KR100207791B1 - Laser scanning unit - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a laser scanning unit for correcting an eccentricity of a rotating body rotating at a high speed. According to the present invention, a polygon mirror having a regular polygon shape for deflecting and scanning a laser beam onto an image plane, and the polygon mirror are integrated with the polygon mirror. A laser scanning unit comprising a rotating body rotating at a low speed and a rotating body supporting member for rotating the rotating body with a minimum frictional force, wherein the rotating body has a ring-shaped balancing to correct an amount of eccentricity generated at the rotating body. And a balancer formed inside the balancing portion.

Description

Laser scanning unit

The present invention relates to a laser scanning unit, and more particularly, to a ring-shaped balancing that includes a liquid balancer and a solid balancer in a predetermined eccentric weight generated due to density imbalance and shape asymmetry of a rotating body which is rotated at a very high speed by a scanning motor. The present invention relates to a laser scanning unit in which the unit is formed.

As is well known, in recent years high speed rotating rotors, for example, spindle motors for ultra-high precision rotation of discs of hard disk drivers, disks and polygon mirrors driven by drives such as laser scanning units of laser printers Mass having the predetermined mass at the position where the eccentricity of the rotating body is corrected (usually symmetrical with the eccentric generating portion) in order to prevent the deterioration of rotational performance due to the partial density difference and the eccentric weight caused by the asymmetry of the shape. Balancing device is introduced to compensate for the eccentricity caused by attaching.

A balancing device applied to a scanning motor of such a conventional laser scanning unit will be described with reference to FIG. 1 as an example.

The laser scanning unit includes a polygon mirror 10 having a regular polygonal shape that deflects the laser beam at large, and an eccentric correction weight 100 attached to a predetermined position of the polygon mirror 10 to prevent rotational eccentricity of the polygon mirror 10. And hemispheres 30, 35 and hemispheres 30 and 35 having a fixed shaft 20, which is the rotation center of the polygon mirror 10, and a hemispherical surface with a high sphericity pressed into the fixed shaft 20. And a bushing 40 for supporting the radial load and the thrust load, the motors 50 and 55 serving as driving devices, the hub 60, the upper housing 75 and the lower housing 70, and the like.

The lower housing 70 is press-fitted and fixed to the fixed shaft 20 to which the hemispheres 30 and 35 are fixed, and the polygon mirror 10, the motor stator 50, and the motor rotor () on the outer circumferential surface of the bushing 40. 55) is installed.

The bushing 40 supports the weight of the polygon mirror 10 and the bushing 40, the radial load and the thrust load of the motor stator 50 and the motor rotor 55, and the bushing 40 has a predetermined diameter. The through-hole is formed in the center of the cylinder with a diameter larger than the fixed shaft 20 in the center of the cylinder, the both ends of the rod is the same as the curvature of the hemispheres 30, 35 that are pre-machined (30a, 30b) Is formed.

The through-hole of the bushing 40 has a cylindrical spacer having a dimension precisely processed to form a predetermined gap between the hemispheres 30 and 35 and the hemisphere grooves 30a and 30b and to adjust the gap gap formed therein. 40a is inserted.

The aforementioned polygon mirror 10 has a regular polygon shape circumscribed to a circle having a predetermined diameter, and at a predetermined position of the polygon mirror 10 due to the shape asymmetry of the polygon mirror 10 and the fine material density imbalance of the polygon mirror 10. In order to correct the amount of eccentricity generated in the polygon mirror, the eccentricity correction weight body 100 having a predetermined mass is attached to the eccentric portion in a symmetrical manner with respect to the amount of eccentricity.

Looking at the action of the balancing device applied to the scanning motor of the laser scanning unit configured as described above, first, when power is applied to the stator 50 and the rotor 55, the rotor 55 starts to rotate in a stopped state (ω = 0). It rotates at a predetermined revolutions per minute (4000 to 18000 rpm), wherein the polygon mirror 10 is also rotated at the same rotational speed as the rotor 55 by a laser diode (not shown) or a surface emitting laser diode (not shown). The generated laser beam is deflected by the polygon mirror 10 to an imaging surface (photosensitive drum; not shown).

