JP2004324681A - Bearing mechanism, motor, and disc drive unit - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent deterioration of bearing performance due to discharge of foreign matter in a communication hole left when the communication hole is formed from the communication hole in a bearing mechanism using fluid dynamic pressure. <P>SOLUTION: This bearing mechanism 4 is provided with a rotor hub 31 having a shaft 30, and a sleeve 22 to which the shaft 30 is inserted. Between the shaft 30 and the sleeve 22, lubricating oil 50 is provided. Between a bearing surface 41b as an outer circumferential surface of the shaft 30 and a bearing surface 41a as an inner circumferential surface of the sleeve 22, a micro-gap 51 for generating fluid dynamic pressure by the lubricating fluid 50 is provided. The communication hole 60 is provided in the sleeve 22 for communication between the fixed end side of the shaft 30 and the free end side of the lubricating oil 50 with each other. Pressure balance is thus maintained between the upper side and the lower side of the gap 51. On an inside surface of the communication hole 60, a coating film 61 of material having such characteristics as to hold foreign matter is formed. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a bearing mechanism using a fluid dynamic pressure, a motor including the bearing mechanism, and a disk drive using the motor.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, a disk drive device such as a hard disk device or a removable disk device includes a spindle motor (hereinafter, referred to as a “motor”) that rotationally drives a recording disk. In recent disk drive motors, a bearing mechanism in which a shaft is inserted into a sleeve is provided, and the bearing mechanism utilizes fluid dynamic pressure of lubricating oil filled in a gap between the sleeve and the shaft. In such a bearing mechanism, in order to prevent the lubricating oil from leaking from a gap between the shaft and the sleeve, which is a dynamic pressure part in the bearing mechanism, or to circulate the lubricating oil between a plurality of dynamic pressure parts. In order to balance pressures, there is known an apparatus provided with a communication hole for communicating lubricant oil at a plurality of locations.
[0003]
The communication holes are generally formed by electric discharge machining or drilling, but due to their small diameter, they are difficult to clean, and foreign matter (such as cutting powder) during the formation of the communication holes remains in the communication holes. There is a possibility that. The foreign matter remaining in the communication hole flows out of the communication hole due to the flow of the lubricating oil and enters the gap between the shaft and the sleeve, which is a dynamic pressure part, and contacts the shaft and the sleeve to adversely affect bearing performance. May give.
[0004]
For this reason, there is known a bearing mechanism in which a filter for filtering lubricating oil is provided in a communication hole to remove foreign substances contained in lubricating oil (for example, see Patent Documents 1 to 4).
[0005]
[Patent Document 1]
JP-A-48-29938
[Patent Document 2]
JP-A-8-163818 (paragraph 0038, FIG. 6)
[Patent Document 3]
JP-A-8-163821 (paragraph 0035, FIG. 7)
[Patent Document 4]
JP-A-10-80091 (paragraph 0024, FIG. 1)
[0006]
[Problems to be solved by the invention]
By the way, a thinner disk drive is desired. In recent years, for the purpose of further miniaturization, for example, a fluid dynamic pressure by lubricating oil is used between an outer peripheral surface of a shaft and an inner peripheral surface of a sleeve. To provide support in the radial direction perpendicular to the rotation axis, and to utilize the fluid dynamic pressure of the lubricating oil between the lower surface (the surface on the shaft side) of the rotating body fixed to the shaft and the upper end surface of the sleeve. Attention has been paid to a bearing mechanism (hereinafter, referred to as an “ST (single thrust) type”) that supports in a thrust direction parallel to a rotation shaft.
[0007]
As another example of a preferable bearing mechanism that can be downsized, a conical inclined surface provided on an outer peripheral surface of a shaft and an inclined surface provided on an inner peripheral surface of a sleeve opposed to the inclined surface are provided. Among them, there is a bearing mechanism (hereinafter, referred to as “cone type”) that supports in the radial direction and the thrust direction using fluid dynamic pressure. In the cone type bearing mechanism, since the support in both the radial direction and the thrust direction is performed by the inclined bearing surface, miniaturization is realized.
[0008]
In the ST type or cone type bearing mechanism, the diameter of the communication hole (for example, 1 mm or less) is reduced along with the miniaturization. Therefore, foreign matter that cannot be removed by washing during motor manufacturing and remains in the communication hole is usually reduced. It has been considered that it adheres strongly in the communication hole and does not flow out much when the motor is driven. For this reason, conventionally, in the ST type or cone type bearing mechanism, no filter was provided in the communication hole. However, it has been found that even in the ST type or cone type bearing mechanism, foreign matter flows out of the communication hole depending on the temperature change of the lubricating oil, the flow state of the lubricating oil, and the like.
[0009]
On the other hand, the filter must not obstruct the flow of the lubricating oil in the communication hole, and the density of the filter cannot be extremely increased. Can not. Therefore, a method of removing foreign matter more efficiently than a filter is also desired.
[0010]
The present invention has been made in view of the above problems, and has as its object to provide a bearing mechanism (particularly, a small bearing mechanism) that utilizes fluid dynamic pressure to more reliably prevent foreign substances from flowing out of a communication hole. I do. It is another object of the present invention to improve reliability of a motor and a disk device having a bearing mechanism using a fluid dynamic pressure by preventing outflow of foreign matter.
[0011]
[Means for Solving the Problems]
The invention according to claim 1 is an electric motor, comprising: a first assembly having a shaft; and a second assembly having a bottomed sleeve into which the shaft is inserted. One of the first assembly and the second assembly has a field magnet arranged around the shaft, and the other assembly faces the field magnet, and An armature that generates a rotational force between the field magnet and the center axis of the shaft, wherein the first assembly extends outward from the fixed end of the shaft with respect to the center axis; A disk portion extending from the disk portion, and a cylindrical portion protruding from the disk portion along the outer periphery of the sleeve around the center axis toward a free end side of the shaft, and the shaft of the disk portion Side face and the end face of the sleeve facing the disc portion And at least one of the inner peripheral surface of the sleeve and the outer peripheral surface of the shaft, a groove for generating fluid dynamic pressure is formed, and a groove is formed between the disk portion and the sleeve. The gap, the gap between the sleeve and the shaft, and the gap between the free end side surface of the shaft and the bottom surface of the sleeve, lubricating oil is continuously present, and the sleeve or the shaft is It has a communication hole for communicating the lubricating oil on the fixed end side and the lubricating oil on the free end side of the shaft, and a filter arranged in the communication hole.
[0012]
The invention according to claim 2 is an electric motor, comprising: a first assembly having a shaft; and a second assembly having a sleeve into which the shaft is inserted. One of the three-dimensional body and the second assembly has a field magnet arranged around the shaft, and the other assembly faces the field magnet and An armature that generates a rotational force about a central axis of the shaft between the magnet and the shaft, the shaft has a substantially conical conical portion whose diameter gradually increases along the central axis; A sleeve having an inclined surface facing a side surface of the conical portion, wherein a groove for generating a fluid dynamic pressure is formed on at least one of the side surface and the inclined surface of the conical portion; Lubricating oil continues in the gap between the side surface and the inclined surface There Te, the sleeve or the shaft has a communication hole that communicates the lubricating oil present at both ends of the shaft than the side surface of the conical portion, and a filter disposed in the communicating hole.
