JP2865766B2 - Polygon mirror motor - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a vertical motor, a method of manufacturing the vertical motor, and a bearing device suitable for the vertical motor, or a polygon driven by this type of motor. It relates to a mirror motor.

[Conventional technology]

Conventionally, Japanese Utility Model Publication No. Sho 63-1287 is known as a polygon mirror motor. FIG. 4 shows a bearing device of a ball bearing, in which a rotation detecting device is disposed at one free end of a shaft, a support member of a magnet is disposed at the other free end, and a polygon is disposed outside the same. A mirror is placed. Then, the drive coil is disposed outside the bearing device, and further forms an outer rotor type polygon mirror motor having a magnet on the outside thereof.

The purpose of this prior art is to prevent oil mist from the bearing part from scattering directly on the polygon mirror, and to block it with a magnet support member so that the bearing is not exposed directly below the polygon mirror. It is characterized by.

As the second polygon mirror motor, as shown in FIG. 5, there is known an example of a closed structure suitable for high-definition image processing. In a laser printer, a laser beam from a laser unit composed of a semiconductor laser, a gas laser, or the like is reflected by a rotating mirror b of a polygon rotor a and irradiated onto the back surface of the photoreceptor. It is configured to rotate over d via a sleeve e. Incidentally, as one similar to this configuration, one described in Japanese Patent Application Laid-Open No. 1-105015 is also known.

A large number of grooves for generating dynamic pressure are formed on the outer peripheral surface of the fixed shaft d, and the rotation of the rotary sleeve e generates a dynamic pressure for supporting a thrust load and a radial load. In other words, the groove for generating dynamic pressure is functionally capable of generating a dynamic pressure by the lower groove f _{1 having a} herringbone shape, the middle groove f ₂ forming the herringbone shape, and the upper groove f ₁ to generate a radial load. Support and middle groove f ₂
Air is sent to the upper surface of the fixed shaft d by
The thrust load is supported by increasing the air pressure between the bearing and the thrust bearing g at the upper end.

On top of the rotating sleeve e is polygonal rotor a screwed, also the rotor magnet C ₁ is fixed to the lower portion,
And with stator coils C ₂ for driving the rotor magnet C ₁ is in the fixed driving motor C so as to surround the periphery of the rotor magnet C _1, the laser irradiated from the outside to the mirror b of the polygon rotor a A laser incident window h for transmitting light and laser light reflected to a desired afterglow surface is formed on a part of the upper peripheral surface of the outer cylinder i, and is rotated at a high speed by the drive motor C. Not only does the polygon rotor need to maintain high rotation accuracy,
The gap between the fixed shaft and the rotary sleeve is made extremely narrow in order to reduce the deflection of the reflecting surface.

[Problem to be Solved by the Invention] The above-described conventional technology has the following problems.

Since the polygon mirror motor rotates at high speed, heat is generated on the sliding surface of the radial bearing. It is desirable that this heat be dissipated by the bearing and the bearing support member and not be conducted to the shaft (rotating shaft).

When heat is transmitted to the shaft and the shaft thermally expands, the stress of the fitting portion with the polygon mirror increases, and the reflection surface of the polygon mirror is disadvantageously distorted. The present invention aims to solve the above problems.

[Means for solving the problem]

The present invention relates to a stator having a drive coil and a bearing support member, a rotor rotatably supported by a radial bearing of the bearing support member with a rotating shaft, and a motor magnet provided on a base forming the rotor. And a polygon mirror motor having a polygon mirror supported by a base, wherein the bearing support member includes a bottom substrate portion, and a bearing support cylinder portion that rises up in the center of the bottom substrate portion, and the rotation shaft Also made of aluminum that easily conducts heat, and if a radial bearing is placed inside the bearing support cylinder, it will be filled with magnetic fluid, and the magnet above the bearing support cylinder will rise to the outside of the radial bearing and flow out to the outside A magnetic fluid seal for suppressing fluid, wherein the base is formed integrally with a disc-shaped mounting portion and a lower surface of the mounting portion; A cylindrical support cylinder portion, which is placed in a non-contact state, a boss portion protruding in the center of the plate-shaped mounting portion, and the rotation shaft being inserted and fitted at the center, and an outer periphery of the plate-shaped mounting portion And an annular support ring formed so as to rise up to the side, formed of aluminum, which is more easily transmitted to the heat than the rotating shaft, and fitted with a motor magnet on the outer periphery of the support cylinder, and the polygon mirror includes:
A fitting hole provided in the center is fitted to the outer periphery of the boss portion, and a lower end surface is abutted on the support ring to be placed on the board-shaped placing portion.