On the other hand, the polygon mirror 10 and the other components are precisely processed so that eccentricity does not occur with respect to the center of rotation, even if the components are precisely processed so as to be symmetrical with respect to each other, the material density unevenness and the center of rotation of each component Asymmetrical processing and attachment position asymmetry causes a few mg of eccentricity below the critical rotational speed (where the critical rotational speed is the minimum rotational speed per minute at which the eccentricity correction effect of the rotating body that minimizes the eccentricity occurs).

At this time, the attachment position of the eccentric correction weight 100 and the mass of the mass should be attached corresponding to the eccentric position of the polygon mirror 10, but it is very difficult to accurately determine the eccentric position of the eccentric correction weight 100 is mainly Attached by experience, there is a problem that the accuracy is very low and takes a lot of time.

The present invention has been made in view of such a conventional problem, and an object of the present invention is generated by several mg even below the critical rotational speed by an ultraviolet curing agent which is chemically reacted and cured by ultraviolet rays and an eccentric correction steel ball having a predetermined mass. The present invention provides a laser scanning unit having a balancing unit for correcting vibration and vibration caused by an eccentric amount of a polygon mirror.

1 is a cross-sectional view showing a conventional laser scanning unit and a balancing device applied to the laser scanning unit.

Figure 2 is a cross-sectional view showing in one embodiment a balancing device according to the invention applied to a laser scanning unit.

Figure 3 is a cross-sectional view showing another embodiment of the present invention.

Figure 4 is a cross-sectional view showing another embodiment of the present invention.

Figure 5 is a cross-sectional view showing another embodiment of the present invention.

* Description of the symbols for the main parts of the drawings *

10: polygon mirror 20: fixed shaft

30,35: Hemisphere 40: Bushing

320: UV curing agent

Such a laser scanning unit for achieving the object of the present invention includes a polygon mirror of a polygonal shape for scanning by deflecting the laser beam to the image plane; and

A rotating body which rotates integrally with the polygon mirror; and

A laser scanning unit comprising a rotor support member for rotating the rotor with a minimum friction force;

The rotating body may include a ring-shaped balancing unit and a balancer formed inside the balancing unit to correct an amount of eccentricity generated in the rotating body.

Hereinafter, a scanning motor of a laser scanning unit in which a balancing device according to the present invention is installed will be described with reference to FIG. 2 as an example. Other parts of the laser scanning unit except for the scanning motor have a conventional structure and function. Since the same description thereof will be omitted, and will be described in detail with respect to the scanning motor which is a key part of the present invention.

The scanning motor includes a polygon mirror 10 that reflects the laser beam to a photosensitive drum (largely), a rotating body 40, 60, and a rotating body 40 which are integrally rotated with the polygon mirror 10. , 60 includes a rotor support member for rotating with minimal frictional force.

The polygon mirror 10 has a through hole having a predetermined diameter, and the through hole of the polygon mirror 10 has a hub 60 which is a polygon mirror first support member which is a rotating body which rotates integrally with the polygon mirror 10. Is combined, the hub 60 is a shape in which two cylinders 60a and 60b having two different diameters are bonded to each other, and the polygon mirror is formed in the first cylinder 60a having the smaller diameter among the two cylinders. The through-hole of 10 is formed in the diameter, and the groove | channel 60c of predetermined diameter and predetermined depth is dug | drilled in the 2nd cylinder 60b which has a large diameter on the other side.

It is formed in a portion where the small diameter cylinder 60a and the large diameter cylinder 60b meet after being inserted into the cylindrical 60a having a small diameter on one side of the hub 60 in the through hole of the polygon mirror 10 as described above. It is placed in the jaw portion which is present, and then completely adhered by the leaf spring 77 or the like.

The hub 60, which is the polygon mirror first support member, is coupled to the bushing 40, which is the polygon mirror second support member that is integrally rotated with the hub 60, and the bushing 40 has a cylindrical shape having a predetermined height. Therefore, the diameter is slightly larger than that of the groove 60c of the hub 60, and has a diameter that is forcibly fitted to the groove 60c.

