MOTOR

Abstract

A yoke includes a first cylindrical unit held by a radially outside surface of a rotor base, a yoke annular unit extending radially outwardly from an axially lower end of the first cylindrical unit, and a second cylindrical unit extending axially downward from a radially outer end of the yoke annular unit, and a magnet fixed to a radially inside surface of the second cylindrical unit.

Description

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of priority to Japanese Patent Application No. 2018-002065 filed on Jan. 10, 2018. The entire contents of this application are hereby incorporated herein by reference.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present disclosure relates to a motor.

2. Description of the Related Art

A disc recording device includes a motor that rotates a recording medium such as an optical disc. For example, a conventional motor includes a spindle motor that rotates a recording disc placed on a disc placing unit. A rotor hub of the spindle motor includes a disc placing unit on which the recording disc is placed and an annular protrusion in which an annular yoke fixing a magnet is press-fitted. The disc placing unit includes a disc receiving surface abutting on the recording disc and a non-contact surface formed on an inner circumferential side of the disc receiving surface. The annular protrusion is provided below the disc placing unit in an axial direction.

When the yoke is press-fitted, sometimes the disc placing unit is deformed to degrade flatness of the disc receiving surface. Although the degradation of the flatness can be corrected by precision cutting of the rotor hub, a contaminant such as dust and fine debris during the machining adheres when the rotor hub is machined while the yoke is provided. In the conventional motor, in order to avoid a problem caused by the contamination, the deformation of the disc placing unit due to the press fitting of the yoke is prevented by setting an outer diameter of the annular protrusion smaller than an outer diameter of the non-contact surface.

However, the conventional motor does not have a way to prevent the deformation caused by the press fitting of the yoke other than the above configuration. Thus, in a motor that does not have the above configuration, it is necessary to suppress or prevent the deformation caused by the press fitting of the yoke by another configuration.

SUMMARY OF THE INVENTION

According to an exemplary embodiment of the present disclosure, a motor includes a rotor that is rotatable about a center axis and a stator that drives the rotor. The rotor includes a magnet radially opposed to the stator, a cylindrical yoke to which the magnet is fixed, and a rotor hub that holds the yoke. The rotor hub includes a cylindrical rotor base and a flange on which an annular plate member is able to be placed on a surface oriented toward one side in an axial direction. The flange is radially outward with respect to the rotor base, extends in a circumferential direction, and is located on one side in the axial direction with respect to the stator. The yoke includes a first cylindrical unit held by a side surface located radially outward in the rotor base, a yoke annular unit extending radially outwardly from an end on the other side in the axial direction of the first cylindrical unit; and a second cylindrical unit extending from an end located radially outward with respect to the yoke annular unit to the other side in the axial direction, the magnet being fixed to a side surface located radially inward in the second cylindrical unit.

The above and other elements, features, steps, characteristics and advantages of the present disclosure will become more apparent from the following detailed description of the preferred embodiments with reference to the attached drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a sectional view illustrating a configuration example of a motor.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Hereinafter, an exemplary embodiment of the present disclosure will be described with reference to the drawing.

In the specification, a direction parallel to a center axis CA is referred to as an “axial direction” in a motor 100. In the axial direction, a direction from a stator 21 of a stationary unit 2 (to be described later) toward a rotor hub 11 of a rotor 1 (to be described later) is referred to as “axially upward” as one side in the axial direction, and a direction from the rotor hub 11 toward the stator 21 is referred to as “axially downward” as the other side in the axial direction. In each component, an axially upward end is referred to as an “axially upper end”, and an axially downward end is referred to as an “axially lower end”. In each component, an axially upward portion is referred to as an “axially upper portion”, and an axially downward portion is referred to as an “axially lower portion”. On a surface of each component, the surface oriented axially upward is referred to as an “axially upper surface” and the surface oriented axially downward is referred to as an “axially lower surface”.

