JPS63191117A - Dynamic pressure bearing unit for rotary polygon mirror - Google Patents

Abstract

PURPOSE:To reduce the price of the titled unit and to thin the unit by providing the unit with a fixed body obtained by molding a stator york and a driving coil unitedly with resin having a cylindrical face concentrical with the outer periphery of the stator york and a rotary body consisting of a magnet having an inner peripheral face to be rotated around the cylindrical face, a rotor york and a rotary polygon mirror. CONSTITUTION:The driving coil 13 is wound around the stator york 14 to form a stator coil unit 15 and the unit 15 is unitedly molded with resin to form the fixed body 16. The rotary body 17 is inserted so as to be rotated around the 1st cylindrical part 16c of the fixed body 16 and constituted of the rotary polygon mirror 18, the rotor york 19 fixed on the inner peripheral face 18a of the polygon mirror 18 and the magnet 20. Since the inner peripheral face of the magnet is used as a dynamic pressure bearing unit without forming a specific rotary shaft, the bearing constitution can be simplified and its cost can be reduced. Since the dynamic pressure bearing, the driving coil, the magnet, etc., can be constituted in the rotary polygon mirror, the size and thickness of the unit can be reduced.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of the Invention This invention relates to a dynamic pressure bearing unit for a motor for driving a rotating polygon mirror used for optical deflection in a laser beam printer or the like.

BACKGROUND OF THE INVENTION Hydrodynamic bearings generally have very good characteristics in terms of rotation accuracy, noise, vibration, life, etc., and are therefore used in a variety of applications including audiovisual motors.

In particular, this dynamic pressure bearing is considered to be optimal for the optical deflection rotating polygon mirror drive motor of a laser beam printer, which requires high-speed rotation and high-precision rotation.

An example of the above-mentioned conventional rotating polygon dynamic pressure bearing unit will be described below with reference to the drawings.

FIG. 6 shows a conventional rotating polygon mirror dynamic pressure bearing unit.

In FIG. 6, 1 is a shaft, the lower end of which is fixed to the case 2, and the upper end of the shaft 1 is a free end.

Herringbone grooves 3a and 3b are formed near both upper and lower ends of the outer peripheral surface of the shaft 1, and the tips of the arrows are formed in a shape that points in the direction of rotation of the rotating body 4.

A hollow cylindrical cylinder 5 is rotatably fitted onto the shaft 1. A rotor magnet 6, a rotating polygon mirror 7, and an inner magnetic cylinder 10a of a thrust supporting magnetic bearing 8 are attached to this cylinder 5 as described later.

That is, the rotor magnet 6 is fixed such that the inner peripheral edge of the upper end of the opening is in contact with the lower surface side of the flange 5a that projects slightly upward from the vertical center of the cylinder 5, and the rotor magnet 6 is fixed to the case 2.
Rotational force is obtained between the drive coil 12 wound around the stator yoke 11 fixed to the stator yoke 11 .

Further, the rotating polygon mirror 7 is fitted so that the lower edge of the opening of the rotating polygon mirror 7 is in contact with the upper surface side of the flange 5a, and the rotating polygon mirror 7 is inserted through the rotating polygon mirror holding body 8 and the elastic seal 9. The pressing is fixed.

Further, the inner magnetic cylinder 10a is fitted into the small diameter portion of the lower end of the cylinder 5. On the case 2 side, an outer magnetic cylinder 10b surrounds the inner magnetic cylinder 10a.
f) < is provided to support the rotating body 4 in the thrust direction.

The operation of the rotating polygon mirror bearing unit configured as described above will be described below.

First, by energizing the drive coil 12, a rotational driving force is generated between the drive coil 12 and the rotor magnet 6, thereby driving the rotating body 4 clockwise. When this rotating body 4 rotates, dynamic pressure in the radial direction is generated in the gap between the shaft 1 and the cylinder 5 due to the action of the herringbone grooves 3a and 3b, forming an air dynamic pressure bearing. On the other hand, the thrust direction is determined by the magnetic bearing 8 for thrust support.

