JP3184795B2 - Spindle motor and rotating device using the spindle motor as a driving source of the rotating body - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a spindle motor in which a rotor is supported on a stator by a liquid dynamic bearing, and a rotating device using the spindle motor as a driving source of a rotating body.

[0002]

2. Description of the Related Art A dynamic pressure bearing can be reduced in size and can smoothly rotate at a high speed, and therefore is suitable for a bearing of a rotating body device in the field of computers, copying machines and the like. In particular, since the air dynamic pressure bearing does not use a lubricant such as oil, there is no danger of contaminating a rotating body such as a magnetic disk, and is widely used in a rotating body device for driving these. However, air bearings have drawbacks such as extremely low bearing stiffness and difficulty in manufacturing because the bearing clearance is on the order of several microns. For this reason, liquid dynamic pressure bearings that do not have such disadvantages, that is, liquid dynamic pressure bearings that have high bearing rigidity and are easy to manufacture, have been developed.

[0003] FIG. 11 is a schematic diagram of US Patent No. 5,487,608.
Patent Document 1: A conventional rotary device having a liquid dynamic pressure bearing in which a lower end of a bearing is a closed end, an upper end of the bearing is an open end, a radial bearing portion is provided at an upper portion, and a thrust bearing portion is provided at a lower portion. In a motor, when the spindle motor is rotating at high speed, the net flow of lubricating oil due to dynamic pressure is directed toward the closed end of the bearing in the radial bearing portion, and the lubricating oil is driven by the dynamic pressure in the thrust bearing portion. The structure of the radial bearing and the thrust bearing is devised so that the net flow of oil is directed toward the radial bearing, and the net flow combining these two is directed toward the closed end of the bearing. Thus, lubricating oil is prevented from leaking from the bearing when the motor is rotating at high speed. Further, a capillary seal is provided at an open end of the bearing so that the lubricating oil does not leak out of the bearing when the spindle motor is stopped.

That is, the radial dynamic pressure generating groove is a herringbone groove G1 as shown in FIG.
Are formed up and down on the outer peripheral surface with the communication hole 134 as a boundary.
The width of the upper herringbone groove in the axial direction is wider than that of the lower herringbone groove. At the same time, the grooves of the upper group that make up the substantially V-shape of the herringbone of each stage are slightly longer than the grooves of the lower group. The thrust dynamic pressure generating groove is a herringbone groove G2 as shown in FIG. 9, and the upper surface of the first disk-shaped thrust member 74 of the first thrust bearing portion and the second disk-shaped thrust member 76.
Are respectively formed on the upper surface of the. The area of the portion of the upper surface of the first disk-shaped thrust member 74 where the lubricating oil contacts is made smaller than that of the upper surface of the second disk-shaped thrust member 76.

The open end of the bearing is a cylindrical radial bearing member 5.
The upper end of a narrow gap formed between the outer peripheral surface of the second and the inner peripheral surface of the cylindrical radial member 70 communicates with the oil reservoir 160. The oil reservoir 160 forms a space having a shape that expands divergently from the bottom, which is the connection with the open end of the bearing, to the opening to the atmosphere. When the spindle motor is stopped, the lubricating oil fills the bottom of the flared oil reservoir 160 by capillary action, and the surface tension of the lubricating oil in this portion and the opening of the oil reservoir 160 The lubricating oil is prevented from leaking out of the open end of the bearing due to the negative pressure applied to the lubricating oil inside the bearing when moving in the direction of the part. Is given. By forming the oil reservoir 160 into a shape that is widened to the end, the oil reservoir 160 expands due to a large rise in ambient temperature and pressure and rises from the bottom of the oil reservoir 160.
0, so that it does not leak out of the bearing.

