KR100213914B1 - Revolution device of polygon mirror - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a polygon mirror rotating device, comprising a bearing unit mounted on an outer surface of a polygon mirror rotating device to which a fluid bearing is applied and maintaining a uniform distance between a rotating body and a stationary body in the fluid bearing. A shaft, a rotation member which is installed to surround the bearing member of the shaft and is rotated about the shaft, and a polygun mirror seated on a support protrusion formed on an outer surface of the rotation member and simultaneously rotated with the rotation member. It is a useful invention to provide a rotating device for the polygon mirror to make a stable and accurate horizontal rotation, and further contribute to the reliability of the product.

Description

Rotator of Polygon Mirror

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a polygon mirror rotating apparatus mounted on a laser printer or scanner, and more particularly, to a polygon mirror rotating apparatus for improving a structure in which a polygon mirror is rotated so that the polygon mirror can perform more accurate rotation.

In general, a polygon mirror is mounted on a sleeve inside a scanning motor installed in a scanner or a laser printer, and rotates at the same time as the rotor is rotated to reflect the laser beam radiated from a predetermined position, thereby directing the beam toward the printing drum side. It is intended to be deflected.

Referring to the rotating device for rotating the conventional polygon mirror as described above are as follows.

Here, the embodiment will be described by applying the hemisphere bearing to the scanning motor.

1 is a cross-sectional view of a scanning motor to which a conventional polygon mirror rotating device is applied.

The motor 1 has a shaft 11 vertically installed on the housing 10, and is provided with a stator 12 at a predetermined distance around the housing 10, and mutually electromagnetic action with the stator 12 is upward. A yoke 20 having a rotor 21 provided on the inner side thereof and a polygon mirror rotating means 30 fitted to the shaft 11 to satisfy the condition in which the yoke 20 and the polygon mirror 40 are rotated. It consists of.

As the polygon mirror rotating means 30, the polygon mirror 40, the sleeve 31 is fitted loosely from the upper side, and the shaft 11 is fitted to the lower portion of the sleeve 31 It is composed of a bearing 32 rotated about the center, and a plate-shaped elastic member 50 for bringing the polygon mirror 40 into close contact with the sleeve 31.

In this case, a known fluid bearing called a hemispherical bearing is used as the bearing, and the hemispherical bearing 32 includes a bush 32a having a hemispherical groove 32b formed inside and below the cylindrical body; Each groove 32b of the bush 32a has a shape corresponding to that of the bearing member 32c provided in the groove 32b and the bearing member 32c such that the bearing members 32c maintain a predetermined interval. It is comprised by the space holder 32d mounted between them.

A through hole 32e for inserting the shaft 11 is formed in the center of the bearing member 32c and the gap holder 32d.

The hemispherical bearing configured as described above forms a bearing groove in the groove 32b surface of the bush 32a or the outer surface of the bearing member 32c so that the bearing member 32c or the bush 32a enclosing the bearing 32c rotates when the bearing is rotated. By generating air pressure between the groove and the surface opposite thereto, the surface of the groove 32b and the bearing member 32c are spaced a predetermined distance to rotate smoothly.

In the polygon mirror rotating means 30 as described above, when the sleeve 31 and the bush 32a to which the polygon mirror 40 is installed are coupled to each other, the sleeve 31 is heated to apply a heat to the sleeve 31. ) And lowering the temperature of the sleeve 31 to be press-fitted, wherein the following phenomenon occurs between the bush 32a and the bearing member 32c.

When pressing the bush 32a by lowering the temperature of the sleeve 31 to which heat is applied, the groove 32b formed in the inner surface of the bush 32a is changed in diameter due to the forcible compressive force of the sleeve 31. Accordingly, the hemispherical curvature of the groove 32b also changes.

Therefore, the conventional polygon mirror rotating apparatus has the following problems due to the change in curvature of the hemisphere.

As shown in FIG. 2, when the bush having the changed hemispherical surface is rotated on the bearing member, the bush is rotated while maintaining the correct distance L on the surface of the undeformed groove, but deformed when passing through the surface of the deformed groove. The bush is inclined to one side so that the gap L 'is maintained by the exact distance L.

Such lengthening of the bush is generated by the deformed portion in the groove so that the sleeve and the polygon mirror coupled to the bush have non-uniform rotation.

If the polygon mirror is unevenly rotated, the above-described laser beam cannot be reflected at the correct angle on the polygon mirror, and for this reason, a scanner or a laser printer equipped with the scanning motor has a fatal flaw in terms of product reliability. .