The rotating body 4 having the rotating polygon mirror 7 can be supported in a non-contact manner with respect to the shaft 1, thereby achieving stable high-speed rotation.

Problems to be Solved by the Invention However, in the above configuration, the rotating polygon mirror 7,
The cylinder 5 is constructed separately from the cylinder 5, and it is necessary to provide a thrust support magnetic bearing 8 in the axial direction of the cylinder for thrust direction support. 8. Since the elastic seal 9 or the protruding flange portion 5a of the cylinder 5 is provided, it is disadvantageous in terms of cost (man-hours, material cost) and thinning in the axial direction.

(2) When attaching the rotating polygon mirror 7 to the cylinder 5, force is applied to the rotating polygon mirror 7, so the reflecting mirror surfaces 7a to 7e
This impairs the high precision (flatness, surface wobbling, etc.) of

(3) The inclination of the reflecting mirror surfaces 7a to 7f of the rotating polygon mirror 7 with respect to the axis 1 shown in FIG. Therefore, it is difficult to obtain a highly accurate tilt of the reflecting mirror surface with respect to the axis.

There was a problem.

In view of the above problems, the present invention provides a rotating polygon dynamic pressure bearing unit that reduces costs (materials, man-hours), can be made thinner, and has a structure that eliminates deflection of the reflecting mirror surface of the rotating polygon mirror with respect to the axis. This is what we provide.

Means for Solving the Problems In order to solve the above problems, the rotating polygon mirror dynamic pressure unit of the present invention includes a stator yoke and a drive coil that are integrally molded from a resin having a concentric cylindrical body portion at the outer peripheral end of the stator yoke. a rotary body including a cylindrical magnet, a rotor yoke, and a rotating polygon mirror, which is fitted on the outer periphery of the fixed body with reference to the cylindrical body surface, and has an inner circumferential surface that is rotationally driven; A dynamic pressure bearing is configured between the outer circumferential surface of the cylindrical body and the inner circumferential surface of the magnet.

Effects of the present invention With the above-described configuration, the stator yoke and the drive coil are integrally molded into a cylindrical body part made of resin, and the inner peripheral surface of the magnet is used as a hydrodynamic bearing unit, without the need for a special rotating shaft. By high-precision machining of the rotating polygonal mirror surface based on the inner circumferential surface, the bearing configuration becomes extremely simple and the unit cost (man-hours, direct materials) can be significantly reduced. Further, since a dynamic pressure bearing, a drive coil, a magnet, etc. can be configured within the rotating polygon mirror, it can be made smaller and thinner. Further, since there is no need to attach the rotating polygon mirror to other parts and no force is applied to the rotating polygon mirror, the high precision state of the reflecting mirror surface is not impaired.

Furthermore, by processing the reflecting mirror surface of the rotating polygon mirror with high precision based on the inner peripheral surface of the magnet or at the same time as the inner peripheral surface of the magnet, the inclination of the reflecting mirror surface of the rotating polygon mirror with respect to the rotation reference axis of the rotating body can be kept to only the processing accuracy. Can be done.

EXAMPLE Hereinafter, a rotating polygon dynamic pressure bearing unit according to an example of the present invention will be described with reference to the drawings.

FIG. 1 shows a cross section of a rotating polygon dynamic pressure bearing unit in an embodiment of the present invention.

In FIG. 1, a drive coil 13 is wound around a stator yoke 14 made of laminated silicon steel plates or soft ferrite to form a stator coil unit 15. The stator coil unit 15 is further integrally molded with resin to become a fixed body 16, and the fixed body 16 includes a flange 16a1, a mounting screw 16b1, a first cylindrical body portion 16cs extending perpendicularly from the flange 16a, and a first cylindrical body portion. A second cylindrical body portion 16e protrudes from the center of the distal end surface 16d of the second cylindrical body portion 16c.
have.