[0013]
The invention according to claim 3 is the motor according to claim 1 or 2, wherein at least a part of the communication hole has a diameter of a cross section perpendicular to a direction in which the communication hole extends is 1.0 mm or less. .
[0014]
The invention according to claim 4 is a bearing mechanism, comprising: a first member; and a second member rotatably supporting the first member about a predetermined central axis. A groove for generating fluid dynamic pressure is formed in at least one of a first bearing surface of the member and a second bearing surface of the second member opposed to the first bearing surface; Lubricating oil is continuously present in a gap between the bearing surface and the second bearing surface, and the first member or the second member lubricates two portions in the gap or communicating with the gap. A communication hole for communicating oil is provided, and at least a part of the inner surface of the communication hole is coated with a material having a property of retaining foreign matter remaining in the communication hole.
[0015]
The invention according to claim 5 is the bearing mechanism according to claim 4, wherein the openings at both ends of the communication hole are located on both sides of the gap with respect to the direction in which the central axis faces, or one of the openings. Are located in the gap and the other opening is located outside the gap.
[0016]
The invention according to claim 6 is the bearing mechanism according to claim 4 or 5, wherein the first bearing surface is an outer peripheral surface of a shaft around the center axis, and the second bearing surface is , The inner peripheral surface of the bottomed sleeve into which the shaft is inserted.
[0017]
The invention according to claim 7 is the bearing mechanism according to claim 6, wherein the first member further includes a disk portion extending outward from the fixed end of the shaft with respect to the central axis. A groove for generating fluid dynamic pressure is formed on at least one of the shaft-side surface of the disk portion and an end surface of the sleeve facing the disk portion, and a first bearing surface and From a first gap between the second bearing surface to a second gap between the disc portion and the sleeve, and further to a third gap between a free end surface of the shaft and a bottom surface of the sleeve. And the lubricating oil are continuously present, and the communication hole is connected to the space between the first gap and the second gap. Communicate with oil.
[0018]
The invention according to claim 8 is the bearing mechanism according to claim 6, wherein the shaft has a substantially conical shape in which a diameter gradually increases along the central axis, and the first bearing surface is a side surface. The sleeve has a conical portion, the sleeve has an inclined surface that is the second bearing surface facing the side surface of the conical portion, and openings in both ends of the communication hole are formed in the gap with respect to the direction in which the central axis faces. Located on both sides.
[0019]
A ninth aspect of the present invention is the bearing mechanism according to any one of the fourth to eighth aspects, wherein the material is a mixture containing molybdenum disulfide or carbon.
[0020]
The invention according to claim 10 is the bearing mechanism according to any one of claims 4 to 9, wherein at least a part of the communication hole has a diameter of a cross section perpendicular to a direction in which the communication hole extends. 0 mm or less.
[0021]
According to an eleventh aspect of the present invention, there is provided an electric motor, in which the bearing mechanism according to any one of the fourth to tenth aspects, wherein the first member is arranged such that the center shaft is positioned with respect to the second member. A field magnet and an armature that rotate relatively to the center are provided.
[0022]
According to a twelfth aspect of the present invention, there is provided a disk drive device, wherein a housing for accommodating a disk-shaped recording medium for recording information, and wherein the storage medium is fixed inside the housing and rotates the recording medium. 12. A motor according to claim 11, further comprising: an access unit that writes or reads information to or from the recording medium.
[0023]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 is a diagram showing the internal configuration of a disk drive device (hard disk device in this example) 70 according to the first embodiment of the present invention. The disk drive 70 has a clean space in which the inside of a housing 71 is extremely free of dust and dirt, and a disk drive medium in which a disk-shaped recording medium 72 for storing information is mounted inside the housing 71. And an access unit 73 for writing and / or reading information to and from the recording medium 72 are accommodated.
[0024]
The access unit 73 includes a head 731 that magnetically writes and reads information in proximity to the disk-shaped recording medium 72, an arm 732 that supports the head 731, and the head 731 by moving the arm 732. A head moving mechanism 733 for changing the position relative to the head 72 is provided. With such a configuration, the head 731 accesses a required position of the recording medium 72 in a state of being close to the rotating recording medium 72, and performs writing and reading of information.
[0025]
FIG. 2 is a longitudinal sectional view showing the configuration of the motor 1. The motor 1 includes a fixed assembly 2 and a rotating assembly 3. The bearing assembly 4 using a fluid dynamic pressure of lubricating oil causes the rotating assembly 3 to rotate the rotating shaft 10 with respect to the fixed assembly 2. It is rotatably supported as a center.
[0026]
The fixed assembly 2 includes a base plate 21, a sleeve 22, a seal cap 23, an armature 24, a magnetic shield plate 25, and a thrust yoke 26.
[0027]
The base plate 21 holds each part of the fixed assembly 2, and has a substantially bowl shape having a bottom plate 211, a sleeve holding part 212, and an outer wall part 213. The base plate 21 is formed of a non-magnetic material (for example, an aluminum alloy). The bottom plate portion 211 has a substantially disk shape, and the sleeve holding portion 212 projects substantially cylindrically from the center of the bottom plate portion 211, and the sleeve 22 is held by the sleeve holding portion 212. The outer wall portion 213 has a wall shape rising from the bottom plate portion 211 at the outer edge of the bottom plate portion 211. The base plate 21 is fixed to the housing 71 of the disk drive 70 described above.
[0028]
The sleeve 22 rotatably supports the rotating assembly 3 and is formed of metal into a substantially cylindrical shape. The lower end of the sleeve 22 is press-fitted into the sleeve holding portion 212, and the central axis of the sleeve 22 is the rotating shaft 10 of the motor 1. The seal cap 23 has a substantially disk shape and closes an opening on the lower end side of the sleeve 22, whereby the sleeve 22 has a bottomed shape with one end closed. At this time, the seal cap 23 forms a predetermined gap with respect to the end face of the sleeve 22 so as not to close a communication hole 60 described later.
[0029]
The armature 24 has a core formed by stacking silicon steel plates, and a coil wound around the magnetic pole of the core. The armature 24 has a base plate 21 that is disposed around the sleeve 22 (that is, around a shaft 30 described later). It is fixed to the outer wall portion 213. The coil of the armature 24 is connected to a current supply circuit (not shown), and the supplied current is controlled. The magnetic shield plate 25 shields the magnetism from the armature 24, has a substantially annular shape around the rotating shaft 10, and is fixed to the outer wall 213 of the base plate 21 above the armature 24. The magnetic shield plate 25 is formed of a ferromagnetic material.
[0030]
The thrust yoke 26 is for attracting the rotating assembly 3 to the base plate 21 side by magnetic attraction between the field magnet 33 to be described later, and is an annular ferromagnetic material centered on the rotating shaft 10. And is fixed to the bottom plate 211 of the base plate 21.