〔Example〕

Hereinafter, a polygon mirror motor according to an embodiment of the present invention will be described with reference to the drawings. A laser beam from a laser device is incident on the polygon mirror. The incident beam is scanned by a rotating polygon mirror, and a desired image is formed on a light receiving drum of the electrophotographic photosensitive member.

FIG. 1 shows an embodiment of a polygon mirror motor in which an iron core 1 is used.
Is provided with a drive coil 2 and attached to a housing 3. This is the drive coil unit. Further, a position detection sensor 23 and a rotation number detection coil pattern 24 are arranged.

The stator including the drive coil unit has a bearing support member. The bearing support member includes a bottom substrate portion 7 and a bearing support tube portion 7A that rises in the center of the bottom substrate portion 7. Radial bearings 4 and 5 and a thrust bearing 6 are arranged and supported inside the bearing support cylinder 7A. The thrust bearing 6 is supported by a bottom cover 8 fixed to the bottom substrate 7 with screws.

A dynamic pressure seal 10 is provided via a space 9 secured above the radial bearing 4 placed above the bearing support cylinder 7A. A magnetic fluid seal 18 is provided above the dynamic pressure seal 10.

The inside of the bearing support cylinder 7A is filled with a magnetic fluid 11, and a dynamic pressure seal 10 and a magnetic fluid seal 18 are provided so that the magnetic fluid 11 does not leak.

Next, the rotor 16 includes a rotation detecting magnet 12, a motor magnet 13, a polygon mirror 14, and a rotating shaft 15, and has a rotating shaft 15 rotatably supported by the radial bearings 4, 5, and the rotor 16 is mounted on the stator side. It is rotatably supported by

The polygon mirror 14 is used to prevent contamination and reduce noise.
A fully closed cover 17 is attached. The cover 17 is provided with a transparent window 17A.

As can be inferred from FIG. 1, the present polygon mirror motor is roughly divided into a drive coil unit, a seal-integrated magnetic fluid bearing unit, and a rotor with a polygon mirror. Therefore, after assembling the seal-integrated magnetic fluid bearing unit to the drive coil unit, the shaft 15 of the rotor is
The polygon mirror motor can be assembled simply by inserting it into the opening end of the bearing unit and screwing the cover 17 for dust and sound insulation, and the assemblability is very good.

The magnetic fluid 11 is obtained by mixing and stirring a fine ferromagnetic powder of 0.1 μm or less in size and shape which does not precipitate in the liquid, in a low-viscosity metal lubricating oil in order to reduce loss due to viscosity. Used.

Therefore, like ball bearing grease,
Because it is a liquid lubricant instead of a highly viscous lubricant, the load torque of the bearing does not change abruptly with the rotation of the shaft. There is no direct contact, and the shaft is supported by the bearing via the oil film, so it does not wear the bearing and shaft at ON-OFF, increase the clearance, increase the rotational vibration and uneven rotation, Rotation can be continued smoothly.

The radial bearings 4 and 5 and the thrust bearing 6 are made of a copper-based metal bearing, and the bearing support members 7 and 8 are made of, for example, aluminum, and easily radiate heat generated in a bearing portion having a clearance of about 1 μm to 6 μm to the outside air. In addition, deterioration of the magnetic fluid 11 due to chemical change is suppressed, and the life is extended.

The space 9 has a structure of the polygon mirror motor,
Since it is impossible to inject the magnetic fluid 11 after assembly,
In view of the volume error of the bearings 4, 5, 6 and the processing error of the bearing support members 7, 8, the volume error of the magnetic fluid bearing due to the crossing of the outer diameter of the shaft, the volume increase of the fluid due to thermal expansion, and the injection error of the fluid, Even if the magnetic fluid 11 is injected beforehand and the rotating shaft 15 is inserted after that, the magnetic fluid 11 does not overflow and consequently does not stain the polygon mirror.