[0006] The spindle motor disclosed in the above-mentioned US Patent Publication is a practical liquid dynamic pressure bearing which has a higher bearing rigidity than the air dynamic pressure bearing and is easy to manufacture. However,
The fact that two members, a first disk-shaped thrust member 74 and a second disk-shaped thrust member 76, are required to form the thrust bearing portion, and the relationship between the dynamic pressure generating grooves, which are extremely difficult to machine structurally, are taken into consideration. The oil bearing hole 100, the radial dynamic pressure generating portion, and the thrust dynamic pressure generating portion for smoothing the flow of the lubricating liquid generated by the dynamic pressure. Since the upper communication hole 134 and the lower communication hole 102 connecting the parts must be provided in the cylindrical radial bearing member 52, the structure of the liquid dynamic pressure bearing is complicated. For this reason, it is difficult to reduce the size of the liquid dynamic pressure bearing having such a structure, and there is a problem that manufacturing is not always easy. Further, the capillary seal has a narrow gap formed between the outer peripheral surface of the cylindrical radial bearing member 52 and the inner peripheral surface of the cylindrical radial member 70, that is, a communication passage communicating with the bearing clearance of the upper radial bearing portion. In addition, since the oil reservoir 160 is formed so as to expand from the end of the communication passage to the opening to the atmosphere, the length of the cylindrical radial bearing member 52 cannot be shortened, and therefore, the size of the cylinder can be reduced. There is also a problem that is difficult.

The conventional spindle motor shown in FIG.
It is provided with a liquid dynamic pressure bearing which solves the above-mentioned problems. This liquid dynamic pressure bearing is a cylindrical bearing member erected on the fixed base 1, and further has a disk-shaped thrust bearing member 2a at an upper end, a radial bearing cylindrical portion 2b at an intermediate portion, and a support cylindrical portion 2c at a lower portion. A flanged cylindrical bearing member 2 having an oil reservoir through hole 2d formed at the center of the shaft, and a cylindrical bearing member integral with the cup-shaped rotor 6, wherein the flanged cylindrical bearing member 2 is rotatable. A cylindrical bearing member 3 having a stepped funnel-shaped recess having three-stage cylindrical portions accommodated therein; a sealing member 5 for sealing a lower opening end of the cylindrical bearing member in a liquid-tight manner; A thrust holding member 4 for sealing the upper open end of the bearing member in a liquid-tight manner, lubricating oil filled in gaps formed between these members, and a radial bearing cylindrical portion of the cylindrical bearing member 2; Outer peripheral surface and the cylinder And a communication passage and the oil reservoir S8 communicating with the gap of the radial bearing portion to be formed at the inner peripheral surface of the radial dynamic pressure bearing cylindrical portion of the bearing member 3 and S9 and the capillary seal comprising. However, the conventional device shown in FIG. 12 has a problem that the radial bearing cylindrical portion 2b cannot be reduced in size if the radial bearing cylindrical portion 2b is lengthened, and that the radial bearing cylindrical portion 2b cannot shorten the radial bearing cylindrical portion 2b when sufficient radial dynamic pressure cannot be obtained. is there. In addition, there is a problem that the communication path constituting the capillary seal is long, and the processing is not always easy together with the oil reservoir having a divergent cross-sectional shape connected to the communication path.

Further, the conventional spindle motors having the liquid dynamic pressure bearings shown in FIGS. 11 and 12 are caused by the fact that the direction of the axial displacement does not coincide with the direction of the restoring force against the displacement at the time of high-speed rotation. There is a problem that rotation tends to be unstable due to the half-whirl phenomenon. In addition, since the disc-shaped thrust bearing member is disposed at the upper end or the lower end of the bearing, when the spindle motor starts and stops, the rotor falls down with respect to the stator, so that contact sliding tends to occur between the bearing components and the product life. May be shortened.

[0009]

SUMMARY OF THE INVENTION An object of the present invention is to provide a liquid dynamic pressure bearing having a simple structure, a small size, and easy manufacture, which eliminates rotational instability caused by a half-whirl phenomenon. Another object of the present invention is to provide a spindle motor in which a rotor is supported on a stator by a liquid dynamic pressure bearing in which contact sliding between bearing members is reduced, and a rotating device using the spindle motor as a drive source.

[0010]

According to another aspect of the present invention, there is provided a spindle motor including a rotor including a rotor magnet, a stator including a stator coil, and a liquid dynamic bearing for supporting the rotor on the stator. A cylindrical bearing member with a flange having a disk-shaped thrust bearing member at a central portion in the axial direction of the dynamic pressure bearing and a cylindrical portion for a radial bearing and a cylindrical portion for support on both sides thereof, and a radial of the cylindrical bearing member with a flange. A stepped cylindrical bearing member having a small-diameter cylindrical portion into which a bearing cylindrical portion is rotatably inserted on a closed end side, and a large-diameter cylindrical portion into which the disc-shaped thrust bearing member is rotatably inserted on an open end side. If, respectively the open end of the stepped cylindrical bearing member between an annular thrust pressing member and and their components for sealing is subjected to capillary seal The was composed of the lubricating oil filled in the gaps.

