is press-fitted from the outer flange portion 62 of the bearing holder 60 so as to have a constant size. Thereby, positioning of the front side ball bearing 94 is performed.

Subsequently, a shaft (not shown) serving as a jig is inserted into the front side ball bearing 94. Note that the shaft diameter of the jig is set to be approximately equal to or slightly narrower than the shaft diameter of the rotary shaft 13.
Next, the collar 70 is inserted into a jig (not shown) from the opening side of the reduced diameter cylindrical portion 61a. Subsequently, the rear side ball bearing 93 is inserted into the reduced diameter cylindrical portion 61a. At this time, the rear side ball bearing 93 is inserted until it abuts against the end face of the collar 70.

  Next, the wave washer 95 is inserted from the opening side of the reduced diameter cylindrical portion 61a. Then, a wave washer support 96 is press-fitted into the inner peripheral surface of the reduced diameter cylindrical portion 61a from above. Thereafter, the jig is removed, and the assembly of the two ball bearings 94, 94 and the collar 70 to the bearing holder 60 is completed, and the unit of the bearing holder 60 is completed. In a state where the assembling is completed, the wave washer 95 causes the rear side ball bearing 93 to be pressurized.

  Subsequently, the stator 11 is placed on the stator base portion 52 formed on the boss portion 50 of the bracket 12. Then, a unitized bearing holder 60 is inserted into the inner peripheral surface 51 of the boss portion 50 from the stator 11 side. At this time, the bearing holder 60 is inserted until the outer flange portion 62 of the bearing holder 60 contacts the core body 18a of the stator core 18.

  Thereafter, the position of the through hole 55 of the stator core 18 and the position of the through hole 63 formed in the outer flange portion 62 of the bearing holder 60 are matched, and these through holes 55 and 60 are placed on the outer flange portion 62 from above. Insert the bolt 56. Then, the stator 11 and the bearing holder 60 are fastened together with the stator base portion 52 of the boss portion 50. Thereby, the assembly of the stator 11 and the bearing holder 60 is completed.

  Next, the rotating shaft 13 is inserted into the bearing holder 60 from the front side ball bearing 94 side. Here, the rotor yoke 28 is press-fitted and fixed to the rotor yoke support portion 22 of the rotating shaft 13 in advance. After inserting the rotating shaft 13 into the bearing holder 60, a nut 97 is screwed into a male screw portion (not shown) formed at the front end (rear end) of the shaft main body 21.

  Accordingly, the nut 97 abuts on the outer side in the axial direction of the inner ring 93 a of the rear side ball bearing 93. Further, the step surface 22 a of the rotor yoke support portion 22 abuts on the inner ring 94 a of the front side ball bearing 94. The inner side of the inner ring 93a of the rear side ball bearing 93 and the inner side of the inner side 94a of the front side ball bearing 94 are in contact with both ends of the collar 70, respectively. Then, the displacement of the rotary shaft 13 in the removal direction with respect to the bearing holder 60 is restricted, and the assembly of the rotor 14 to the bearing holder 60 is completed.

  Here, since the inner side of the inner ring 93a of the rear side ball bearing 93 and the inner side of the inner side 94a of the front side ball bearing 94 are in contact with both ends of the collar 70, the nut 97 is fastened to the rotary shaft 13. The load caused by this is applied to the inner rings 93a and 94a of the ball bearings 93 and 94, and is not applied to the outer rings 93b and 94b of the ball bearings 93 and 94.

  Next, a washer 39 is inserted into the fan support portion 23 of the rotary shaft 13, and a metal plate 37 of the fan body 3 is inserted from above the washer 39. Then, the nut 40 is screwed into a male screw portion (not shown) formed at the front end (front end) of the fan support portion 23. Thereby, the washer 39 and the metal plate 37 are fastened together with the fan support portion 23, and the assembly of the fan body 3 to the rotating shaft 13 is completed. And the control unit 15 is assembled | attached to the bracket 12, and the assembly of the fan motor 1 is completed.