A direction orthogonal to the center axis CA is referred to as a “radial direction”, and a rotation direction of the rotor 1 around the center axis CA is referred to as a “circumferential direction”. In the radial direction, a direction toward the center axis CA is referred to as “radially inward” as one side in the radial direction, and a direction away from the center axis CA is referred to as “radially outward” as the other side in the radial direction. In each component, a radially inward end is referred to as a “radially inner end”, and a radially outward end is referred to as a “radially outer end”. On a side surface of each component, the side surface oriented radially inward is referred to as a “radially inside surface”, and the side surface oriented radially outward is referred to as a “radially outside surface”.

Names of the direction, the end, and the surface do not express a positional relationship and a direction in the case that the motor 100 is incorporated in an actual device.

For example, the motor 100 of the embodiment is mounted on a disc recording device, and drives and rotates an annular plate member 200 for recording. The annular plate member 200 is an optical disc such as a DVD (Digital Versatile Disc) and a BD (Blu-ray Disc; registered trademark). FIG. 1 is a sectional view illustrating a configuration example of the motor 100. FIG. 1 illustrates a sectional structure in the case that the motor 100 is virtually cut on a plane including the center axis CA.

The motor 100 is an outer rotor type. The motor 100 includes the rotor 1 and the stationary unit 2.

The rotor 1 is rotatable around the center axis CA extending in a vertical direction. As illustrated in FIG. 1, the rotor 1 includes a shaft 10, the rotor hub 11, a yoke 12, and a magnet 13. A configuration of the yoke 12 will be described later.

The shaft 10 extends along the center axis CA. The axially lower portion of the shaft 10 is accommodated in a bearing mechanism 23 (to be described later). The axially upper portion of the shaft 10 protrudes axially upward from the axially upper end of the bearing mechanism 23. The rotor hub 11 is fixed to the axially upper portion of the shaft 10. The shaft 10 is a rotation axis of the motor 100. The shaft 10 is rotatable around the center axis CA extending in the vertical direction. The shaft 10 is not limited to this example, but the shaft 10 may be fixed to the stationary unit 2. That is, the shaft 10 may be a fixed shaft. In the case that the shaft 10 is the fixed shaft, a bearing (not illustrated) is provided between the shaft 10 and the rotor hub 11.

The rotor hub 11 is attached to the axially upper end of the shaft 10. The rotor hub 11 holds the yoke 12. The rotor hub 11 includes a rotor base 111 and a flange 112. The rotor base 111 has a cylindrical shape centered on the center axis CA, and is fixed to the shaft 10. The flange 112 is provided at the radially outer end of the rotor base 111, extends in the circumferential direction, and is located axially upward with respect to the stator 21 of the stationary unit 2. The annular plate member 200 can be placed on an axially upper surface 112a of the flange 112.

More specifically, the rotor base 111 includes a tubular unit 1111 and a fitting unit 1112. The tubular unit 1111 has a tubular shape centering on the center axis CA. The shaft 10 is axially inserted in the tubular unit 1111. In particular, the shaft 10 and the bearing mechanism 23 are inserted in the axially lower portion of the tubular unit 1111. The axially upper portion of the tubular unit 1111 is attached to the axially upper portion of the shaft 10. The fitting unit 1112 is provided at the radially outer end in the axially lower portion of the tubular unit 1111, and extends in the circumferential direction. The flange 112 is provided on the radially outside surface of the fitting unit 1112. In other words, the flange 112 protrudes radially outward from the radially outside surface of the fitting unit 1112. Axially downward with respect to the flange 112, at least the yoke 12 is fixed to the radially outside surface of the fitting unit 1112 by press fitting. In addition to the press fitting, the yoke 12 may be fixed by another method. For example, the press-fitted yoke 12 may be further fixed to the radially outside surface of the fitting unit 1112 using a bonding agent.