Further, in the spindle motor provided with the liquid dynamic pressure bearing configured as described above, or in a rotating body device driven by the spindle motor, the magnetic center of the stator coil is set in the axial cross section of the disc-shaped thrust bearing member. The rotor magnet and the stator coil were arranged so as to substantially coincide with the center. Further, the radial dynamic pressure bearing portion of the liquid dynamic pressure bearing is constituted by an outer peripheral surface of a radial bearing cylindrical portion of the flanged cylindrical bearing member and an inner peripheral surface of a small diameter cylindrical portion of the stepped cylindrical bearing member, The first thrust dynamic pressure bearing portion is constituted by one surface of the disk-shaped thrust bearing member and the opposite surface of the annular thrust holding member, and the second thrust dynamic pressure bearing portion is the other of the disk-shaped thrust bearing member. And a boundary surface between the small-diameter cylindrical portion and the large-diameter cylindrical portion of the stepped cylindrical bearing member. Further, the capillary seal is constituted by an oil reservoir having a cross-sectional shape that expands toward the outside air from a portion communicating with the bearing gap of the first thrust dynamic pressure bearing portion.

[0012]

1 to 4 are views for explaining a rotary shaft type spindle motor according to an embodiment of the present invention. FIG. 1 is a sectional view of the rotary shaft type spindle motor, and FIG. It is the expanded sectional view which exaggerated and showed the bearing gap etc. in the principal part. In these drawings, reference numeral 10 denotes a fixing member that constitutes a part of the stator of the motor, 20 denotes a flanged cylindrical bearing member in which a disk-shaped thrust bearing member 21 is integrally formed at an axial center portion, and 30 denotes a fixing base 10. The stepped cylindrical bearing member 40 formed integrally with the cylindrical member 40 is an annular thrust holding member. Numeral 50 denotes a cup-shaped hub constituting a part of the rotor, which is fixed to the flanged cylindrical bearing member 20 by a mounting hole provided at the center thereof. Reference numeral 60 denotes a rotor magnet which also forms a part of the rotor, and is disposed on the inner peripheral surface of the cup-shaped hub 50. Reference numeral 70 denotes a stator coil, which is a component of the stator, and is arranged on the outer peripheral surface of the stepped cylindrical bearing member 30 close to the rotor magnet 60.

A disk-shaped thrust bearing member 2 is provided at a central portion in the axial direction.
The cylindrical bearing member 20 with a flange 1 is formed as shown in FIG.
As shown in the enlarged view, a cylindrical portion 22 for a radial bearing is formed below the disk-shaped thrust bearing member 21, and a cylindrical portion 23 for support is formed above the thrust bearing member 21. Stepped cylindrical bearing member 3
4, a small-diameter cylindrical portion 31 into which the radial bearing cylindrical portion 22 of the flanged cylindrical bearing member 20 is rotatably inserted and a disk-shaped thrust bearing member 21 are rotatably inserted as shown in FIG. It is a member having at least two cylindrical portions of the large-diameter cylindrical portion 32. These two cylindrical portions are coaxially adjacent to each other, and a boundary surface 35 exists at the boundary. A cylindrical part 33 formed coaxially adjacent to the large diameter cylindrical part 32
Seals the open end of the large-diameter cylindrical portion 32 and thus the open end of the stepped cylindrical bearing member 30 by applying a capillary seal.
This is for inserting and fixing the annular thrust holding member 40. Such a stepped cylindrical bearing member 30 is manufactured by forming a thrust holding member cylindrical portion 33, a large-diameter cylindrical portion 32, and a small-diameter cylindrical portion 31 in order from the top by cutting or the like. the cylindrical portion 31 and so that the large-diameter cylindrical portion 32 is formed on the open end side. S is an oil reservoir forming a capillary seal.