(Operation of fan motor and bearing holder)
Under such a configuration, a magnetic field is generated by selectively supplying current to the plurality of coils 10 wound around the teeth 18 b of the stator 11, and this magnetic field and the magnet 30 provided on the rotor yoke 28 are provided. Magnetic attractive force and repulsive force are generated between them. Thereby, the rotor 14 and the fan main body 3 rotate integrally, and supply cooling air toward a radiator.

Here, the case where the pressure input of the front side ball bearing 94 with respect to the diameter-enlarged cylindrical portion 61b of the bearing holder 60 is reduced due to, for example, an unexpected load greater than the removal load will be described.
Since the stepped cylindrical portion 61 of the bearing holder 60 is formed with a reduced diameter cylindrical portion 61a at the rear portion, when the pressure input of the front side ball bearing 94 to the enlarged diameter cylindrical portion 61b decreases, the stepped cylindrical portion 61 The stepped portion 61c restricts movement of the front side ball bearing 94 to the rear (reduced diameter cylindrical portion 61a side).

On the other hand, there is a risk that the front side ball bearing 94 may move forward due to a decrease in pressure input of the front side ball bearing 94 to the enlarged diameter cylindrical portion 61b. In such a case, since the two ball bearings 93 and 94, the collar 70, and the rotary shaft 13 are integrated, the rear side ball bearing 93 also moves forward as the front side ball bearing 94 moves to the front side. .
Then, the outer ring 93 b of the rear side ball bearing 93 comes into contact with the convex portion 64 of the bearing holder 60. As a result, the forward movement of the rear side ball bearing 93 is restricted. Accordingly, forward movement of the front side ball bearing 94, the collar 70, and the rotary shaft 13 is restricted. For this reason, it is prevented that the two ball bearings 93 and 94 and the rotor 14 fall off from the bearing holder 60 due to an unexpected load more than the removal load.

(effect)
Therefore, according to the first embodiment described above, by forming the convex portion 64 on the inner peripheral surface of the bearing holder 60, the movement of the two ball bearings 93 and 94 with respect to the bearing holder 60 is ensured with a simple structure. Can be regulated. Further, when the rotary shaft 13 is fixed to the bearing holder 60, the load generated by tightening the nut 97 into the male thread portion (not shown) of the rotary shaft 13 is applied to the inner rings 93 a and 94 a of the ball bearings 93 and 94. Since the outer rings 93b and 94b of the respective ball bearings 93 and 94 are not applied, it is possible to prevent reverse forces from being applied to the inner rings 93a and 94a and the outer rings 93b and 94b of the two ball bearings 93 and 94, respectively. .
Therefore, it is possible to reliably prevent the two ball bearings 93 and 94 and the rotary shaft 13 from coming off while preventing the functions of the two ball bearings 93 and 94 from being impaired.

  Further, the protrusion height H1 of the convex portion 64 from the reduced diameter cylindrical portion 61a is set to a height that contacts only the outer ring 93b of the rear side ball bearing 93. For this reason, it is possible to prevent the inner ring 93a and the outer ring 93b from becoming difficult to rotate separately due to the sliding frictional resistance generated between the rear side ball bearing 93 and the convex portion 64, respectively. Therefore, the function of the rear side ball bearing 93 can be reliably prevented from being impaired.

  Furthermore, by forming the convex portion 64 only on a part of the reduced diameter cylindrical portion 61 a of the bearing holder 60, the movement of the two ball bearings 93 and 94 with respect to the bearing holder 60 is efficiently regulated with the minimum protrusion. be able to. Further, it is possible to prevent the roundness of the reduced diameter cylindrical portion 61a from deteriorating as compared with the case where the convex portion 64 is formed over the entire circumference on the inner peripheral surface of the reduced diameter cylindrical portion 61a. For this reason, the increase in the manufacturing cost of the bearing holder 60 can be prevented.

  And since the convex part 64 is formed between the two ball bearings 93 and 94, the movement of the two ball bearings 93 and 94 can be controlled using the dead space in the bearing holder 60 effectively. . That is, even if the convex portion 64 is formed to restrict the movement of the two ball bearings 93 and 94, it is possible to prevent the axial length of the bearing holder 60 from becoming long.