In addition, the rotor support means is a hemispherical groove 30a, 30b having a through hole having a predetermined diameter penetrating both ends of the bushing 40 and a predetermined curvature formed at both ends of the bushing 40 in which the through hole is formed. Hemispheres (30) and (35) formed of hemispheres (30) and (35) which are forcibly fitted to the shaft inserted into the through hole to be in contact with the bush bearing and the hemisphere grooves (30a) and (30b). And a bush bearing, which is a hemispherical groove 30a, 30b formed at both ends of the shaft and the bushing 40 in which the hemispheres 30 and 35 are interfitted, form a bearing to form the rotating body 40 ( Rotate 60) with minimal friction.

Meanwhile, when the hemispheres 30 and 35 are coupled to the hemisphere grooves 30a and 30b of the bushing 40 in close contact with each other, the fluid is connected between the bushing 40 and the hemispheres 30 and 35. Since the gap for forming the pressure is not formed and the function of the fluid bearing is lost, for this reason, an appropriate gap is required between the bushing 40 and the hemispheres 30 and 35, so that the bushing 40 The through hole is fitted with a ring-shaped spacer 40a having a precise height, a predetermined inner diameter, and an outer diameter so that the hemispheres 30, 35 and the hemisphere grooves 30a, 30b of the bushing 40 maintain a predetermined gap. It is supposed to be.

The rotor 55 is formed on the outer circumferential surface of the bushing 40 formed as described above, and the stator 50 is provided at a predetermined position of the lower housing 70 at a spaced apart distance from the motor rotor 50.

In addition, on the outer circumferential surface of the hub 60 on which the polygon mirror 10, which has already been mentioned, is formed, a balancing material forms a predetermined space portion in the shape of a donut, and its longitudinal section forms a square, triangle, or hemispherical shape. The part 200 is formed, and the liquid balancer 210 which is a liquid is filled in the internal space of the balancing part 200 with about 30% to about 60% of the volume of the space.

Herein, the liquid balance 210 is water or oil having a predetermined weight, and such water or oil filled in the balancing part may be rotated by the motors 50 and 55 of the polygon mirror driving apparatus to be rotated at a predetermined threshold speed ( Here, the critical speed is the minimum number of revolutions per minute at which the eccentricity correction effect of the rotating body that minimizes the eccentricity generated in the polygon mirror is generated.) When the eccentricity is generated and the rotation of the polygon mirror 10 is unstable, the critical speed is reduced. When the polygon mirror 10 is rotated as described above, the water or oil of the balancing part 200 causes an eccentric portion (the cause of the eccentricity is caused by the asymmetry of the shape and the imbalance of density), that is, the eccentric portion of the The liquid balancer 210 moves to a portion where the eccentric weight is corrected according to the eccentric weight, and performs stable rotation while correcting the eccentricity.

3 is a view showing another embodiment according to the present invention, the jaw portion 65 is formed in the hub 60, which is the first support member of the polygon mirror driving apparatus, so that the polygon mirror 10 is seated. The diameter of the jaw portion 65 is larger than the diameter of the polygon mirror 10. This means that the vertical projection area of the jaw portion 65 is larger than the vertical projection area of the polygon mirror 10.

In addition, when the ultraviolet rays are irradiated in the vertical direction from the top of the polygon mirror 10, the jaw portion 65 is divided into a portion where the ultraviolet rays are not reached by the polygon mirror 10 and a portion exposed to the ultraviolet rays.

A predetermined ultraviolet curing liquid (e.g., Japanese Three-bond: ultraviolet curing liquid; a liquid when exposed to ultraviolet rays) is a liquid inside a groove having a predetermined width and a predetermined depth in the jaw portion 65 of the portion exposed to ultraviolet rays of the two portions. The material causing the phase change to a solid phase in the 320; filling about 30% to 60%, and attaching a cover 310 of a transparent material so that ultraviolet rays are irradiated on the upper surface of the groove to reduce the amount of eccentricity generated in the polygon mirror 10 The balancing unit 300 to be corrected is formed.