When the annular plate member 200 is placed on the axially upper surface 112a of the flange 112, the axially upper end of the fitting unit 1112 is fitted in the radially inner end of the annular plate member 200. More specifically, axially upward with respect to the flange 112, the radially inside surface of the annular plate member 200 contacts with the radially outside surface of the fitting unit 1112.

A clamping hole 1112a recessed axially downward is provided on the axially upper surface of the fitting unit 1112. When the annular plate member 200 is placed on the axially upper surface 112a of the flange 112, a clamp member (not shown) holds the annular plate member 200 between the clamp member and the axially upper surface 112a of the flange 112. At this point, a part of the clamp member is fitted in the clamp hole 1112a.

Axially downward with respect to the flange 112, the yoke 12 is attached to the radially outside surface of the fitting unit 1112.

The magnet 13 includes magnetic poles, which are different from each other and are alternately arranged in the circumferential direction, and is disposed radially outward with respect to the stator 21 of the stationary unit 2. The magnet 13 is radially opposed to the stator 21. The magnet 13 is fixed to the yoke 12.

The stationary unit 2 rotatably supports the rotor 1. As illustrated in FIG. 1, the stationary unit 2 includes a stator 21, a bracket 22, and the bearing mechanism 23.

The stator 21 drives and rotates the rotor 1 when the motor 100 is driven. The stator 21 is disposed radially inward with respect to the magnet 13. The stator 21 is fixed to the bracket 22 radially inward, and opposed to the magnet 13 radially outward with a gap in the radial direction.

As illustrated in FIG. 1, the stator 21 includes a stator core 211, an insulator 212, and a coil 213. For example, the stator core 211 is a core member constructed with a laminated steel plate in which a plurality of electromagnetic steel plates are laminated. The stator core 211 may have an annular shape centering on the center axis CA. Alternatively, a plurality of split cores (not illustrated) constituting the stator core 211 may be connected in the circumferential direction with the center axis as the center. The radially inner end of the stator core 211 is fixed to the bracket 22. The radially outer end of the stator core 211 is opposed to the magnet 13 of the rotor 1 with a gap in the radial direction. For example, the insulator 22 is an insulating member made of a resin material, and covers at least a part of the stator core 21. The coil 23 is constructed with a conducting wire wound around the stator core 21 with the insulator 22 interposed therebetween.

As illustrated in FIG. 1, the bracket 22 includes a plate 221, an inner peripheral wall 222, and an outer peripheral wall 223. The plate 221 has a plate shape having an opening in a central portion through which the center axis CA passes, and is located axially downward with respect to the rotor 1, the stator 21, and the bearing mechanism 23. The inner peripheral wall 222 protrudes axially upward from the radially inner end of the plate 221, and extends in the circumferential direction. The shaft 10 and the bearing mechanism 23 are inserted in the inner peripheral wall 222. The stator 21 is fixed to the radially outside surface of the inner peripheral wall 222. In the embodiment, the stator core 211 is fixed to the radially outside surface of the inner peripheral wall 222. The outer peripheral wall 223 protrudes axially upward from the radially outer end of the plate 221, and extends in the circumferential direction. The yoke 12 to which the magnet 13 is fixed and the stator 21 are accommodated in a space surrounded by the plate 221, the inner peripheral wall 222, and the outer peripheral wall 223.

The bearing mechanism 23 rotatably supports the shaft 10 by utilizing a fluid dynamic pressure caused by a working fluid such as lubricating oil. As illustrated in FIG. 1, the bearing mechanism 23 includes a bearing holder 231, a sleeve bearing 232, a thrust plate 233, and a cap 234.