Reference numeral 17 denotes a rotary body, which is fitted so as to rotate with reference to the first cylindrical body portion 16c of the fixed body 16.
It consists of a rotor yoke 19 fixed to the inner circumferential surface 18a of the rotating polygon mirror 18, and a magnet 20. In addition, in the gap between the first cylindrical body portion 16c and the magnet inner peripheral surface 20a,
The lubricant 21 is included, but depending on the conditions, it may not be included.

Note that the tip surface 16 of the second cylindrical body portion 16e of the fixed body 16
In other words, a spiral groove 16g as shown in FIG. 3 is usually formed in the portion of the rotor yoke 19 that comes into contact with and separates from the closed end top surface 19a, or a spiral groove 16g as shown in FIG. If a force in the thrust direction can be generated between the surfaces 20a, the spiral groove 16g may not be provided.

Further, the distal end surface 1 of the second cylindrical body portion 16e of the fixed body 16
A lubricant 22 is provided in the gap between the rotor yoke 6f and the closed end top surface 19a of the rotor yoke 19, but it may not be necessary depending on the conditions.

In FIG. 1, both the first cylindrical body part 16C1 and the magnet inner peripheral surface 20a of the fixed body 16 are straight, but normally the first cylindrical body part 16c is straight as shown in FIG. Herringbone grooves 23a and 23b are provided,
The inner peripheral surface 20a of the magnet may be straight, or as shown in FIG. 5, the inner peripheral surface 20a of the magnet may have a herringbone groove 24a.

24b is provided, and the first cylindrical body portion 16c is used in a straight state.

Although this embodiment shows the configuration as a rotating polygon mirror driving device, by fixing a disk hub unit or a turntable unit to the rotating polygon mirror 18, it can also be used as a spindle device for hard disks, optical disks, etc. Needless to say, it can be used.

The operation of the rotating polygon dynamic pressure bearing unit constructed as described above will be explained below with reference to FIG. 1, FIG. 3, and FIG. 4. In Figures 1, 3, and 4,
First, by energizing the driving coil 13, a rotational driving force is generated between the driving coil 13 and the magnet 20, and the rotating body 17 is driven clockwise.

When this rotating body 17 rotates, the herringbone groove 23a
, 23b generates hydraulic pressure in the radial direction, and hydraulic pressure in the axial direction occurs due to the function of the spiral groove 16g on the tip surface 16f of the cylindrical body portion of the pen 2, thereby forming a hydrodynamic bearing. Stable high-speed rotation is performed using the cylindrical body portion 16 of No. 1 as a reference.

Here, if the rotating body 17 is a non-cuttable magnet, the rotating polygon mirror 18 is processed with high precision based on the inner peripheral surface 20a of the magnet, or if it is a cuttable magnet, the rotating polygon mirror 1
8 and the inner circumferential surface 20a of the magnet are simultaneously machined with high precision, so that the stable, high-precision, high-speed rotation due to the dynamic pressure bearing remains unchanged, while the reflecting mirror surfaces 18a to 18 of the rotating polygon mirror 18
f can be directly communicated. That is, the reflective mirror surfaces 18a to 18f can be stably moved with respect to the rotation reference axis.

Effects of the Invention As described above, the present invention includes a fixed body in which the stator yoke and the drive coil are integrally molded of resin with a cylindrical surface concentric with the outer peripheral surface of the stator yoke, and an inner peripheral surface that rotates with respect to the cylindrical surface. By creating a rotating structure in which a rotating body consisting of a magnet, a rotor yoke, and a rotating polygon mirror is rotated, (a) the number of dynamic pressure bearing components is small (the unit cost (man-hours and direct materials) can be significantly reduced);

(b) There is no need to attach the rotating polygon mirror to other parts (because no force is applied to the rotating polygon mirror, the high precision state of the reflecting mirror surface is not impaired.