The liquid dynamic pressure bearing shown in FIGS.
It comprises two radial dynamic pressure bearings, an upper or first thrust dynamic pressure bearing and a lower or second thrust dynamic pressure bearing. The radial dynamic pressure bearing part is a cylindrical bearing member 2 with a flange.
8, the outer peripheral surface of the radial bearing cylindrical portion 22 and the inner peripheral surface of the small diameter cylindrical portion 31 of the stepped cylindrical bearing member 30. One of these outer peripheral surface and inner peripheral surface is shown in FIG. A radial dynamic pressure generating groove G1 as shown is formed, and the other is a flat surface. The upper thrust dynamic pressure bearing portion includes the upper surface of the disk-shaped thrust bearing member 21 and the annular thrust holding member 4.
A thrust dynamic pressure generation groove G2 as shown in FIG. 9 is formed on one of the upper and lower surfaces, and the other is a flat surface. Further, the second thrust dynamic pressure bearing portion is constituted by a lower surface of the disc-shaped thrust bearing member 21 and a boundary surface 35 between the small-diameter cylindrical portion 31 and the large-diameter cylindrical portion 32 of the stepped cylindrical bearing member 30. A thrust dynamic pressure generating groove G2 as shown in FIG. 9 is formed on one of the boundary surfaces 35, and the other is a flat surface.

In FIG. 2, R1 is a narrow gap formed between the upper surface of the disk-shaped thrust bearing member 21 and the lower surface of the disk-shaped thrust holding member 40, including the bearing clearance of the first thrust dynamic pressure bearing portion. R2 is a disk-shaped thrust bearing member 21
Is a narrow gap formed between the outer peripheral surface of the cylindrical member and the inner peripheral surface of the large-diameter cylindrical portion 32 of the stepped cylindrical bearing member 30. R3 is the lower surface of the disc-shaped thrust bearing member 21 and the stepped cylindrical bearing member 3
A narrow gap formed between the small-diameter cylindrical portion 31 and the boundary surface 35 of the large-diameter cylindrical portion 32, including the bearing gap of the second thrust dynamic pressure bearing portion. R4 is a cylindrical bearing member 20 with a flange.
Is a narrow gap formed between the outer peripheral surface of the radial bearing cylindrical portion 22 and the inner peripheral surface of the small diameter cylindrical portion 31 of the stepped cylindrical bearing member 30, and includes the bearing clearance of the radial dynamic pressure bearing portion. Further, R5 is formed between the lower end surface of the radial bearing cylindrical portion 22, ie, the lower end surface of the flanged cylindrical bearing member 20, and the closed end surface of the small-diameter cylindrical portion 31, ie, the closed end surface of the stepped cylindrical bearing member 30. It is a narrow gap. These gaps are 4 to 2
An appropriate value in the range of about 0 microns is selected at the time of design.
These narrow gaps R1 to R5 are filled with lubricating oil by a vacuum injection method or a dropping method.

The oil sump S is a cylindrical bearing member 2 with a flange.
0 supporting cylindrical portion 23 and annular thrust holding member 40
It is composed of That is, the cross-section of the inner diameter hole of the annular thrust holding member 40 is formed into a truncated conical shape by cutting, and the supporting cylindrical portion 23 is inserted into the inner diameter hole to form a circle.
As shown in FIG. 2, an oil reservoir S having a divergent cross section as shown in FIG. 2, that is, an oil reservoir S which expands divergently from a narrow end to an enlarged end is easily formed by the annular thrust holding member 40 and the cylindrical bearing member 20 with a flange. Is done. The narrow end of the oil reservoir S is an open end, and communicates with the narrow gap R1 including the bearing gap of the first thrust dynamic pressure bearing. The enlarged end of the oil reservoir S is open to the atmosphere. When the spindle motor is stopped, the lubricating oil fills the narrow end of the divergent oil reservoir S by capillary action, and the surface tension of the lubricating oil in this portion and the lubricating oil are The lubricating oil is prevented from leaking out of the open end of the bearing due to the negative pressure applied to the lubricating oil inside the bearing when the lubricating oil moves in the direction of the enlarged end of the bearing. Therefore, the enlarged end opening to the atmosphere and the first
The oil reservoir S having a narrow end communicating with the narrow gap R1 including the bearing gap of the thrust dynamic pressure bearing portion functions as a so-called capillary seal. The oil reservoir S is formed so as to expand from the narrow end toward the atmosphere because the lubricating oil expands due to a large increase in the ambient temperature and pressure, and the oil reservoir S expands from the narrow end to the enlarged end. In order to prevent leakage outside the bearings.