[0031]
On the other hand, the rotating assembly 3 includes a rotor hub 31, a retaining member 32, a field magnet 33, and a magnetic shield plate.
[0032]
The rotor hub 31 holds each part of the rotary assembly 3, and has a shaft 30, a disk part 312, a cylindrical part 313, and a disk mounting part 314, and a part other than the shaft 30 is substantially a bowl. It has a shape. The rotor hub 31 is formed of a magnetic material such as iron.
[0033]
One end of the shaft 30 is a fixed end fixed to the center of the disk portion 312, and the other end is a free end. The disk portion 312 has a disk shape extending outward from the fixed end of the shaft 30 with respect to the rotation shaft 10. The cylindrical portion 313 has a cylindrical shape protruding from the disk portion 312 to the free end side of the shaft 30 along the outer periphery of the sleeve 22 around the rotation shaft 10 at the outer edge of the disk portion 312. The disk mounting portion 314 is a portion on which the above-described disk-shaped recording medium 72 (see FIG. 1) is mounted, and projects annularly from the outer peripheral surface of the cylindrical portion 313. Note that the recording medium 72 is fixed to the disk mounting portion 314 by a clamper (not shown).
[0034]
The rotor hub 31 is in a state where the shaft 30 is inserted into the sleeve 22 of the fixed assembly 2, the lower surface of the disk portion 312 faces the upper end surface of the sleeve 22, and the cylindrical portion 313 is located along the outer periphery of the sleeve 22. The sleeve 22 is supported rotatably about the rotation shaft 10. The distal end side (free end side) of the shaft 30 is located at the lower end side of the sleeve 22, the fixed end side of the shaft 30 is located at the upper end side of the sleeve 22, and the central axis of the shaft 30 coincides with the central axis of the sleeve 22. , The rotating shaft 10 of the motor 1.
[0035]
The retaining member 32 prevents the shaft 30 from coming off the sleeve 22 (that is, the rotation assembly 3 being separated from the fixed assembly 2), and is formed in an annular shape around the rotation shaft 10. It is fixed to the inner peripheral surface of the cylindrical portion 313. The retaining member 32 is formed of a metal such as iron, and when the rotating assembly 3 moves in a direction away from the fixed assembly 2, the retaining member 32 comes into contact with a flange portion 221 protruding from the upper portion of the sleeve 22 in the outer peripheral direction. The shaft 30 is prevented from coming off the sleeve 22.
[0036]
The field magnet 33 is disposed around the shaft 30 around the rotation shaft 10, and the armature 24 to which a predetermined current is applied is rotated about the rotation shaft 10 between the armature 24 and the field magnet 33. 3 to generate a rotating force (torque). Further, the field magnet 33 also plays a role of generating a force for attracting the rotating assembly 3 to the base plate 21 side of the fixed assembly 2 by a magnetic attraction force between the field magnet 33 and the lower thrust yoke 26 as described above. . The field magnet 33 is annular and multipolar magnetized around the rotation shaft 10, and is fixed to the outer peripheral surface of the cylindrical portion 313 of the rotor hub 31. The field magnet 33 is arranged such that the magnetic center of the field magnet 33 (the magnetic center with respect to the direction in which the rotation axis 10 faces) substantially coincides with the magnetic center of the armature 24 of the fixed assembly 2. It is arranged at a position facing the armature 24.
[0037]
The magnetic shield plate 34 shields the magnetism from the field magnet 33, is formed in an annular shape around the rotating shaft 10, and is formed of a ferromagnetic material. 33 and is fixed to the outer peripheral surface of the cylindrical portion 313 of the rotor hub 31.
[0038]
FIG. 3 is an enlarged view showing the right side from the rotation shaft 10 of the motor 1 in FIG. Next, the bearing mechanism 4 that rotatably supports the rotating assembly 3 with respect to the fixed assembly 2 will be described. The bearing mechanism 4 is an ST (single thrust) type that supports in the thrust direction parallel to the rotating shaft 10 between the lower surface (the surface on the shaft 30 side) of the disk portion 312 of the rotor hub 31 and the upper end surface of the sleeve 22. The rotor hub 31 (particularly, the shaft 30 and the disk portion 312), the sleeve 22, and the seal cap 23 constitute a main part. Further, a lubricating oil 50 is appropriately interposed between these components.
[0039]
The outer peripheral surface of the shaft 30 is a bearing surface 41b, and the inner peripheral surface of the sleeve 22 is a bearing surface 41a facing the bearing surface 41b. A minute gap 51 is provided between the bearing surface 41a and the bearing surface 41b. The gap 51 extends from the fixed end side of the shaft 30 to the free end side (from the upper end side to the lower end side of the sleeve 22), and lubricates. Oil 50 is continuously present. A groove (not shown) for generating a fluid dynamic pressure of a pair of herringbones is formed on at least one of the bearing surface 41a and the bearing surface 41b, and the rotation of the rotor hub 31 causes the pressure of the lubricating oil 50 in the gap 51 to increase. Is maximum at the center of the groove of each herringbone, that is, raised at two points on the free end side and the fixed end side of the shaft 30. Since the grooves of the pair of herringbones are symmetrical to each other, the generated pressures are the same and are in a balanced state (that is, lubricating oil does not flow to either one). As a result, a fluid dynamic pressure is generated in the gap 51 so as to separate the bearing surface 41a and the bearing surface 41b in a direction perpendicular to the rotating shaft 10, and the rotor hub 31 radially moves at the bearing surfaces 41a and 41b by the fluid dynamic pressure. Supported in the direction.
[0040]
The lower surface (the surface on the shaft 30 side) of the disk portion 312 of the rotor hub 31 is also a bearing surface 42b, and the upper end surface of the sleeve 22 is a bearing surface 42a facing the bearing surface 42b. A minute gap 52 is provided between the bearing surface 42a and the bearing surface 42b, and the gap 52 communicates with the gap 51 on the fixed end side of the shaft 30, and extends from the inner circumferential surface side of the sleeve 22 to the outer circumferential surface side. And the lubricating oil 50 is continuously present. A spiral fluid dynamic pressure generating groove (not shown) is formed in at least one of the bearing surface 42a and the bearing surface 42b. The rotation of the rotor hub 31 causes the pressure of the lubricating oil 50 in the gap 52 to rotate. It is raised on the shaft 10 side. Accordingly, a fluid dynamic pressure is generated in the gap 52 in a direction parallel to the rotating shaft 10 to separate the bearing surfaces 42a and 42b from each other, and the rotor hub 31 causes the bearing surfaces 42a and 42b to move by the fluid dynamic pressure. Is supported in the thrust direction.
[0041]
In the motor 1, by utilizing the fluid dynamic pressure of the lubricating oil 50, the rotor hub 31 can be rotated with high accuracy and low noise by non-contact support. Note that the bearing surfaces 41a and 41b and the bearing surfaces 42a and 42b are coated with a mixture containing molybdenum disulfide in order to reduce frictional resistance at the start of rotation of the motor 1.