The bearing holder 231 has a tubular shape extending axially with the center axis CA as the center, and is inserted and fixed inside the inner peripheral wall 222 of the bracket 22. The axially lower portion of the shaft 10, the bearing holder 231, the sleeve bearing 232, the thrust plate 233, and the cap 234 are disposed in the bearing holder 231. The axially upper end of the bearing holder 211 is radially opposed to the shaft 10 with the working fluid interposed therebetween. The sleeve bearing 232 has a tubular shape extending axially. The shaft 10 is inserted in the bearing holder 231 and the sleeve bearing 232. The thrust plate 233 has a plate shape extending perpendicularly to the axial direction. The thrust plate 233 is provided axially downward with respect to the shaft 10, and radially opposed to the axially lower end of the shaft 10 with the working fluid interposed therebetween. Consequently, the shaft 10 can be prevented from moving axially downward with respect to the thrust plate 233. The cap 234 is fitted in the axially lower end of the bearing holder 231, and closes and covers the axially lower end.

The inside of the bearing holder 231 is filled with the working fluid such as a lubricating oil. More specifically, gaps of the axially lower end of the shaft 10, the bearing holder 231, the sleeve bearing 232, the thrust plate 233, and the cap 234 are filled with the working fluid. The bearing holder 231 rotatably supports the shaft 10 with the working fluid and the bearing 232 interposed therebetween. Thanks to lubricating action of the working fluid, the shaft 10 can slide smoothly on the axially upper end of the bearing holder 231, the sleeve bearing 232, and the thrust plate 233.

The configuration of the yoke 12 will be described below. The yoke 12 has a cylindrical shape centering on the center axis CA, and is provided on the radially outside surface at the axially lower end of the rotor base 111. In FIG. 1, the yoke 12 is provided on the radially outside surface of the fitting unit 1112 at the axially lower end of the fitting unit 1112.

As illustrated in FIG. 1, the yoke 12 includes a first cylindrical unit 121, a yoke annular unit 122, and a second cylindrical unit 123. The first cylindrical unit 121 has a tubular shape extending axially. The first cylindrical unit 121 is held on the radially outside surface of the rotor base 111. The yoke annular unit 122 has an annular plate shape perpendicular to the axial direction. The yoke annular unit 122 extends radially outward from the axially lower end of the first cylindrical unit 121. The second cylindrical unit 123 has a tubular shape extending axially. The second cylindrical unit 123 extends axially downward from the radially outer end of the yoke annular unit 122. The magnet 13 is fixed to the radially inside surface of the second cylindrical unit 123.

The axially upper end of the yoke 12 is press-fitted in the axially lower end of the rotor hub 11. The radially inside surface in the axially upper end of the yoke 12 is in pressure contact with the radially outside surface in the axially lower end of the rotor hub 11. Consequently, the yoke 12 is held by the rotor hub 11. In other words, the first cylindrical unit 121 is press-fitted in the axially lower end of the rotor base 111. More specifically, the first cylindrical unit 121 is press-fitted in the axially lower end of the fitting unit 1112. The radially inside surface of the first cylindrical unit 121 is in pressure contact with the radially outside surface at the axially lower end of the rotor base 111. More specifically, the radially inside surface of the first cylindrical unit 121 is in pressure contact with the radially outside surface at the axially lower end of the fitting unit 1112.

When the rotor hub 11 is press-fitted in the yoke 12, stress acting on the rotor hub 11 due to the press fitting of the yoke 12 is relaxed by elastic deformation of the yoke 12. More specifically, in the case that the yoke 12 has a cylindrical shape different from the above configuration, sometimes the rotor hub 11 is deformed by the stress to radially incline a direction normal to the axially upper surface 112a of the flange 112 when the rotor base 111 is fitted in the first cylindrical unit 121 of the yoke 12. The deformation of the flange 112 becomes problematic when the annular plate member 200 such as an optical disc is placed on the axially upper surface 112a of the flange 112. On the other hand, according to this configuration, the deformation of the rotor hub 11 can be suppressed when the yoke 12 is held by the rotor hub 11, so that the deformation of the flange 112 due to the press fitting of the yoke 12 as described above and generation of the problem associated with the deformation of the flange 112 can be suppressed or prevented.

