JP2002218702A - Fan motor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a low-cost fan motor enables lowering the friction of a bearing device. SOLUTION: In the fan motor 30 provided with a rotary part 33 that has a rotor 32 with a fan, a stator 37 arranged to face the magnet part 36 of the rotor 32, and a bearing device 38 that rotatably supports the rotary part 33, the bearing device 38 is provided with an outer ring 40, balls 42 that rolls on rolling grooves formed on the surface of the inner circumference of the outer ring 50, and a shaft member that has a cylindrical surface 31a, that supports the side of the balls 42 separated away from the rolling grooves 41 on the outer ring 40. The shaft member is constituted of a rotary shaft 31 of the rotary part 33, and the end part of the rotary shaft 31 is contacted on a point with a housing 34 via a spherical body 44.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fan motor for cooling or the like which supports a rotating part by a rolling bearing device.

[0002]

2. Description of the Related Art Conventional fan motors of this type include:
For example, those shown in FIGS. 6 and 7 are known. The inner rotor type fan motor shown in FIG. 6 is externally fitted and fixed to a rotating portion 3 composed of a rotating shaft 1 and a rotor 2 with a fan fixed to one end of the rotating shaft 1 and a cylindrical portion 5 of a housing 4. And a ball bearing arranged in the cylindrical portion 5 and rotatably supporting the rotary shaft 1 inserted in the cylindrical portion 5. 8 is provided. The ball bearings 8 are arranged at two places apart in the axial direction, and the upper one of the two ball bearings 8
Is pressed downward by a spring 9 to apply an appropriate axial load between the bearings 8 to ensure smooth rotation.

On the other hand, a flat rotor type fan motor shown in FIG. 7 has a rotating unit 13 comprising a rotating shaft 11 and a rotor 12 with a fan fixed to one end of the rotating shaft 11.
And the rotor 1 with fan attached to the housing 14
And a bearing device 18 disposed in the cylindrical portion 15 of the housing 14 and rotatably supporting the rotating shaft 11 inserted in the cylindrical portion 15.
The bearing device 18 includes two outer races 18a fitted into the cylindrical portion 15 at a distance in the axial direction and a rolling groove 18b formed on an inner diameter surface of the outer race 18a. And the rolling element 18c. The rolling element 1 is mounted on the rotating shaft 11.
8c is formed with a peripheral groove 11a as an inner ring side rolling groove that supports the side separated from the rolling groove 18b.
An appropriate axial load is applied between the bearing devices 18 via a spring 19 interposed between the bearing devices 18a.

[0004]

In the fan motor shown in FIGS. 6 and 7, a rolling element, that is, a steel ball is in contact with an outer ring and an inner ring through a rolling groove having a curvature. Since the contact surface between the moving groove and the steel ball receives a load (preload) in the axial direction by a spring, a frictional force accompanied by spin sliding occurs between the rolling groove and the steel ball. The oil film formed at the contact portion between the oil film and the steel ball fluctuates due to the change in the lubrication state due to the change in temperature and speed, and the fluctuation of the oil film causes a problem that the frictional force fluctuates.

Furthermore, not only is it necessary to machine the inner ring of the bearing or the circumferential groove of the rotary shaft, but also a preload applying mechanism such as a spring is required, which hinders the cost reduction of the fan motor. The present invention has been made to solve such inconveniences, and has as its object to provide a low-cost fan motor that can reduce the friction of a bearing device.

[0006]

In order to achieve the above object, a fan motor according to the present invention comprises: a rotating section having a rotor with a fan; a stator arranged to face a magnet section of the rotor with a fan; A bearing device that rotatably supports a rotating portion, wherein the bearing device includes an outer ring, a rolling element that rolls a rolling groove formed in an inner diameter surface of the outer ring, A shaft member having a cylindrical surface that supports a side of the outer ring that is separated from the rolling groove.

[0007] When the shaft member is the rotating shaft of the rotating portion, it is preferable that the ends of the rotating shaft are brought into point contact.

[0008]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an explanatory sectional view for explaining a fan motor which is an example of an embodiment of the present invention.
FIG. 5 to FIG. 5 are explanatory sectional views for describing a fan motor according to another embodiment of the present invention.

Referring to FIG. 1, this fan motor 30 is of an inner rotor type, and has a rotating shaft (shaft member) 31.
And a rotor 3 with a fan fixed to one end of the rotating shaft 31
2 and a magnet part 3 of a rotor 32 with a fan which is externally fitted and fixed to a cylindrical part 35 of a housing 34.
6, a stator 37 disposed in the circumferential direction and a cylindrical portion 3.
Rotating shaft 3 disposed in the cylindrical portion 35 and inserted into the cylindrical portion 35
1 for rotatably supporting the bearing 1.