A spindle motor used in a rotating body device using a magnetic disk or an optical disk as a rotating body or a rotating body device using a polygon mirror as a rotating body as shown in FIG.
Usually, it is a direct drive DC brushless motor. Rotor magnets 70 arranged at equal intervals on the inner peripheral surface of cup-shaped hub 50 and stator coils 7 mounted on the outer peripheral surface of stepped cylindrical bearing member 30 in close proximity thereto
Numeral 0 is a component of the electromagnetic circuit of the DC brushless motor. The stator coil 70 is an electromagnet to which an exciting current is added from a DC power supply via an electronic rectifier circuit and whose polarity changes periodically. In other words, the direction of the magnetic field generated by the stator coil 70 changes periodically. The rotational force of the motor is generated by the electromagnetic attractive force and the repulsive force between the magnetic field of the stator coil 70 whose direction changes periodically and the magnetic field of the rotor magnet 60 whose direction is constant.

In the present invention, the magnetic center of the stator,
Specifically, the rotor magnet 60 and the stator coil 70 are arranged such that the center of the magnetic circuit of the stator coil 70 substantially coincides with the center of the axial cross section of the disc-shaped thrust bearing member 21. The center of the disk-shaped thrust bearing member 21 in the axial cross section is formed at the axial center of the cylindrical bearing member 20 with a flange, and is located substantially at the center of the liquid dynamic bearing. For this reason, by setting the magnetic center of the stator to substantially coincide with the center of the axial cross section of the disk-shaped thrust bearing member 21 as described above, the magnetic path formed by the stator coil 70 is formed above and below the bearing in a well-balanced manner. Since the resistance is reduced, the magnetic field generating the rotational force can be used more effectively than in the conventional device. Further, since the member generating the rotational force by the electromagnetic action is located substantially at the center of the liquid dynamic pressure bearing by the above arrangement, the instability of rotation caused by the half-whirl phenomenon can be remarkably reduced.

FIG. 5 shows another embodiment of the present invention. In the rotary shaft type spindle motor having a liquid dynamic pressure shown in FIG.
Oil is excessively drawn from the outer diameter portion to the inner diameter portion of the dynamic pressure generating groove of the thrust dynamic pressure bearing portion during high-speed rotation into the disk-shaped thrust bearing member 21 formed at the axial center of the flanged cylindrical bearing member 20. In this case, two balance holes H are provided axially symmetrically so as not to be disturbed. In FIG. 5, the closed end of the stepped cylindrical bearing member 30 is formed using a seal member. That is, the stepped cylindrical bearing member 30
As shown in FIG. 6, the thrust holding member cylindrical portion 3
3. A large-diameter cylindrical portion 32, a small-diameter cylindrical portion 31, and a sealing member cylindrical portion 34 which is an opening are formed in order from the top by cutting or the like, and a disc-shaped sealing member 38 is liquid-tight to the opening cylindrical portion 34. The lower end of the small-diameter cylindrical portion 31 which is fixed and thus the lower end of the stepped cylindrical bearing member 30 is a closed end. As shown in FIG. 5, sheet - to form a closed end to the stepped cylindrical bearing member 30 with the seal member has the advantage of expanding and ease of processing, the choices in the injection method of the lubricating oil.

FIG. 7 shows still another embodiment of the present invention, which is a fixed shaft type spindle motor provided with a liquid dynamic pressure bearing. FIG.
1 are basically the same as those of the rotary shaft type spindle motor shown in FIG. However, there are some differences due to the fixed shaft type. That is, the flanged cylindrical bearing member 20
The supporting cylindrical portion 23 is inserted and fixed in a mounting hole of the fixed base 10, and a cup-shaped hub 50 is coaxially fixed to the stepped cylindrical bearing member 30. A cylindrical portion for mounting a stator coil is formed on the fixed base 10, and a stator coil 70 is mounted on an outer peripheral surface of the cylindrical portion. Stepped cylindrical bearing member 30
Is a member having an open end and a closed end. Capillary seal comprises cross-section of the annular thrust retainer member 40 is a divergent oil reservoir S formed between the supporting cylindrical portion 23 of the frustoconical inner diameter hole and the flanged cylindrical bearing member 20, Ya ambient temperature Lubricating oil is prevented from leaking out of the bearing even when the pressure rises significantly.