  Further, the length of the collar 70 is L1, and a front side ball bearing 94 press-fitted into the enlarged diameter cylindrical portion 61b and an end face 64a on the rear side ball bearing 93 side of the convex portion 64 formed in the reduced diameter cylindrical portion 61a. The total length L1 and the distance L2 are set so as to satisfy the formula (1), where L2 is the distance between the two. For this reason, when the nut 97 is fastened to the male thread portion (not shown) of the rotating shaft 13, the outer ring 93 b and the convex portion 64 abut before the collar 70 abuts against the inner ring 93 a of the rear side ball bearing 93. Can be prevented.

Here, when the outer ring 93b and the convex portion 64 come into contact with the inner ring 93a of the rear side ball bearing 93 before the collar 70 comes into contact, the load that is pressed forward by the nut 97 on the inner ring 93a. It takes. On the other hand, the outer ring 93b is subjected to a load that is pressed rearward by coming into contact with the convex portion 64.
That is, it is possible to prevent the outer ring 93b and the projection 64 from coming into contact with the inner ring 93a of the rear side ball bearing 93 before the collar 70 comes into contact, so that the inner ring 93a and the outer ring 93b of the rear side ball bearing 93 can be prevented. In addition, it is possible to prevent a reverse force from being applied. Therefore, the rear side ball bearing 93, the front side ball bearing 94, and the rotation with respect to the bearing holder 60 are simply configured to reliably prevent the function of the rear side ball bearing 93 from being impaired and only to form the convex portion 64. The shaft 13 can be reliably prevented from coming off.

Of the two ball bearings 93 and 94 fitted in the bearing holder 60, the rear side ball bearing 93 is inserted into the reduced diameter cylindrical portion 61a, while the front side ball bearing 94 is replaced with an enlarged diameter cylinder. The portion 61b is press-fitted. Here, the dimensional management such as the roundness of the reduced diameter cylindrical portion 61a to be inserted becomes gentler than the dimensional management such as the roundness of the enlarged diameter cylindrical portion 61b to be press-fitted.
That is, neither of the two ball bearings 93 and 94 is press-fitted into the bearing holder 60, and only the front-side ball bearing 94 is press-fitted, so that the manufacturing cost of the bearing holder 60 can be reduced. . Further, since only the front-side ball bearing 94 needs to be press-fitted, the assembly workability can be improved as compared with the case where both of the two ball bearings 93 and 94 are press-fitted.

  Further, in addition to inserting the rear side ball bearing 93 into the reduced diameter cylindrical portion 61a of the bearing holder 60, when the rear side ball bearing 93 is assembled to the reduced diameter cylindrical portion 61a, the reduced diameter cylindrical portion 61a is attached to the rear side ball bearing 61. After inserting the bearing 93, the wave washer 95 is inserted. Then, a wave washer support 96 is press-fitted into the reduced diameter cylindrical portion 61 a from above, and a pressure is applied to the rear side ball bearing 93. Therefore, by applying an appropriate pressure to the rear side ball bearing 93 while absorbing the dimensional variation of the bearing holder 60, the two ball bearings 93, 94, and the collar 70, the rolling surface (ball member) of each ball bearing is applied. Can be stabilized. As a result, the life of the fan motor 1 can be extended.

  When both of the two ball bearings 93 and 94 are press-fitted into the bearing holder 60, the rolling of the ball bearings 93 and 94 is caused by vibration due to slight backlash or a decrease in rigidity of the bearing holder 60 due to deterioration during connection or the like. It becomes difficult to stabilize the surface. For this reason, it becomes difficult to extend the life of the fan motor 1 effectively.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIG. In addition, the same code | symbol is attached | subjected and demonstrated to the same aspect as 1st Embodiment.
FIG. 3 is a longitudinal sectional view of the bearing holder in the second embodiment, and corresponds to FIG.
In the second embodiment, the fan motor 1 is used for cooling a radiator of a vehicle, and is installed on the rear side of a vehicle body of a radiator (not shown). The fan motor 1 includes an electric motor 2 that is a drive unit, and an electric motor. The fan main body 3 that is rotationally driven by the motor 2 is the same as the first embodiment.