The bearing device 38 includes a plurality of (two in the figure) outer rings 40 which are arranged in the axial direction and fitted and fixed in the cylindrical portion 35, and a rolling formed on the inner surface of the outer ring 40. A ball 42 as a rolling element that rolls in the groove 41, a retainer 43 that rotatably holds the ball 42, and an outer ring 4 of the ball 42
Cylindrical surface 31a supporting the side separated from the 0 rolling groove 41
And a shaft member having
The shaft member is constituted by the rotating shaft 31 of the rotating unit 33. A substantially central portion of the lower end surface of the rotating shaft 31 is in point contact with the spherical body 44 fixed to the bottom surface of the housing 34 via a lubricant such as grease, and therefore, between the rotor magnet portion 36 and the stator 37. The axial load due to the acting magnetic force or the wind pressure of the fan is supported by the spherical body 44. The axial load is
It is smaller than the axial load applied to the two bearings by the conventional spring.

The outer ring 40, the ball 42, and the retainer 43 are integrally formed to form an outer ring assembly. The outer ring assembly is managed cleanly and is filled with a predetermined lubricant such as grease. Rubber seals 45 are attached to both sides or one side of the outer ring assembly to hold the grease. Note that a metal shield plate may be attached instead of the rubber seal 45, or a spacer may be provided between the outer ring assemblies to be spaced apart from each other in the axial direction.
The retainer 43 is preferably made of plastic capable of retaining grease.
The diameter of the pocket for supporting the ball 42 on the inner diameter side of the retainer 43 is smaller than the diameter of the ball 42 so that the ball 42 does not drop to the inner diameter side before being inserted into the holder 1.

When the rotating shaft 31 is made of a steel material, it is preferable that the surface of the rotating shaft 31 be subjected to a hardening treatment so as to impart abrasion resistance to the same hardness as that of the outer ring 40. When a ceramic material is used for the ball 42, the rotating shaft 31 may be made of a ceramic material (silicon nitride, silicon carbide, zirconia, alumina, etc.). In the case of a resin ball 42, the surface of the rotating shaft 31 is particularly hardened. It does not have to be applied. Further, the radius of curvature of the rolling groove 41 of the outer ring 40 in the outer ring assembly is set to 51 to 65% with respect to the diameter of the ball 42,
Even if the ball 42 and the retainer 43 move in the axial direction, they do not come off the outer ring assembly.

The radial run-out defined by the rotating shaft 31 and the ball 42 of the outer ring assembly is determined up to the radial clearance.
2 is maintained slightly smaller than the inscribed circle diameter. The specific effective clearance dimension is set to about 1 to 10 μm in consideration of the clearance required for assembly and thermal expansion due to heat generated during rotation. This range is preferable because the radial runout is small and the incorporation is good.

As described above, in this embodiment, the outer race 40
A ball 42 is interposed between the rolling groove 41 of the rotary shaft 31 and the cylindrical surface 31 a of the rotary shaft 31, and the substantially central portion of the lower end surface of the rotary shaft 31 is greased to a spherical body 44 fixed to the bottom surface of the housing 34. The axial load is supported by point contact via a lubricant such as
0 does not act on the rolling groove 41 and the cylindrical surface 31a of the rotating shaft 31. Therefore, only the radial load is supported. As a result, the ball contact between the rolling groove 41 of the outer ring 40 and the cylindrical surface 31a of the rotating shaft 31 is achieved. This prevents the occurrence of spin slippage as in the past and reduces friction of the bearing device, and the radial load is as small as the unbalanced load of the fan, thus reducing the rolling friction due to the radial load. can do.

Further, since the substantially central portion of the lower end surface of the rotating shaft 31 is point-contacted with a spherical body 44 fixed to the bottom surface of the housing 34 via a lubricant such as grease to support an axial load. In addition, it is possible to reduce the sliding friction, and at the boundary lubrication state where the rotational speed is substantially zero, the contact occurs at an insufficient oil film forming portion, so that the oil film is less susceptible to the oil film viscosity change. Variations in friction can be reduced.

Furthermore, since the conventional groove machining of the inner ring or shaft of the bearing is not required, and a preload applying mechanism such as a spring is not required, the cost of the bearing device and the fan motor can be reduced. In the above embodiment, the axial load is supported by bringing the end surface of the rotating shaft 31 into point contact with the spherical body 44 fixed to the bottom surface of the housing 34 via a lubricant such as grease. Instead, as shown in FIG. 2, the end of the rotating shaft 31 is processed into a convex spherical shape, and the convex spherical surface is brought into point contact with the bottom surface of the housing 34 via a lubricant such as grease to reduce the axial load. It may be supported. In this case, the bottom surface of the housing is processed as a contact portion.

Further, in the above-described embodiment, the case where the end face of the rotating shaft 31 is point-contacted is taken as an example. Alternatively, as shown in FIG. Axial load may be supported by surface contact with a lubricant such as grease. In this case, although it is not a point contact, the sliding load can be reduced because the axial load is small.

Further, in the above embodiment, the case where the present invention is applied to an inner rotor type fan motor is taken as an example. However, the present invention is not limited to this. For example, as shown in FIG. Even when the present invention is applied to a simple outer rotor type fan motor, the same operation and effect can be obtained. In any case, the axial load is supported not by the rolling grooves of the bearing but by the housing, as in the above embodiment.