In the fixed shaft type spindle motor shown in FIG. 7 as well, the radial dynamic pressure bearing portion includes the outer peripheral surface of the radial bearing cylindrical portion 22 of the flanged cylindrical bearing member 20 and the small diameter cylindrical portion of the stepped cylindrical bearing member 30. the inner peripheral surface and is composed of, and RDG G1 as shown in FIG. 8 is formed on one or Re not have the inner peripheral surface thereof an outer peripheral surface of the other is a flat surface. The first thrust dynamic pressure bearing portion includes a lower surface of the disk-shaped thrust bearing member 21 and the annular thrust holding member 4.
A thrust dynamic pressure generating groove G2 as shown in FIG. 9 is formed on one of the lower surface and the upper surface, and the other is a flat surface. Further, the second thrust dynamic pressure bearing portion is constituted by a lower surface of the disc-shaped thrust bearing member 21 and a boundary surface between the small-diameter cylindrical portion and the large-diameter cylindrical portion of the stepped cylindrical bearing member 30. Either one has a thrust dynamic pressure generating groove G as shown in FIG.
2 are formed, and the other is a flat surface. Further, the rotor magnet 60 and the stator coil 70 are arranged such that the magnetic center of the stator, specifically, the center of the magnetic circuit of the stator coil 70 substantially coincides with the center of the axial cross section of the disc-shaped thrust bearing member 21. .

[0022]

According to the present invention, there is provided a cylindrical bearing member having a unique shape of a flanged cylindrical bearing member in which a disk-shaped thrust bearing member is integrally formed at a central portion in the axial direction, and the flanged cylindrical bearing member is rotated. A spindle motor provided with a liquid dynamic pressure bearing having a stepped cylindrical bearing member that can be freely accommodated as a main component, and a rotating body device using the spindle motor as a drive source of a rotating body. By providing a liquid dynamic pressure bearing whose main component is a columnar bearing member with a flange of this unique shape, the magnetic center of the stator coil is aligned substantially with the center of the axial cross section of the disk-shaped thrust bearing member. The rotor magnet and the stator coil can be arranged, and the spindle motor and the rotating body device using the same as the driving source can reduce the rotational instability caused by the half-whirl phenomenon. Moreover, since the magnetic flux of the magnetic circuit is effectively used by the arrangement of the constituent members,
It has also become possible to reduce the weight of the stator coil and core or to reduce the exciting current.

Further, the capillary seal is formed by tapering the inner diameter hole of the annular thrust holding member,
This and the supporting cylindrical portion of the cylindrical bearing member with a flange can easily constitute a divergent oil reservoir, and in this case, there is no influence on the formation of the dynamic pressure generating groove of either the thrust bearing portion or the radial bearing portion. Therefore, there is a great advantage that the dynamic pressure is not reduced. Further, since the disk-shaped thrust bearing member is located at the axial center of the cylindrical bearing member, the rotor is less likely to fall with respect to the stator when the spindle motor starts and stops, so that contact abrasion hardly occurs between the components of the bearing. There is no danger of shortening the product life.

A cylindrical bearing member having a unique shape such as a flanged cylindrical bearing member in which a disk-shaped thrust bearing member is integrally formed at an axial center portion, and a stepped housing for rotatably accommodating the flanged cylindrical bearing member. By using the cylindrical bearing member as a main component of the liquid dynamic pressure bearing, the capillary seal can be easily configured. Further, since the cylindrical bearing member is not provided with an oil reservoir, the liquid dynamic pressure according to the present invention can be improved. The bearing has a simple structure, can be miniaturized, and is easily processed.

[Brief description of the drawings]

FIG. 1 is a sectional view of an embodiment of a spindle motor provided with a liquid dynamic bearing according to the present invention.

FIG. 2 is a partially enlarged view of the spindle motor of FIG. 1 in which a bearing clearance is exaggerated.

FIG. 3 is an enlarged cross-sectional view of a flanged cylindrical bearing member constituting a dynamic pressure bearing provided in the spindle motor of FIG. 1;

FIG. 4 is an enlarged sectional view of a stepped cylindrical bearing member constituting a dynamic pressure bearing provided in the spindle motor of FIG. 1;

FIG. 5 is a sectional view of another embodiment of the spindle motor provided with the liquid dynamic pressure bearing of the present invention.

FIG. 6 is an enlarged sectional view of a stepped cylindrical bearing member constituting a dynamic pressure bearing provided in the spindle motor of FIG. 5;

FIG. 7 is a sectional view of still another embodiment of the spindle motor provided with the liquid dynamic pressure bearing of the present invention.

FIG. 8 is a diagram illustrating an example of a radial dynamic pressure generation groove.

FIG. 9 is a diagram illustrating an example of a thrust dynamic pressure generation groove.

FIG. 10 is a perspective view showing an example of a rotator device using a spindle motor as a drive source of the rotator.