The magnetic fluid seal 18 is integrated with the dynamic pressure seal 10 and is set on the bearing support cylinder 7A outside the space 9.

As shown in FIG. 2, the bearing support cylinder 7A and the dynamic pressure seal 10
The space between them is sealed with an adhesive or the like to prevent leakage due to the permeation of the magnetic fluid, thereby preventing the polygon mirror 14 from being stained.

The polygon mirror 14 is attached to the rotor 16 as follows.

The base as a main part of the rotor 16 is a disk-shaped mounting portion, and is integrally formed on the lower surface of the mounting portion, and the bearing support tube portion 7A is in a non-contact state. A cylindrical support cylinder portion to be placed, a boss portion 16A that protrudes in the center of the plate-shaped mounting portion, and into which the rotating shaft 15 is inserted and fitted, and rises to the outer peripheral side of the plate-shaped mounting portion. And a support ring formed as described above, and is formed of aluminum, which is more easily transmitted to the heat than the rotary shaft 15 formed of stainless steel. The motor magnet 13 is fitted around the outer periphery of the support cylinder.

The polygon mirror 14 is mounted on the board-shaped mounting portion of the base. The polygon mirror 14 is mounted on the board-shaped mounting portion by fitting the outer periphery of the boss portion 16A into a fitting hole provided in the center of the polygon mirror 14 and making the lower end surface abut the support ring 16B. Is done.

The fitting between the fitting hole of the polygon mirror 14 and the boss 16A is performed by warm fitting.

The polygon mirror 14 is mounted on the board-shaped mounting portion such that the lower end surface near the outer periphery comes into contact with the support ring 16B. If the entire lower surface of the polygon mirror 14 abuts on the plate-shaped mounting portion without depending on the abutment of the support ring 16B, a partial contact by the support ring 16B may occur due to poor sitting, vibration, etc. It is intended to be in contact.

Due to the support structure, the upper surface of the polygon mirror 14 may be thermally deformed in a convex shape by the heat generated from the bearing device.

That is, the heat generated by the bearing device is
The light is transmitted to the polygon mirror 14 via 6A. Polygon mirror
The heat transmitted to 14 is radiated from support ring 16B.
For this reason, the polygon mirror 14 has a temperature difference between the upper surface side and the lower surface side, the upper surface is thermally deformed in a convex shape, and the reflection surface is distorted.

In order to prevent this thermal deformation, the bearing support cylinder 7A was formed of aluminum. Aluminum has higher thermal conductivity than stainless steel. The heat generated in the radial bearings 4 and 5 and the thrust bearing 6 is transmitted to the rotating shaft 15 made of stainless steel, but the heat is easily transmitted to the bearing support cylinder 7A.
Is transmitted to more. Therefore, the heat transmitted to the polygon mirror 14 via the rotating shaft 15 and the boss 16A is reduced, and the above-described thermal deformation is less likely to occur, so that the distortion of the reflecting surface is eliminated.

〔The invention's effect〕

As described above, the stator having the drive coil and the bearing support member, the rotor rotatably supported by the radial bearing of the bearing support member with the rotating shaft, and the base forming the rotor are provided. In a polygon mirror motor having a motor magnet and a polygon mirror supported on a base, the bearing support member includes a bottom substrate portion, a bearing support cylinder portion rising up at the center of the bottom substrate portion, and the rotation support member includes: Made of aluminum, which conducts heat more easily than the shaft, and when a radial bearing is placed inside the bearing support cylinder, it is filled with magnetic fluid, and further above the bearing support cylinder, it rises above the radial bearing and flows out to the outside A magnetic fluid seal for holding down the magnetic fluid to be formed, wherein the base is formed integrally with a disc-shaped disc-shaped mounting portion and a lower surface of the disc-shaped mounting portion, and the shaft is A cylindrical support tube portion supporting tube portion is placed in a non-contact state, and raised in the center of the plate-like mounting part,
And a boss portion into which the rotating shaft is inserted and fitted at the center, and an annular support ring formed so as to rise up on the outer peripheral side of the board-shaped mounting portion, and an aluminum to which heat is more easily transmitted than the rotating shaft. And a motor magnet is fitted around the outer periphery of the support cylinder. The polygon mirror fits a fitting hole provided at the center with the outer periphery of the boss, and a lower end surface of the polygon mirror is brought into contact with the support ring. The polygon mirror motor is characterized in that the polygon mirror motor is brought into contact with and mounted on the board-shaped mounting portion.