In the embodiment, an axial length of the first cylindrical unit 121 is shorter than a radial length of the yoke annular unit 122. For this reason, the yoke annular unit 122, a portion between the yoke annular unit 122 and the first cylindrical unit 121, and a portion between the yoke annular unit 122 and the second cylindrical unit 123 are easily largely deformed. Thus, the stress acting on the rotor hub 11 due to the press fitting of the yoke 12 can easily be relaxed by the deformation of the yoke 12. The present disclosure is not limited to the embodiment, and the axial length of the first cylindrical unit 121 may be equal to the radial length of the yoke annular unit 122. Alternatively, the axial length of the first cylindrical unit 121 may be longer than the radial length of the yoke annular unit 122.

The yoke 12 is located radially outward with respect to the rotor base 111, and located radially inward with respect to the outer peripheral wall 213 of the bracket 22. More specifically, the first cylindrical unit 121, the yoke annular unit 122, and the second cylindrical unit 123 are located radially outward with respect to the fitting unit 1112, and located radially inward with respect to the outer peripheral wall 213 of the bracket 22.

The yoke 12 is located axially downward with respect to the flange 112. More specifically, each of the first cylindrical unit 121, the yoke annular unit 122, and the second cylindrical unit 123 is located axially downward with respect to the flange 112. The first cylindrical unit 121 and the yoke annular unit 122 are located axially upward with respect to the stator 21. An axial position of the second cylindrical unit 123 overlaps an axial position of the stator 21. When being viewed from the radial direction, the second cylindrical unit 123 overlaps the stator 21. That is, the second cylindrical unit 123 is radially opposed to the stator 21 with the magnet 13 interposed therebetween.

When viewed from the circumferential direction, a recess la is provided between the yoke 12 and the flange 112 as illustrated in FIG. 1. The recessed la is recessed radially inward, and extends in the circumferential direction. As illustrated in FIG. 1 when viewed from the circumferential direction, the recess la is constructed with the axially lower surface of the flange 112, the radially outside surface of the first cylindrical unit 121, and the axially upper surface of the yoke annular unit 122. In other words, in the embodiment, the yoke annular unit 122 is axially opposed to the axially lower surface of the flange 112 with a gap. That is, in the axial direction, the gap is provided between the yoke annular unit 122 and the axially lower surface of the flange 112. Thus, a space where the yoke 12 can be deformed can be secured axially downward with respect to the flange 112. Thus, for example, when the yoke 12 is held by the rotor hub 11, the yoke 12 is easily deformed in order to relax the stress acting on the rotor hub 11 due to the press fitting of the yoke 12.

The radially outside surface at the axially lower end of the fitting unit 1112 in which the yoke 12 is held is located radially inward with respect to the radially outside surface at the axially upper end of the fitting unit 1112. In other words, the radial position at the radially outer end of the fitting unit 1112 axially downward with respect to the flange 112 is located radially inward of the radial position at the radially outer end of the fitting unit 1112 axially upward with respect to the flange 112. For this reason, in the present embodiment, when the annular plate member 200 is placed on the axially upper surface 112a of the flange 112, the radial position at the radially outer end of the rotor base 111 in which the first cylindrical unit 121 of the yoke 12 is disposed is located radially inward with respect to the radially inner end of the annular plate member 200. According to this configuration, the radial inner end of the yoke annular unit 122 is disposed further radially inward, so that the radial length of the yoke annular unit 122 can be set longer. Thus, the yoke 12 is more easily deformed, so that the stress acting on the rotor hub 11 due to the press fitting of the yoke 12 is easily relaxed by the deformation of the yoke 12. The present disclosure is not limited to the embodiment, but the radial position at the radially outer end of the rotor base 111 may be located at the same position as the radial position at the radially inner end of the annular plate member 200. Alternatively, the radial position at the radially outer end of the rotor base 111 may be located radially outward with respect to the radially inner end of the annular plate member 200.