FIG. 11 is an enlarged sectional view of a main part of an example of a spindle motor having a conventional liquid dynamic pressure bearing.

FIG. 12 is a sectional view of another example of a spindle motor provided with a conventional liquid dynamic pressure bearing.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 10 Fixed base 20 Flanged cylindrical bearing member 21 Disc-shaped thrust bearing member 22 Radial bearing cylindrical part 23 Supporting cylindrical part 30 Stepped cylindrical bearing member 31 Small diameter cylindrical part 32 Large diameter cylindrical part 33 Cylindrical part for thrust holding member 34 Sealing member cylindrical portion 35 Boundary surface between small-diameter cylindrical portion and large-diameter cylindrical portion 38 Sealing member 40 Annular thrust holding member 50 Cup-shaped hub 60 Rotor magnet 70 Stator coil S Oil reservoir (oil reservoir for capillary seal) R1 First Narrow gap including the bearing gap of the thrust bearing portion R2 Gap R3 Narrow gap including the bearing gap of the second thrust bearing portion R4 Narrow gap including the bearing gap of the radial bearing portion R5 Gap G1 Radial dynamic pressure generating groove G2 Thrust dynamic pressure generating groove SM Spindle motor LD Rotating body H Pressure balance hole

Claims (6)

(57) [Claims] 1. A spindle motor comprising: a rotor including a rotor magnet; a stator including a stator coil; and a liquid dynamic bearing for supporting the rotor on the stator. a cylindrical bearing member with flanges each having a cylindrical portion for the radial bearing of the bearing member and on opposite sides of the supporting cylindrical portion, open
A stepped cylindrical bearing member having an end and a closed end, wherein a small-diameter cylindrical portion into which a radial bearing cylindrical portion of the flanged cylindrical bearing member is rotatably inserted is on the closed end side and the disc-shaped thrust bearing member. A stepped cylindrical bearing member having a large-diameter cylindrical portion at an open end side rotatably inserted therein, and an annular thrust holding member for sealing the open end of the stepped cylindrical bearing member by applying a capillary seal thereto And a lubricating oil filled in gaps formed between these components. 2. A spindle motor comprising: a rotor including a rotor magnet; a stator including a stator coil; and a liquid dynamic bearing for supporting the rotor on the stator. a cylindrical bearing member with flanges each having a cylindrical portion for the radial bearing of the bearing member and on opposite sides of the supporting cylindrical portion, open
A stepped cylindrical bearing member having an end and a closed end, wherein a small-diameter cylindrical portion into which a radial bearing cylindrical portion of the flanged cylindrical bearing member is rotatably inserted is on the closed end side and the disc-shaped thrust bearing member. A stepped cylindrical bearing member having a large-diameter cylindrical portion at an open end side rotatably inserted therein, and an annular thrust holding member for sealing the open end of the stepped cylindrical bearing member by applying a capillary seal thereto And the lubricating oil filled in the gaps formed between these constituent members, and such that the magnetic center of the stator substantially coincides with the center of the axial cross section of the disc-shaped thrust bearing member. A spindle motor in which a rotor magnet and a stator coil are arranged. 3. The radial dynamic pressure bearing portion of the liquid dynamic pressure bearing includes an outer peripheral surface of a radial bearing cylindrical portion of the flanged cylindrical bearing member and an inner peripheral surface of a small diameter cylindrical portion of the stepped cylindrical bearing member. Wherein the first thrust dynamic pressure bearing portion is constituted by one surface of the disc-shaped thrust bearing member and the opposed surface of the annular thrust holding member, and the second thrust dynamic pressure bearing portion is constituted by the disc-shaped thrust bearing. 3. The spindle motor according to claim 1, wherein the spindle motor comprises the other surface of the bearing member and a boundary surface between the small-diameter cylindrical portion and the large-diameter cylindrical portion of the stepped cylindrical bearing member. 4. The oil reservoir according to claim 1, wherein the capillary seal is an oil reservoir having a cross-sectional shape that widens toward the outside air from a portion communicating with the bearing gap of the first thrust dynamic pressure bearing portion. Spindle motor. 5. The closed end of the stepped cylindrical bearing member is formed by an opening formed at an end of the small-diameter cylindrical portion and a sealing member for sealing the opening in a liquid-tight manner. The spindle motor according to claim 1. 6. A rotating body device using the spindle motor according to claim 1 or 2 as a driving source of the rotating body.