[0042]
A minute gap 53 is provided between an end surface 43b on the free end side of the shaft 30 and the upper surface 43a of the seal cap 23, and the gap 53 communicates with the gap 51 on a side surface on the free end side of the shaft 30. The lubricating oil 50 exists continuously over the entire upper surface of the seal cap 23. The seal cap 23 prevents the lubricating oil 50 from flowing out from the lower end of the sleeve 22. Since the lubricating oil is continuous between the gap 53 and the gaps 51 and 52, and the pressure of the lubricating oil in the gap 51 is in a balanced state, the pressure of the lubricating oil in the gap 53 affects the fluid dynamic pressure in the gap 51. It becomes the same as the gap 52 without receiving it.
[0043]
As described above, the flange portion 221 projecting outward with respect to the rotary shaft 10 is integrally formed on the upper end side of the sleeve 22, and the outer peripheral surface 44 a of the flange portion 221 and the cylindrical portion 313 of the rotor hub 31 are formed. A gap 54 is provided between the inner peripheral surface 44b and the inner peripheral surface 44b. The gap 54 communicates with the gap 52 at the upper end of the outer peripheral surface of the sleeve 22, and is filled with the lubricating oil 50 from the upper end to the lower end of the flange portion 221. The gap 54 gradually widens from the upper end side to the lower end side of the flange portion 221, and a taper seal is formed in which the interface of the lubricating oil 50 has a meniscus shape due to capillary action and surface tension, and serves as an oil buffer. In addition, the outflow of the lubricating oil 50 is prevented.
[0044]
The lubricating oil 50 is continuously and continuously filled from the gap 54 to the gaps 52, 51, and 53, and the bearing mechanism 4 has an interface of the lubricating oil 50 only in the gap 54 (that is, the interface is 1). So-called full-fill structure. As a result, since no air is interposed in the bearing, abnormal contact between the shaft 30 and the sleeve 22 due to bubbles generated in the lubricating oil 50, leakage of the lubricating oil 50 due to expansion of the air inside the bearing, and the like are prevented. Be suppressed.
[0045]
A communication hole 60 filled with the lubricating oil 50 is formed in the sleeve 22. The communication hole 60 penetrates through the sleeve 22 from the upper end surface of the sleeve 22 toward the lower end surface thereof in parallel with the rotation shaft 10. The opening of the communication hole 60 is formed by the shaft 30 and the sleeve 22 in the direction in which the rotation shaft 10 faces. Are located on both sides (the fixed end side and the free end side of the shaft 30) of the gap 51 between them. Thereby, the communication hole 60 communicates the lubricating oil in the gap 52 on the fixed end side of the shaft 30 and the lubricating oil in the gap 53 on the free end side. As a result, the pressure of the lubricating oil in the gap 51 does not reach a desired balance state due to a machining error in the groove for generating fluid dynamic pressure and the bearing surfaces 41a and 41b, and a pressure difference is generated between the gaps 52 and 53. Even in this case, the gaps 52 and 53 are connected to each other by the communication hole 60, so that no pressure difference occurs. Thereby, the rotating assembly 3 is stably supported in the thrust direction without the lubricating oil leaking or generating bubbles. The communication hole 60 also serves to supply the lubricating oil 50 to the bearing gap or to store the lubricating oil 50.
[0046]
The communication hole 60 is formed in a substantially circular shape by, for example, electric discharge machining or drilling, and has a diameter of a cross section perpendicular to a direction in which the communication hole 60 extends is at least about 1.0 mm at least in part. When the cross section is not substantially circular, the diameter mentioned here corresponds to the maximum width of the cross section perpendicular to the direction in which the communication hole 60 extends.
[0047]
Further, the coating film 61 is formed over the entire inner surface of the communication hole 60 with a material having a property of retaining foreign matter remaining when the communication hole 60 is formed. The material of the coating film 61 is preferably, for example, a mixture containing molybdenum disulfide similarly to the material for coating the bearing surfaces 41a, 41b, 42a, and 42b, whereby the bearing surfaces 41a, 41b, 42a, and 42b are formed. In addition to diverting the applied material, even if a mixture containing molybdenum disulfide adheres to the outside of the communication hole 60, the bearing performance is not affected and the workability is good.
[0048]
The coating film 61 is formed by injecting molybdenum disulfide into the communication hole 60 after forming the communication hole 60. The mixture containing molybdenum disulfide has a property of holding a small object of about 1.0 mm or less. By injecting this mixture into the communication hole 60, the mixture covers the remaining foreign matter in the communication hole 60. The covering film 61 is formed so as to cover, and the foreign matter remaining when the communication hole 60 is formed or the like is held (or fixed) by the covering film 61 in the communication hole 60. This thickness is, for example, about 0.1 mm so as not to block the communication hole 60 and to hold foreign matter.
[0049]
Thereby, even if the lubricating oil 50 flows in the communication hole 60 when the rotor hub 31 rotates, foreign matter is more reliably prevented from flowing out of the communication hole 60, and the foreign matter is prevented from flowing into the bearing (that is, the gap 51 or the gap 52). Of the bearing is prevented, and a decrease in bearing performance is prevented.
[0050]
By the way, in the case of the ST type aiming at miniaturization like the bearing mechanism 4, since the diameter of the communication hole 60 is small, foreign matter is easily caught in the communication hole 60, and is sufficiently removed by ordinary cleaning during motor manufacturing. Is difficult. Therefore, it can be said that the above-described prevention of foreign matter outflow by covering the communication hole 60 is an effective method in the bearing mechanism 4 of the ST type. In particular, when the diameter of the communication hole 60 is about 1.0 mm or less, the size of the foreign matter is close to the diameter of the communication hole 60, the foreign matter is easily caught, and the ultrasonic cleaning of the communication hole 60 becomes difficult. Prevention of the outflow of foreign matter by covering the communication hole 60 is a more effective method. In other words, this method does not solve the problem of the foreign matter remaining in the communication hole 60 by removing the foreign matter from the communication hole 60 but intentionally holds the foreign matter in the communication hole 60 so as not to flow out. It is. Therefore, in the former method, the possibility of outflow remains unless the foreign matter is completely removed. However, in the latter method (this embodiment), the uniform covering is performed regardless of whether the foreign matter remains in the communication hole 60. Thus, there is virtually no possibility of spills.
[0051]
The motor 1 is configured such that the rotating assembly 3 is rotatably supported by the fixed assembly 2 by such a bearing mechanism 4, and the current supplied to the armature 24 is controlled so that the field magnet 33 and the armature The rotating assembly 3 is driven to rotate about the rotating shaft 10 (which is also the central axis of the shaft 30 and the sleeve 22) with respect to the fixed assembly 2 by the magnetic action with the rotating assembly 24. Thereby, the disk-shaped recording medium 72 mounted on the disk mounting portion 314 (see FIG. 2) is driven to rotate. The reliability of the motor 1 and the disk drive device 70 is improved by the bearing mechanism 4.