The balancing unit 300 configured as described above first irradiates the ultraviolet curing liquid 320 with ultraviolet rays in a state in which the eccentricity is corrected by the ultraviolet curing liquid 320 which is a liquid state capable of rotating at a high speed more than a critical rotation speed. The ultraviolet curing liquid 320 is fixed to the balancing part 300.

Of course, the eccentricity does not occur even below the critical rotational speed by the solid state ultraviolet curing liquid 300 fixed in such a state, and the polygon mirror makes stable rotation.

4 is a view showing another embodiment according to the present invention, a ring-shaped groove having a predetermined width and a predetermined depth is formed at a predetermined position on the outer circumferential surface of the bushing 40 that is the second polygon support member. Is again sealed by a cover 410 of a transparent material, the groove and the space formed by the cover 410 is a balancing unit 400.

The balance part 400 is injected with a liquid, for example, water, oils having a predetermined specific gravity, and liquid balancers causing a phase change from a liquid state to a solid state when exposed to ultraviolet rays, and a liquid liquid in the balancing part 400. Since the balancer 420 is difficult to inject, the liquid balancer injection hole 430 having a predetermined diameter is formed to penetrate the groove wall and the bushing 40.

Of course, the solid balancer in the solid state, for example, steel balls, solid materials, etc. are put before attaching the cover 410 to the groove.

Even when the bushing 40 is rotated at a high speed in the state configured as described above, the same operation and effect as in the above embodiment can be obtained.

2 to 4, a few mg of eccentricity generated in the polygon mirror 10 by being formed in the hub 60 as the polygon mirror first support member or the hub 60 as the polygon mirror second support member. In order to correct the weight, the balance part has a liquid balancer or a solid balancer introduced, but preferably, as shown in FIG. 5, when the UV-curing liquid 510, which is a liquid balancer, and the steel ball 520, which is a solid balancer, are put together, the balance is improved. The effect can be obtained.

As described in detail above, a balancing part having a predetermined cross-sectional area is formed on the rotating part of the laser scanning unit, and a liquid balancer and a solid balancer are formed on the balancing part to sufficiently compensate for the eccentric weight generated in the laser scanning unit, thereby improving the rotating performance of the scanning unit. It is effective to improve.

Claims (12)

A polygon mirror having a regular polygon shape for scanning the laser beam by deflecting the image plane; and A rotating body which rotates integrally with the polygon mirror; and A laser scanning unit comprising a rotor support member for rotating the rotor with a minimum friction force; And the rotating body includes a ring-shaped balancing part and a balancer formed inside the balancing part to correct an amount of eccentricity generated in the rotating body. According to claim 1, The rotating body is a polygon mirror first support member having one side end protruding to a predetermined height through the hollow portion formed in the polygon mirror is fixed, the groove having a predetermined diameter on the other end; Wow And a polygon mirror second support member whose one end is forcibly fitted into the groove of the polygon mirror first support member. 2. The laser scanning unit of claim 1, wherein the rotating body supporting member is a bearing portion for reducing friction generated when the rotating body rotates in association with the polygon mirror second supporting member. The method of claim 3, wherein the bearing portion has a hemisphere having the same curvature as the curvature of the hemisphere grooves formed on both ends of the second polygon support member; An axis having a predetermined diameter that is interfitted with a second polygon support member interposed therebetween in a state in which the hemispheres of the hemispheres face each other; And a bush bearing having a hemispherical groove shape having a predetermined curvature in contact with the hemisphere. The laser scanning unit of claim 1, wherein a balance portion is formed in the polygon mirror. The laser scanning unit of claim 2, wherein the polygon mirror first support member is provided with a balancing portion. 3. The laser scanning unit of claim 2, wherein a balance portion is formed in the polygon mirror second support member. The laser scanning unit of claim 1, wherein the balancer is a steel ball. The laser scanning unit of claim 1, wherein the balancer is a liquid. The laser scanning unit of claim 1, wherein the balancing part includes both liquid and steel balls. 11. The laser scanning unit of claim 9 or 10, wherein the liquid causes a phase change from liquid to solid by a predetermined stimulus. 12. The laser scanning unit of claim 11, wherein the liquid is an ultraviolet curing agent solidified by ultraviolet rays.

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