The fan motor 50 shown in FIG.
1. A rotating part 53 composed of a fan 52 a fixed to one end of the rotating cylinder 51 and a rotor magnet part 56 externally fitted to the rotating cylinder 51, and attached to an inner peripheral surface of a cylindrical part 55 of a housing 54. A stator 57 is provided in the rotor magnet portion 56 so as to face the circumferential direction, and a bearing device 58 is provided in the rotating cylinder 51 and rotatably supports the rotating portion 53.

The bearing device 58 includes a plurality of (two in the figure) outer rings 60 which are arranged in the axial direction and fitted and fixed in the rotary cylinder 51, and a rolling formed on the inner surface of the outer ring 60. A ball 62 as a rolling element that rolls in the groove 61, a retainer 63 that rotatably holds the ball 62, and an outer ring 6 of the ball 62
Cylindrical surface 64a supporting the side separated from the zero rolling groove 61
And a shaft member having
The shaft member is constituted by a fixed shaft 64 projecting from the upper surface 54 a of the convex portion at the bottom of the housing 54. The lower end surface of the lower outer ring 60 is in contact with the convex upper surface 54a of the housing 54 via a lubricant such as grease to form a sliding bearing. Therefore, the rotor magnet portion 56 and the stator 57
An axial load due to a magnetic force acting between them or a wind pressure of a fan or the like is supported by the sliding bearing.

The fan motor 70 shown in FIG.
1. A rotating part 73 composed of a fan 72a fixed to one end of the rotating cylinder 71 and a rotor magnet part 76 fitted on the rotating cylinder 71, and attached to the inner peripheral surface of a cylindrical part 75 of a housing 74. The rotor includes a stator 77 circumferentially opposed to the rotor magnet section 76, and a bearing device 78 disposed in the rotating cylinder 71 and rotatably supporting the rotating section 73.

The bearing device 78 includes a plurality of (two in the figure) outer rings 80 which are arranged in the axial direction and fitted and fixed in the rotary cylinder 71, and a rolling formed on the inner surface of the outer ring 80. A ball 82 as a rolling element that rolls in the groove 81, a retainer 83 that rotatably holds the ball 82, and an outer ring 8 of the ball 82
Cylindrical surface 84a supporting the side apart from the 0 rolling groove 81
And a shaft member having
The shaft member is constituted by a fixed shaft 84 projecting from the upper surface 74a of the convex portion at the bottom of the housing 74. The lower retainer 83 is protruded downward in the axial direction, and the protruding end contacts the upper surface 74a of the convex portion of the housing 74 via a lubricant such as grease to form a sliding bearing. An axial load due to a magnetic force acting between the magnet portion 76 and the stator 77 or a wind pressure of a fan is supported by the sliding bearing.

[0023]

As is apparent from the above description, according to the present invention, it is possible to provide a fan motor capable of reducing the friction of the bearing device at low cost.

[Brief description of the drawings]

FIG. 1 is an explanatory sectional view for explaining a fan motor which is an example of an embodiment of the present invention.

FIG. 2 is an explanatory cross-sectional view illustrating a fan motor according to another embodiment of the present invention.

FIG. 3 is an explanatory cross-sectional view illustrating a fan motor according to another embodiment of the present invention.

FIG. 4 is an explanatory cross-sectional view for explaining a fan motor according to another embodiment of the present invention.

FIG. 5 is an explanatory cross-sectional view for explaining a fan motor according to another embodiment of the present invention.

FIG. 6 is an explanatory sectional view for explaining a conventional fan motor.

FIG. 7 is an explanatory sectional view for explaining a conventional fan motor.

[Explanation of symbols]

 Reference Signs List 30 fan motor 31 rotating shaft (shaft member) 31a cylindrical surface 32 rotor with fan 33 rotating part 36 rotor magnet part 37 stator 38 bearing device 40 outer ring 41 rolling groove 42 ball (rolling) Moving body)

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI theme coat ゛ (Reference) F04D 29/34 F04D 29/34 J 5H607 F16C 33/38 F16C 33/38 33/58 33/58 // F16C 17/08 17/08 21/00 21/00 H02K 7/14 H02K 7/14 A (72) Inventor Chiaki Oyama 1-5-50 Kugenuma Shinmei 1-chome, Fujisawa-shi, Kanagawa F-term (in reference) 3H022 AA03 BA04 BA06 CA12 CA15 CA45 DA13 3H033 AA02 BB02 BB08 CC06 DD01 EE11 3J011 AA20 BA08 JA02 KA03 MA12 3J101 AA03 AA32. AA12 BB01 BB07 BB09 BB14 BB17 BB25 CC01 CC05 FF04 GG01 GG02 GG04 GG08 GG09

Claims (1)

[Claims] A rotating unit having a rotor with a fan, a stator arranged to face a magnet unit of the rotor with a fan,
A fan motor comprising: a bearing device rotatably supporting the rotating portion; wherein the bearing device includes an outer ring, a rolling element that rolls a rolling groove formed in an inner diameter surface of the outer ring, and the rolling element. A shaft member having a cylindrical surface that supports a side of the outer ring that is separated from the rolling groove of the outer ring.