[0052]
FIG. 4 is a longitudinal sectional view showing a configuration of a motor 1a of a disk drive device according to a second embodiment of the present invention, and FIG. 5 is an enlarged view of a right side of a rotation shaft 10 of the motor 1a in FIG. FIG. In the present embodiment, the configuration of the disk drive device other than the motor 1a is the same as that of the first embodiment, and a description thereof will be omitted. In the motor 1a, the same components as those in the first embodiment are denoted by the same reference numerals.
[0053]
The motor 1a according to the second embodiment includes a fixed assembly 2 and a rotating assembly 3, and the rotating assembly 3 is fixed to the fixed assembly 2 by a bearing mechanism 4 utilizing a fluid dynamic pressure of lubricating oil. Are supported so as to be rotatable about the rotation shaft 10. The fixing assembly 2 is the same as the first embodiment except that the communication hole 60 is not formed in the sleeve 22. In the rotating assembly 3, the shaft 30 is configured by fitting and fixing the cylindrical outer cylinder member 35 to the shaft portion 311 of the rotor hub 31. Other configurations of the rotary assembly 3 are the same as those of the first embodiment.
[0054]
Next, the bearing mechanism 4 will be described with reference to FIG. The bearing mechanism 4 is provided between the lower surface of the disk portion 312 (the surface on the shaft 30 side) of the rotor hub 31 and the upper end surface of the sleeve 22 in the thrust direction parallel to the rotating shaft 10 as in the first embodiment. It is of an ST (single thrust) type for supporting, in which the shaft portion 311 of the rotor hub 31 and the outer cylindrical member 35 (that is, the shaft 30) are inserted into the sleeve 22. To support.
[0055]
A gap 51 between a bearing surface 41b which is an outer peripheral surface of the shaft 30 and a bearing surface 41a which is an inner peripheral surface of the sleeve 22, a bearing surface 42b which is a lower surface of the disk portion 312, and a bearing surface which is an upper end surface of the sleeve 22. 42a, the gap 53 between the free end side end surface 43b of the shaft 30 and the upper surface 43a of the seal cap 23, the outer peripheral surface 44a of the flange portion 221 and the inner peripheral surface 44b of the cylindrical portion 313. The gap 54 between them is the same as in the first embodiment. That is, the bearing surfaces 41a, 41b, 42a, and 42b in which grooves for generating fluid dynamic pressure are formed as required are covered with a mixture containing molybdenum disulfide, and the gaps 53 to the gaps 51, 52, and 54 are formed. The lubricating oil 50 exists continuously and has a so-called full-fill structure. However, the bearing surface 41b which is the outer peripheral surface of the shaft 30 becomes the outer peripheral surface of the outer cylindrical member 35.
[0056]
A gap 55 is provided between the upper end surface of the outer cylinder member 35 and the lower surface of the disk portion 312, and the gap 55 is a gap 51 which is a radial bearing and a gap which is a thrust bearing at the fixed end side of the shaft 30. Call 52. The shaft 30 has a communication hole 60 a formed between the outer cylindrical member 35 and a spirally formed groove from the fixed end side to the free end side of the shaft portion 311. In FIG. 5, only two cross sections of the spiral communication hole 60a are shown, and each of these cross sections is denoted by reference numeral 60a.
[0057]
As in the first embodiment, the openings of the communication holes 60a are located on both sides of the gap 51 (the fixed end side and the free end side of the shaft 30) in the direction in which the rotating shaft 10 faces, and the communication holes 60a are radial. The lubricating oil on both sides of the gap 51 as a bearing, that is, the lubricating oil on the gap 55 on the upper side (fixed end side of the shaft 30) of the outer cylinder member 35 and the lubricating oil on the lower side (free end side of the shaft 30) 53 Communicate with lubricating oil.
[0058]
As in the first embodiment, the communication hole 60a has a diameter of a cross section perpendicular to the direction in which the communication hole 60a extends at least in part (when the communication hole is not substantially circular, the communication hole 60a extends in the direction in which the communication hole 60a extends). (The maximum width of the vertical cross-sectional shape) is about 1.0 mm or less. A coating film 61 of a mixture containing molybdenum disulfide is formed on the inner side surface of the communication hole 60a. The coating film 61 is formed by injecting molybdenum disulfide into the communication hole 60a, whereby foreign matter remaining when the communication hole 60a is formed or the like is retained in the communication hole 60a.
[0059]
As described above, in the motor 1a according to the second embodiment, the communication hole 60a is provided in the shaft 30. Even in this case, by covering the communication hole 60a with a material having a property of retaining foreign matter, even if the lubricating oil 50 flows through the communication hole 60 when the rotor hub 31 rotates, the foreign matter may be removed from the inside of the communication hole 60. Outflow is more reliably prevented. As a result, foreign substances are prevented from entering the inside of the bearing (that is, the gap 51 and the gap 52), and a decrease in bearing performance is suppressed. In particular, when the bearing mechanism 4 is of the ST type for the purpose of miniaturization, and the diameter of the communication hole 60a is about 1.0 mm or less, the covering of the communication hole 60a further prevents the outflow of foreign matter. Method. Then, the reliability of the motor 1a and the disk drive device is improved by the bearing mechanism 4.
[0060]
FIG. 6 is a longitudinal sectional view showing the configuration of the motor 1b of the disk drive device according to the third embodiment of the present invention. FIG. 7 is an enlarged view of the right side from the rotation shaft 10 of the motor 1b in FIG. FIG. In the present embodiment, the configuration of the disk drive device other than the motor 1b is the same as in the first embodiment, and a description thereof will be omitted. In the motor 1b, the same components as those in the first embodiment are denoted by the same reference numerals.
[0061]
The motor 1b includes a fixed assembly 2b and a rotating assembly 3b, and the rotating assembly 3b is centered on the rotating shaft 10 with respect to the fixed assembly 2b by a bearing mechanism 4b using a fluid dynamic pressure of lubricating oil. Supported rotatably.
[0062]
The fixing assembly 2b includes a base plate 21b, a sleeve 22b, a seal cap 23b, and an armature 24. The base plate 21b has a bottom plate part 211 and a sleeve holding part 212. The sleeve holding portion 212 projects cylindrically at the center of the bottom plate portion 211, and the sleeve 22b is held in the sleeve holding portion 212. The inner peripheral surface of the sleeve 22b gradually increases in diameter toward the upper end on the upper end side, gradually increases toward the lower end side on the lower end side, and increases in diameter near the middle between the upper end side and the lower end side. Is constant. The seal cap 23b has an air hole 231 at the center, and is attached to the end face on the lower end side of the sleeve 22b. The armature 24 is fixed to the outer peripheral surface of the sleeve holding section 212.
[0063]
The rotating assembly 3b includes a rotor hub 31b, a field magnet 33, and a cone member 36. The rotor hub 31b has a shaft portion 311, a disk portion 312, a cylindrical portion 313, and a disk mounting portion 314.