The electric motor 2 is a so-called outer rotor type brushless motor, and includes a stator 11, a bracket 12, a rotor 14, and a control unit 15, and a rotating shaft 13 of the rotor 14 extends in the front-rear direction. Thus, it is the same as that of the above-mentioned 1st Embodiment also in the point arrange | positioned at a vehicle body (not shown).
Furthermore, the point that the rotating shaft 13 of the rotor 14 is rotatably supported by the bearing holder 160 fitted in the boss portion 50 of the bracket 12 is the same as in the first embodiment. Further, the bearing holder 160 is obtained by performing deep drawing on a metal plate, and is formed by bending a stepped cylindrical portion 61 formed in a two-stepped shape and a front end of the stepped cylindrical portion 61. The point comprised by the outer flange part 62 is the same as that of the above-mentioned 1st Embodiment.

(Bearing holder)
Here, the difference between the first embodiment and the second embodiment described above is that the convex portion 64 is formed on the inner peripheral surface of the bearing holder 60 in the first embodiment, whereas the second embodiment is different. Then, in the bearing holder 160, a cut and raised portion 164 is formed instead of the convex portion 64.
As shown in FIG. 3, when the cut-and-raised portion 164 forms the drain hole 165 near the stepped portion 61c below the reduced diameter cylindrical portion 61a, a part of the reduced diameter cylindrical portion 61a is directed radially inward. It is a metal piece formed by cutting and raising.

Here, the protruding height H <b> 2 of the cut-and-raised portion 164 from the reduced diameter cylindrical portion 61 a is set to a height that contacts only the outer ring 93 b of the rear side ball bearing 93.
Further, when the distance between the front-side ball bearing 94 press-fitted into the bearing holder 60 and the end surface 164a of the cut-and-raised portion 164 on the rear-side ball bearing 93 side is L3, the total length L1 of the collar 70 and the distance L3 is
L1> L3 (2)
It is set to satisfy.

  Therefore, according to the second embodiment described above, the same effects as those of the first embodiment described above can be achieved. In addition to this, using the cut and raised portion 164 cut when the drain hole 165 is formed, the movement of the two ball bearings 93 and 94 is reliably restricted without increasing the number of manufacturing steps. It can prevent impairing the function of the two ball bearings 93 and 94.

The present invention is not limited to the above-described embodiment, and includes various modifications made to the above-described embodiment without departing from the spirit of the present invention.
For example, in the first embodiment described above, the convex portion 64 is formed between the two ball bearings 93, 94 of the reduced diameter cylindrical portion 61a in order to restrict the movement of the rear side ball bearing 93 with respect to the bearing holder 60. Explained the case. In the second embodiment described above, the cut-and-raised portion 164 is provided between the two ball bearings 93 and 94 of the reduced diameter cylindrical portion 61a in order to restrict the movement of the rear side ball bearing 93 with respect to the bearing holder 160. The case of forming was described.
However, the present invention is not limited to these, and the bearing holders 60 and 160 may be formed so as to restrict the movement of at least one of the two ball bearings 93 and 94.

More specifically, for example, the following configurations are exemplified.
(1) A convex portion 64 is formed on the inner peripheral surface of the reduced diameter cylindrical portion 61a over the entire circumference.
(2) The drainage hole 65 is formed in the bearing holder 60 by press working, and the burr formed at the periphery of the opening of the drainage hole 65 at this time restricts the movement of the rear side ball bearing 93 relative to the bearing holder 60. Use as a thing.
(3) A convex portion or an annular ring is separately attached to the inner peripheral surfaces of the bearing holders 60, 160, and these convex portions or the annular ring are moved with respect to the bearing holders 60, 160 of the two ball bearings 93, 94. Is used as a regulation.
(4) Between the two ball bearings 93 and 94 of the reduced diameter cylindrical portion 61a, the front side of the front side ball bearing 94 of the enlarged diameter cylindrical portion 61b without forming the convex portion 64 and the cut and raised portion 164, That is, the convex part 64 and the cut-and-raised part 164 are formed at the connection part between the enlarged diameter cylindrical part 61 b and the outer flange part 62.