In the embodiment, the radial position at the radially outer end of the rotor base 111 in which the first cylindrical unit 121 of the yoke 12 is disposed is located radially inward with respect to the radially outer end of the stator 21. According to this configuration, the radial position at the radially outer end of the rotor base 111 in which the first cylindrical unit 121 of the yoke 12 is disposed is radially inward with respect to the radially outer end of the stator 21. For this reason, the radial length between the radially outer end of the stator 21 and the radially inner end of the yoke annular unit 122 becomes longer, so that the radial length of the yoke annular unit 122 can be set longer. Thus, the yoke 12 is more easily deformed, so that the stress acting on the rotor hub 11 due to the press fitting of the yoke 12 can be more easily relaxed by the deformation of the yoke 12. The present disclosure is not limited to the embodiment, but the radial position at the radially outer end of the rotor base 111 may be located at the same position as the radial position at the radially outer end of the stator 21. Alternatively, the radial position at the radially outer end of the rotor base 111 may be radially outward with respect to the radially outer end of the stator 21.

The axially upper end of the yoke 12 is axially separated from the flange 112. More specifically, in the present embodiment, the axially upper end of the first cylindrical unit 121 is axially opposed to the axially lower surface of the flange 112 with a gap. That is, the axially upper end of the first cylindrical unit 121 is separated axially downward from the axially lower surface of the flange 112. For this reason, the yoke 12 can be prevented from directly applying the stress to the flange 112 when the yoke 12 is held by the rotor hub 11. Thus, the deformation of the flange 112 at this time can effectively be prevented. The present disclosure is not limited to the embodiment, but the axially upper end of the first cylindrical unit 121 may axially contact with the axially lower surface of the flange 112.

For example, the present disclosure is useful for the motor having the yoke that fixes the magnet.

Features of the above-described preferred embodiments and the modifications thereof may be combined appropriately as long as no conflict arises.

While preferred embodiments of the present disclosure have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing from the scope and spirit of the present disclosure. The scope of the present disclosure, therefore, is to be determined solely by the following claims.

Claims

1. A motor comprising: a rotor rotatable about a center axis; anda stator that drives the rotor; wherein the rotor includes: a magnet radially opposed to the stator;a cylindrical yoke to which the magnet is fixed; anda rotor hub that holds the yoke;the rotor hub includes: a cylindrical rotor base; anda flange on which an annular plate is able to be placed on a surface oriented toward one side in an axial direction;the flange is radially outward with respect to the rotor base, extends in a circumferential direction, and is located on one side in the axial direction with respect to the stator; andthe yoke includes: a first cylindrical unit held by a side surface located radially outward in the rotor base;a yoke annular unit extending radially outward from an end on the other side in the axial direction of the first cylindrical unit; anda second cylindrical unit extending from an end located radially outward with respect to the yoke annular unit to the other side in the axial direction; whereinthe magnet is fixed to a side surface located radially inward in the second cylindrical unit.

2. The motor according to claim 1, wherein the first cylindrical unit is located on the other side in the axial direction with respect to the flange; andthe yoke annular unit is axially opposed to a surface oriented toward the other side in the axial direction of the flange with a gap.

3. The motor according to claim 1, wherein when the annular plate member is placed on the surface oriented toward one side in the axial direction of the flange, a radial position at a radially outer end of the rotor base in which the first cylindrical unit of the yoke is disposed is located radially inward with respect to a radially inner end of the annular plate member.

4. The motor according to claim 1, wherein a radial position at a radially outer end of the rotor base in which the first cylindrical unit of the yoke is disposed is located radially inward with respect to a radially outer end of the stator.

5. The motor according to claim 1, wherein an end on one side in the axial direction of the first cylindrical unit is axially opposed to a surface oriented toward the other side in the axial direction of the flange with a gap.

6. The motor according to claim 1, wherein an axial length of the first cylindrical unit is shorter than a radial length of the yoke annular unit.