[0064]
The shaft portion 311 is provided along the rotating shaft 10, the disk portion 312 extends outward from the fixed end side of the shaft portion 311 perpendicularly to the rotating shaft 10, and the cylindrical portion 313 extends from the outer periphery of the disk portion 312 to the shaft portion. 311 protrude cylindrically toward the free end side, and these have a shape similar to the motor 1a according to the second embodiment. The field magnet 33 is attached to the inner peripheral surface of the cylindrical portion 313 and is disposed around the shaft portion 311. The armature 24 faces the field magnet 33 and rotates between the field magnet 33 and the field magnet 33. A rotational force centered at 10 is generated.
[0065]
A first conical portion 318 is formed on the free end side of the shaft portion 311 by fitting and adhering and fixing a substantially conical cone member 36. The diameter of the outer peripheral surface of the cone member 36 gradually increases toward the free end side of the shaft portion 311. That is, the outer peripheral surface of the first conical portion 318 is a substantially conical inclined surface whose diameter gradually increases toward the free end side. Further, a second conical portion 319 is integrally formed on the fixed end side of the shaft portion 311. The outer peripheral surface of the second conical portion 319 is a substantially conical inclined surface whose diameter gradually increases toward the fixed end. As described above, in the rotating assembly 3b, the shaft portion 311 and the cone member 36 form the substantially conical first conical portion 318 whose diameter gradually increases toward the free end along the rotating shaft 10, The shaft 30 has a substantially conical second conical portion 319 whose diameter gradually increases toward the solid end along the axis 10.
[0066]
Next, the bearing mechanism 4b will be described with reference to FIG. The bearing mechanism 4b includes the rotor hub 31b, the cone member 36, the sleeve 22b, and the seal cap 23b, and the shaft 311 and the cone member 36 of the rotor hub 31b (ie, components of the shaft 30) are inserted from above and below the sleeve 22b. Accordingly, the sleeve 22b supports the rotor hub 31b so as to be rotatable around the rotation shaft 10.
[0067]
The bearing mechanism 4b includes a bearing surface 46b that is an outer peripheral surface of the first conical portion 318 (that is, the cone member 36), a bearing surface 46a that is a lower portion of the inner peripheral surface of the sleeve 22b, and an outer peripheral surface of the second conical portion 319. This is a cone type in which a lubricating oil 50 is interposed between the bearing surface 47b and the bearing surface 47a, which is the upper part of the inner peripheral surface of the sleeve 22b, to support in the radial direction and the thrust direction, respectively.
[0068]
The lower bearing surface 46a of the sleeve 22b is inclined to face the inclination of the bearing surface 46b of the first conical portion 318, and a small gap 56 is formed between the bearing surface 46a and the bearing surface 46b. The upper bearing surface 47a of the sleeve 22b is inclined to face the inclination of the bearing surface 47b of the second conical portion 319, and a small gap 57 is formed between the bearing surface 47a and the bearing surface 47b. As in the first embodiment, the bearing surfaces 46a, 46b, 47a, and 47b are coated with a mixture containing molybdenum disulfide to improve lubricity.
[0069]
A gap 58 is provided between the outer peripheral surface between the first conical portion 318 and the second conical portion 319 of the shaft 30 and the inner peripheral surface of the sleeve 22b near the center in the direction of the rotation axis 10. 58 communicates with the gap 56 at the upper end of the first conical portion 318 and communicates with the gap 57 at the lower end of the second conical portion 319.
[0070]
The gap 59 between the lower end surface of the first conical portion 318 and the upper surface of the seal cap 23b gradually increases from the outer peripheral surface side of the first conical portion 318 toward the rotating shaft 10. The lower end side (the free end side of the shaft 30) communicates with the gap 56. Thus, a taper seal is formed in which the interface of the lubricating oil 50 becomes a meniscus shape due to capillary action and surface tension, and serves as an oil buffer and prevents the lubricating oil 50 from flowing out.
[0071]
Similarly, also near the fixed end of the shaft 30 (near the upper end of the sleeve 22b), the end of the gap 57 gradually widens toward the fixed end of the shaft 30, and a taper seal is formed. The lubricating oil 50 exists continuously from the gap 57 to the gaps 58, 56, 59.
[0072]
The first conical portion 318 has a communication hole 60b penetrating from the upper end to the lower end of the first conical portion 318 in parallel with the outer peripheral surface of the first conical portion 318. Are located on both sides of the gap 56 (the fixed end side and the free end side of the shaft 30) in the direction in which the rotating shaft 10 faces. The communication hole 60b allows the lubricating oil 50 between the gap 58 and the gap 59 on both sides of the gap 56 to communicate with each other.
[0073]
The communication hole 60b is formed by, for example, electric discharge machining or drilling, similarly to the first embodiment, and has a diameter of a cross section perpendicular to the direction in which the communication hole 60b extends, at least in a part, that is, the direction in which the communication hole 60b extends. Has a maximum width of about 1.0 mm or less. Further, by injecting the mixture containing molybdenum disulfide, a coating film 61 of the mixture containing molybdenum disulfide is formed on the entire inner surface of the communication hole 60b. Thus, foreign matter remaining when the communication hole 60b is formed or the like is held in the communication hole 60b.
[0074]
At least one of the bearing surfaces 46a and 46b and at least one of the bearing surfaces 47a and 47b are formed with grooves (not shown) for generating a hydrodynamic pressure of a herringbone. When the rotor hub 31b rotates, pressure is generated in each of the gap 56 and the gap 57 so that the lubricating oil 50 flows toward the center of the gap 58. As a result, a fluid dynamic pressure in a direction in which the bearing surfaces 46a and 46b are separated from each other and a fluid dynamic pressure in a direction in which the bearing surfaces 47a and 47b are separated from each other are generated. It is supported by pressure in a radial direction perpendicular to the rotating shaft 10 and in a thrust direction parallel to the rotating shaft 10.
[0075]
When the rotor hub 31b rotates, the pressure in the lubricating oil 50 in the gap 58 is increased by the fluid dynamic pressure (pumping force) generated in the gap 56 and the gap 57, and the lubricating oil 50 in the gap 58 is separated through the communication hole 60b. It circulates to 56 and flows. As a result, even if bubbles are generated in the lubricating oil 50 in the gaps 56, 57, and 58, the bubbles are released from the gap 59 to the atmosphere via the communication holes 60b. Therefore, the pressure balance of the lubricating oil 50 in the gaps 56 to 59 is maintained, so that the lubricating oil 50 leaks out of the bearing and abnormal contact between the bearing surfaces is prevented.
[0076]
In the bearing mechanism 4b, since the inside of the communication hole 60b is covered with a material having a property of retaining foreign matter, it is possible to more reliably prevent the outflow of foreign matter, as in the first embodiment. Further, the bearing mechanism 4b is a cone type for the purpose of miniaturization, and the diameter of the communication hole 60b is reduced (especially, about 1.0 mm or less), so that it is difficult to remove it sufficiently by ordinary cleaning. Even if it does, the outflow of foreign matter can be prevented. As a result, a decrease in bearing performance is prevented. Further, in the motor 1b including the bearing mechanism 4b and the disk drive device, the reliability is improved.