  Further, in the above-described embodiment, a case where the convex portions 64 and the cut-and-raised portions 164 that restrict the movement of the rear-side ball bearing 93 are formed in the bearing holders 60 and 160 of the electric motor 2 that is used as the fan motor 1. explained. However, the present invention is not limited to this, and various electric motors having a structure that supports the two ball bearings 93 and 94 by using the bearing holders 60 and 160 are convex portions for restricting the movement of the ball bearings 93 and 94. 64, the cut-and-raised portion 164, and the like can be employed.

DESCRIPTION OF SYMBOLS 1 Fan motor 2 Electric motor 3 Fan main body 10 Coil 11 Stator 13 Rotating shaft 14 Rotor 28 Rotor yoke 30 Magnet (magnetic pole)
35 Fan blade 60, 160 Bearing holder 64 Convex portion 65, 165 Drain hole 70 Color (spacer member)
71 Holding part 93 Rear side ball bearing (ball bearing: second ball bearing)
94 Front side ball bearing (ball bearing: first ball bearing)
164 Raising part

Claims (9)

A stator having coils wound around a plurality of teeth,
A bearing holder fixed at the radial center of the stator and having two ball bearings fitted therein;
A rotating shaft rotatably supported with respect to the stator via the two ball bearings;
A rotor yoke provided on the rotating shaft and formed to cover the stator;
An electric motor comprising a plurality of magnetic poles arranged to face the stator on the rotor yoke,
The bearing holder is provided with a cylindrical spacer member that is externally fitted to the rotating shaft and is disposed between the inner rings of the two ball bearings to hold the relative positions of the two ball bearings. the regulating portion for regulating the movement to at least one of the bearing holder of ball bearings provided between the two ball bearings,
The axial length of the spacer member is determined by the distance between the first ball bearing of the two ball bearings and the end surface on the second ball bearing side of the two ball bearings in the restricting portion. An electric motor characterized by being set longer .   The electric motor according to claim 1, wherein the restricting portion is a convex portion that is formed to protrude from an inner peripheral surface of the bearing holder. The bearing holder is formed by forming a metal plate into a cylindrical shape,
The electric motor according to claim 1, wherein the restricting portion is a cut-and-raised portion formed by cutting a part of the peripheral wall of the bearing holder inward in the radial direction.   The electric motor according to any one of claims 1 to 3, wherein the restricting portion is formed so as not to contact an inner ring of the two ball bearings.   The electric motor according to any one of claims 1 to 4, wherein the restricting portion is provided on a part of an inner peripheral surface of the bearing holder. Said first ball bearing, while the press-fitted into the bearing holder, an electric motor according to claim 5, characterized in that the second ball bearing, was inserted into the bearing holder. An electric motor;
A fan blade attached to the electric motor and rotating with rotation of the electric motor;
The electric motor is
A stator having coils wound around a plurality of teeth,
A bearing holder fixed at the radial center of the stator and having two ball bearings fitted therein;
A rotating shaft rotatably supported with respect to the stator via the two ball bearings;
A rotor yoke provided on the rotating shaft and formed to cover the stator;
The rotor yoke includes a plurality of magnetic poles arranged to face the stator,
The rotation axis is arranged along the horizontal direction,
The bearing holder is a fan motor formed by forming a metal plate into a cylindrical shape,
The bearing holder is provided with a cylindrical spacer member that is externally fitted to the rotating shaft and is disposed between the inner rings of the two ball bearings to hold the relative positions of the two ball bearings. Forming a drain hole in the part,
The cut and raised portion which is cut and raised radially inward when forming the water drain hole, formed as a restricting portion for restricting movement to at least one of the bearing Holder of the two ball bearings,
The cut and raised portion is provided between the two ball bearings,
The axial length of the spacer member is set between the first ball bearing of the two ball bearings and the end surface on the second ball bearing side of the two ball bearings in the cut and raised portion. A fan motor characterized by being set longer than the distance . The fan motor according to claim 7 , wherein the cut-and-raised portion is formed so as not to contact an inner ring of the two ball bearings. It said first ball bearing, while the press-fitted into the bearing holder, a fan motor according to claim 7 or claim 8, characterized in that the second ball bearing, was inserted into the bearing holder.

Images