 According to this configuration, there are the following advantages.

(Effect) (1). The polygon mirror was fitted on the outer periphery of the boss with the fitting hole provided at the center, and the lower end surface was placed on the plate-shaped mounting portion with the lower end surface in contact with the support ring. The polygon mirror is better seated and less susceptible to vibration than one that abuts the entire end face.

(2). When the lower end surface of the polygon mirror abuts on the support ring, heat transfer tends to cause thermal deformation in a convex shape on the upper surface side, but the bearing support cylinder that supports the radial bearing is made of aluminum that conducts heat more easily than the rotating shaft. Since it is formed, the heat is well transmitted to the bearing support cylinder portion generated in the radial bearing, and the heat transmitted to the polygon mirror is reduced, so that no thermal deformation occurs.

(3). Since a magnetic fluid seal is provided above the bearing support cylinder to suppress the magnetic fluid flowing out to the outside of the radial bearing, there is no leakage of the magnetic fluid, and the polygon mirror is not contaminated with the magnetic fluid.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view showing a polygon mirror motor according to one embodiment of the present invention, FIG. 2 is a support structure diagram of a bearing and a seal of the present invention, FIG.
FIG. 4 is a longitudinal sectional view showing the prior art. 2 ... drive coil, 4 ... radial bearing, 5 ... radial bearing, 6A ... boss, 6B ... annular support ring, 7A ...
... Bearing support cylinder, 11 ... Magnetic fluid, 18 ... Magnetic fluid seal.

──────────────────────────────────────────────────続 き Continuation of the front page (72) Inventor Kazuhiko Kawaike 502 Kandachi-cho, Tsuchiura-shi, Ibaraki Machinery Research Laboratory, Hitachi, Ltd. (56) References JP-A-64-83920 (JP, A) JP-A-58- 79448 (JP, A) Fully open sho 55-106456 (JP, U) Fully open sho 62-125351 (JP, U) Fully open sho 62-51944 (JP, U) (58) Fields investigated (Int. ⁶ , DB name) H02K 29/00 H02K 5/00-5/26 G02B 26/10

Claims (1)

(57) [Claims] 1. A stator having a drive coil and a bearing support member, a rotor rotatably supported by a radial bearing of the bearing support member with a rotating shaft, and a motor provided on a base forming the rotor. In a polygon mirror motor having a magnet and a polygon mirror supported on a base, the bearing support member includes a bottom substrate portion, a bearing support cylinder portion rising in the center of the bottom substrate portion, and the rotating shaft. It is made of aluminum that conducts heat more easily, and if a radial bearing is arranged inside the bearing support cylinder, it fills in magnetic fluid, and further above the bearing support cylinder, it climbs above the radial bearing and flows out to the outside A magnetic fluid seal for holding down a magnetic fluid, wherein the base is formed integrally with a disc-shaped mounting portion, and a lower surface of the mounting portion, and A cylindrical support tubular portion on which the tubular portion is placed in a non-contact state, a boss protruding at the center of the board-shaped mounting portion, and the rotation shaft being inserted and fitted at the center, and the board-shaped mounting portion An annular support ring formed so as to rise up on the outer peripheral side of the polygon mirror, formed of aluminum which is more easily transmitted to the heat than the rotating shaft, and fitted with a motor magnet on the outer periphery of the support cylindrical portion; A polygonal mirror motor, wherein a fitting hole provided at the center is fitted to an outer periphery of the boss portion, and a lower end surface is abutted on the support ring to be mounted on the board-shaped mounting portion. .