[0077]
In the first to third embodiments, the coating film 61 may be formed of a mixture containing carbon instead of molybdenum disulfide (so-called diamond-like carbon coat). The mixture containing carbon is a material that is coated on the bearing surface in order to harden the surface and reduce generation of wear powder. Even if carbon adheres to the outside of the communication hole, it does not affect bearing performance. Further, the coating film 61 is not limited to a mixture containing molybdenum disulfide or carbon, and may be another material such as a resin or a metal as long as the material has a property of retaining foreign matter remaining in the communication hole. Good. Furthermore, the coating film 61 only needs to be formed on at least a part of the inner surface of the communication hole, and the coating film 61 may be formed after cleaning the communication hole in order to further suppress the outflow of foreign matter. .
[0078]
FIG. 8 is an enlarged longitudinal sectional view showing a right side of a rotation shaft 10 of a motor 1c of a disk drive device according to a fourth embodiment of the present invention. In the present embodiment, the configuration of the disk drive device other than the motor 1c is the same as that of the first embodiment, and a description thereof will be omitted. In the motor 1c, the same components as those in the first embodiment are denoted by the same reference numerals, and description thereof will be omitted.
[0079]
In the motor 1c, the rotating assembly 3 is supported by the fixed assembly 2 so as to be rotatable around the rotating shaft 10 by the bearing mechanism 4 utilizing the fluid dynamic pressure of the lubricating oil 50. In the bearing mechanism 4, a filter 62 (for example, a membrane filter) is disposed in the communication hole 60 instead of the coating film 61 in the first embodiment. The other configuration of the bearing mechanism 4 is the same as that of the first embodiment, and is a so-called full-fill ST type in which the lubricating oil 50 is continuously provided from the gap 53 to the gaps 51, 52, and 54. I have.
[0080]
The communication hole 60 has a diameter of a cross section perpendicular to the direction in which the communication hole 60 extends, that is, the maximum width of a cross section perpendicular to the direction in which the communication hole 60 extends, at least in part, as in the first embodiment. The filter 62 is set to 1.0 mm or less, and the filters 62 are arranged in two places near the openings on both sides in the communication hole 60 (that is, near the opening on the gap 52 side and near the opening on the gap 53 side).
[0081]
In the bearing mechanism 4, when the lubricating oil 50 flows in the communication hole 60, foreign matter remaining in the communication hole 60 is retained by the filter 62 in the communication hole 60 when the communication hole 60 is formed. In particular, since the filter 62 is arranged near the opening on both sides of the communication hole 60, the foreign matter is confined in the communication hole 60, and the foreign matter is prevented from flowing out regardless of the flow direction of the lubricating oil 50. As a result, foreign substances are prevented from entering the inside of the bearing (that is, the gap 51 and the gap 52), and a decrease in bearing performance is prevented.
[0082]
The bearing mechanism 4 is of the ST type for the purpose of miniaturization, and the diameter of the communication hole 60 is small (particularly, the diameter of a cross section perpendicular to the extending direction of the communication hole 60 is at least about 1.0 mm or less at least in part). Therefore, foreign substances that cannot be removed by ordinary washing are effectively prevented from flowing out of the communication holes 60, and the reliability of the motor 1c and the disk drive device having such a bearing mechanism 4 is improved. .
[0083]
FIG. 9 is a diagram showing a motor 1d according to the second embodiment in which a filter 62a (for example, a membrane filter) is provided in the communication hole 60a instead of the coating film 61 in the communication hole 60a. Other configurations of the disk drive device provided with the motor 1d and the motor 1d are the same as those of the second embodiment, and the same components are denoted by the same reference numerals.
[0084]
The filters 62a are arranged at two positions near the openings on both sides in the communication hole 60a (that is, near the opening on the gap 53 side and near the opening on the gap 55 side). As a result, similarly to the motor 1c shown in FIG. 8, foreign matter is prevented from flowing out from the communication hole 60a having a small diameter, deterioration in bearing performance is prevented, and reliability of the motor 1d and the disk drive device is improved. You.
[0085]
FIG. 10 is a view showing a motor 1e in which a filter 62b (for example, a membrane filter) is provided in the communication hole 60b in place of the coating film 61 in the motor 1b according to the third embodiment. Other configurations of the disk drive device having the motor 1e and the motor 1e are the same as those of the third embodiment, and the same components are denoted by the same reference numerals.
[0086]
The filters 62b are arranged at two places near the openings on both sides in the communication hole 60b (that is, near the opening on the gap 58 side and near the opening on the gap 59 side). As a result, similarly to the third embodiment, in the cone type bearing mechanism 4b for miniaturization, it is difficult to remove foreign matter by ordinary cleaning. 1) prevents foreign matter from flowing out of the communication hole 60b, prevents deterioration of bearing performance, and improves the reliability of the motor 1e and the disk drive device.
[0087]
In the fourth to sixth embodiments, the filter does not necessarily need to be arranged near the opening on both sides of the communication hole, and may be arranged at one place in the communication hole. In this case, the filter may be arranged at any position such as near the opening of the communication hole, near the center, or the like.
[0088]
As described above, the embodiments of the present invention have been described, but the present invention is not limited to the above embodiments, and various modifications are possible.
[0089]
The communication hole may be provided in various forms in the shaft or the sleeve. For example, in the ST type motors 1 and 1c, the communication hole 60 does not need to be formed in a linear shape, and the communication hole 60a in the motors 1a and 1d may be provided in the shaft 30 in a linear or folded line. In the cone type motors 1b and 1e, the communication hole 60b may be provided in the second conical portion 319, and a communication hole which connects the gap 58 and the gap 59 may be provided on the sleeve 22b side.
[0090]
The communication hole is provided in the case where the lubricating oil at both sides communicating with a specific gap (gap 51 or gap 56) is communicated with respect to the direction in which the rotating shaft 10 faces (that is, the openings at both ends of the communication hole are located on both sides of the gap). However, the present invention is not limited to this case, and one opening may open toward the inside of the gap and the other opening may be located outside the gap. As a result, it is possible to balance the pressure of the lubricating oil inside and outside the gap existing substantially along the direction of the rotating shaft 10, and to stably support the rotating assembly. Further, both openings may be formed in the gap depending on the shape of the fluid dynamic pressure generating groove formed in the gap. That is, the communication hole may be provided in any way as long as it allows the lubricating oil to communicate with the specific gap or at two locations communicating with the gap.
[0091]
Further, the structure of the motor may be variously modified. For example, in the ST type motors 1, 1a, 1c, and 1d, a thrust bearing may be further provided on the free end side of the shaft 30. As for the cone type motors 1b and 1e, only one conical portion may be provided.
[0092]
In the above embodiment, in the motor, the field magnet may be arranged on either the rotating shaft side of the armature or outside the armature. Further, the armature may be provided on the rotating assembly side, and the field magnet may be provided on the fixed assembly side. Further, the shaft may be provided on the fixed assembly side, and the sleeve may be provided on the rotating assembly side. The field magnets and the armatures may also be vertically arranged in the direction in which the rotating shaft 10 faces.
[0093]
The disk drive device 70 is not limited to a hard disk device, and may be a disk drive device such as a removable disk device.