(c) Since a dynamic pressure bearing, a drive coil, a magnet, etc. can be configured within the rotating polygon mirror, it can be made smaller and thinner.

(d) The reflecting mirror surface of the rotating polygon mirror can be machined with high precision either with reference to the inner peripheral surface of the magnet or at the same time as the inner peripheral surface of the magnet. It can only be suppressed.

You can obtain effects such as

[Brief explanation of the drawing]

Fig. 1 is a sectional view of a rotating polygon dynamic pressure bearing unit in an embodiment of the present invention, Fig. 2 is a plan view of the rotating body as seen from the rotating body side of Fig. 1, and Fig. 3 is a unit used in the present invention. A plan view of the cylindrical body integrally molded with resin shown in Fig. 1, viewed from the tip side;
Fig. 4 is an individual view of the fixed body in the second embodiment, Fig. 5 is a sectional view of the magnet in the third embodiment, and Fig. 6 is a sectional view of the rotating polygon dynamic pressure bearing unit in the conventional embodiment. FIG. 7 is a plan view of the rotating polygon mirror shown in FIG. 6. 13... Drive coil, 14... Stator yoke, 15... Stator coil unit,
16...Fixed body, 16c...First cylindrical body part, 16d...Distal end surface of the first cylindrical body part,
16e... Second cylindrical body part, 16f...
- Tip surface of second cylindrical body part, 16g...Spiral groove, 19...Rotor yoke, 19a...
... Closed end top surface of rotor yoke, 20 ... Magnet, 20a ... Inner peripheral surface of magnet, 21.
22...Lubricant, 23a, 23b...
herringbone groove. Name of agent: Patent attorney Toshio Nakao and 1 other person +3---
M moving coil 16d --- 1st s
Yen xa, 1isi14---Stata Toku
16e-9-2nd degree circular section detail 15--No. tacoil unit 16F--f
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Claims (6)

[Claims] (1) A stator coil unit consisting of a stator yoke and a drive coil is integrally molded with resin, and a fixed body having a first cylindrical body portion concentric with the outer circumferential surface of the stator yoke on its outer circumferential surface, a rotating polygon mirror, and A rotating body consisting of a rotor yoke and a cylindrical magnet fixed to the inner circumferential surface of a rotating polygon mirror, the rotating body being attached to the outer circumference of the fixed body, and the inner circumferential surface of the magnet being attached to the first side of the fixed body. It is rotatably fitted so as to face the cylindrical body part with a predetermined gap, and the first
A rotating polygon mirror dynamic pressure bearing unit that constitutes a dynamic pressure bearing between the outer peripheral surface of the cylindrical body and the inner peripheral surface of the magnet. (2) The rotating polygon dynamic pressure bearing unit according to claim 1, wherein a herringbone groove is provided in the first cylindrical body portion of the fixed body that faces the inner peripheral surface of the magnet. (3) The rotating polygon dynamic pressure bearing unit according to claim 1, wherein a herringbone groove is provided on the inner peripheral surface of the magnet facing the first cylindrical body portion of the fixed body. (4) A second cylindrical body part is provided at the center of the front end face of the first cylindrical body part of the fixed body that comes into contact with and separates from the closed end top surface of the rotor yoke, and a spiral groove is provided in the front end face of the second cylindrical body part. The rotating polygon mirror dynamic pressure bearing unit according to item 1, 2, or 3. (5) A rotating polygon according to claim 1 or 2 or 3 or 4, wherein a lubricant is provided in a gap between the first cylindrical body portion of the fixed body and the inner peripheral surface of the magnet. Mirror dynamic pressure bearing unit. (6) The rotating polygon mirror dynamic pressure bearing unit according to claim 4, wherein a lubricant is provided in a gap between the tip end surface of the second cylindrical body portion of the fixed body and the closed end top surface of the rotor yoke.