[0094]
【The invention's effect】
According to the first to third aspects of the present invention, it is possible to prevent a decrease in bearing performance and improve the reliability of the motor.
[0095]
According to the fourth to tenth aspects of the present invention, it is possible to prevent a decrease in bearing performance, and according to the eleventh aspect of the present invention, it is possible to improve the reliability of the motor.
[0096]
In the twelfth aspect, the reliability of the disk drive device can be improved.
[Brief description of the drawings]
FIG. 1 is a diagram showing a disk drive device according to a first embodiment.
FIG. 2 is a longitudinal sectional view showing a motor of the disk drive device.
FIG. 3 is an enlarged longitudinal sectional view showing a motor.
FIG. 4 is a longitudinal sectional view showing a motor of a disk drive device according to a second embodiment.
FIG. 5 is an enlarged longitudinal sectional view showing a motor.
FIG. 6 is a longitudinal sectional view showing a motor of a disk drive device according to a third embodiment.
FIG. 7 is an enlarged longitudinal sectional view showing a motor.
FIG. 8 is an enlarged longitudinal sectional view showing a motor of a disk drive device according to a fourth embodiment.
FIG. 9 is an enlarged longitudinal sectional view showing a motor.
FIG. 10 is an enlarged longitudinal sectional view showing a motor.
[Explanation of symbols]
1,1a, 1b, 1c, 1d, 1e motor
2,2b fixing assembly
3,3b rotating assembly
4,4b bearing mechanism
10 Rotation axis
22, 22b sleeve
23, 23b Seal cap
24 armature
30 shaft
31, 31b Rotor hub
33 Field magnet
35 Outer cylinder member
36 cone members
41a, 41b, 42a, 42b, 46a, 46b Bearing surface
50 Lubricating oil
51-59 gap
60, 60a, 60b Communication hole
61 Coating film
62, 62a, 62b filters
311 Shaft
312 disk part
313 cylindrical part
318,319 Conical part
70 Disk drive
71 Housing
72 Recording medium
73 Access section

Claims (12)

An electric motor,
A first assembly having a shaft;
A second assembly having a bottomed sleeve into which the shaft is inserted;
With
One of the first assembly and the second assembly has a field magnet disposed around the shaft;
The other assembly has an armature that faces the field magnet and generates a rotational force about the center axis of the shaft between the field magnet and the assembly.
The first assembly comprises:
A disk portion extending outward from the fixed end of the shaft with respect to the central axis,
A cylindrical portion protruding from the disc portion to the free end side of the shaft along the outer periphery of the sleeve around the center axis;
Further having
At least one of the shaft-side surface of the disk portion and the end surface of the sleeve facing the disk portion, and at least one of the inner peripheral surface of the sleeve and the outer peripheral surface of the shaft. A groove for generating fluid dynamic pressure is formed, a gap between the disk portion and the sleeve, a gap between the sleeve and the shaft, and a free end side surface of the shaft and a bottom surface of the sleeve. Lubricating oil is continuously present in the gap between
The sleeve or the shaft,
A communication hole for communicating the lubricating oil on the fixed end side and the lubricating oil on the free end side of the shaft,
A filter arranged in the communication hole,
A motor having: An electric motor,
A first assembly having a shaft;
A second assembly having a sleeve into which the shaft is inserted;
With
One of the first assembly and the second assembly has a field magnet disposed around the shaft;
The other assembly has an armature that faces the field magnet and generates a rotational force about the center axis of the shaft between the field magnet and the assembly.
The shaft has a substantially conical conical portion whose diameter gradually increases along the central axis,
The sleeve has an inclined surface facing a side surface of the conical portion,
A groove for generating fluid dynamic pressure is formed on at least one of the side surface and the inclined surface of the conical portion, and lubricating oil is continuously provided in a gap between the side surface of the conical portion and the inclined surface. Exist
The sleeve or the shaft,
A communication hole for communicating the lubricating oil present at both ends of the shaft with respect to the side surface of the conical portion,
A filter arranged in the communication hole,
A motor having: The motor according to claim 1 or 2,
A motor, wherein at least a part of the communication hole has a diameter of a cross section perpendicular to a direction in which the communication hole extends is 1.0 mm or less. A bearing mechanism,
A first member;
A second member that supports the first member rotatably about a predetermined central axis;
With
A groove for generating fluid dynamic pressure is formed in at least one of a first bearing surface of the first member and a second bearing surface of the second member facing the first bearing surface; Lubricating oil is continuously present in a gap between the first bearing surface and the second bearing surface,
The first member or the second member has a communication hole that communicates the lubricating oil in the gap or at two sites communicating with the gap,
A bearing mechanism, wherein at least a part of the inner surface of the communication hole is coated with a material having a property of retaining foreign matter remaining in the communication hole. The bearing mechanism according to claim 4, wherein
Regarding the direction in which the central axis faces, openings at both ends of the communication hole are located on both sides of the gap, or one opening is located in the gap and the other opening is located outside the gap. Bearing mechanism. The bearing mechanism according to claim 4 or 5,
The first bearing surface is an outer peripheral surface of the shaft about the central axis,
The bearing mechanism, wherein the second bearing surface is an inner peripheral surface of a bottomed sleeve into which the shaft is inserted. The bearing mechanism according to claim 6, wherein
The first member further includes a disk portion extending outward from the fixed end of the shaft with respect to the central axis,
A groove for generating fluid dynamic pressure is formed in at least one of the shaft-side surface of the disk portion and an end surface of the sleeve facing the disk portion, and a first bearing surface and the second bearing surface are formed. Lubricating oil from a first gap between the bearing surface to a second gap between the disk portion and the sleeve, and further to a third gap between the free end surface of the shaft and the bottom surface of the sleeve; Exist continuously,
The communication hole communicates the lubricating oil in a portion communicating between the first gap and the second gap or the lubricating oil in the second gap with the lubricating oil in the third gap. Bearing mechanism. The bearing mechanism according to claim 6, wherein
The shaft has a substantially conical portion whose diameter gradually increases along the central axis, and the first bearing surface is a side surface,
The sleeve has an inclined surface that is the second bearing surface facing a side surface of the conical portion,
A bearing mechanism, wherein openings in both ends of the communication hole are located on both sides of the gap in a direction in which the central axis faces. The bearing mechanism according to any one of claims 4 to 8, wherein
The bearing mechanism, wherein the material is a mixture containing molybdenum disulfide or carbon. The bearing mechanism according to any one of claims 4 to 9, wherein
A bearing mechanism, wherein at least a part of the communication hole has a diameter of a cross section perpendicular to a direction in which the communication hole extends is 1.0 mm or less. An electric motor,
A bearing mechanism according to any one of claims 4 to 10,
A field magnet and an armature for rotating the first member relative to the second member about the central axis;
A motor comprising: A disk drive,
A housing for accommodating a disk-shaped recording medium for recording information,
The motor according to any one of claims 1 to 11, wherein the motor is fixed inside the housing and rotates the recording medium.
An access unit for writing or reading information on or from the recording medium.

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