Accordingly, the present invention has been made to solve the above problems, the object of the polygon mirror rotating device to provide a rotation means that the groove of the bush is not deformed to make the polygon mirror more accurate rotation. .

Features of the present invention for achieving the above object are as follows.

According to an aspect of the present invention, there is provided a polygon mirror rotating device to which a fluid bearing is applied and maintains a uniform distance between a rotating body and a fixed body in the fluid bearing, comprising: a shaft including a bearing portion mounted on an outer surface thereof; Rotating member is wrapped around the bearing member of the shaft and is rotated about the shaft; And a polygon mirror mounted on a support protrusion formed on an outer surface of the rotating member and simultaneously rotating with the rotating member.

A bearing member included in the shaft, the bearing member being pressed into the shaft and facing up and down; And it characterized in that it comprises a spacing retainer mounted between the opposed bearing member.

The rotating member includes a cylinder having a groove corresponding to the bearing member therein; And a coupling surface for extrapolating the polygon mirror to a predetermined position on the outer surface of the cylinder, and includes a support protrusion supporting a bottom of the polygon mirror by protruding a predetermined length over the lower circumference of the coupling surface.

1 is a cross-sectional view of a scanning motor to which a conventional polygon mirror rotating device is applied.

Figure 2 is a cross-sectional view showing a deformation of the bearing portion in the polygon mirror rotating apparatus.

Figure 3 is a cross-sectional view of the scanning motor to which the present invention polygon mirror rotating device is applied.

4 is a perspective view showing a rotating member of the present invention.

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

* Explanation of symbols for main parts of the drawings

1: motor 10: housing

60, 90: rotating member 61: cylinder

62: groove 63: bearing member

65: engaging surface 66: support protrusion

Referring to the configuration of an embodiment of the present invention having the characteristics as described above are as follows.

In this embodiment, the hemispherical bearing is applied to the scanning motor.

3 is a cross-sectional view of the scanning motor to which the polygon mirror rotating device is applied, and FIG. 4 is a perspective view of the rotating member.

The scanning motor 1 has a housing 10 in which a shaft 11 is installed vertically, and the stator 12 is mounted at a predetermined distance around the stator 12, and the stator 12 is disposed above the stator 12. A motor unit 80 composed of a yoke 20 having a rotor 21 that is rotated by electromagnetic action, and installed on the shaft 11 to transmit the rotational force of the yoke 20 to the polygon mirror 40. It consists of a rotating means (70).

In the configuration of the motor unit 80, the lower end of the outer circumferential surface of the yoke 20 is bent so that the upper side is opened, the storage chamber 22 is formed so that the heavy material for balancing adjustment is mounted.

Rotating means (70) is a bearing unit (100) consisting of a polygon mirror (40), a bearing member (63) fitted to face the shaft (11) and held at regular intervals by a spacing holder (64), and the bearing. It is installed to surround the outer surface of the part 100, the rotating member 60 to allow the poly-mirror 40 is fitted to the outer surface, and to fix the poly-mirror 40 to the rotating member 60 It is configured to include an elastic member (50).

The elastic member 50 is preferably made of a leaf spring, one end is to be supported by the rotating member 60, the other end is supported on the upper surface of the polygon mirror 40.

The rotating member 60 has grooves 62 corresponding to the bearing member 63 at upper and lower portions, respectively, and passes through the grooves 62 to the outer diameter and length of the gap holder 64. Of the cylinder body 61 having a spaced maintenance hole 67 corresponding thereto, an engaging surface 65 such that the polygon mirror 40 is coupled to a predetermined position on the outer circumferential surface of the cylinder 61, and the engaging surface 65 It is formed to protrude over the rotation direction of the cylinder 61 at the lower end, and includes the support protrusion 66 which made the upper surface support the bottom face of the polygon mirror 40. As shown in FIG.

The support protrusion 66 is preferably formed integrally with the cylinder (61).

A support groove 61a for supporting the elastic member 50 is formed above the coupling surface 65 of the cylinder 61.

The support protrusion 66 is provided with a storage chamber 66a in which a heavy material for balancing is formed by forming a groove having a predetermined depth on an upper surface thereof.

Hereinafter, the operation of the present invention having an embodiment of the above configuration will be described.

When an external electrical signal is applied to the stator 12, the yoke 20 having the rotor 21 rotated according to the stator 12 and the electromagnetic action is rotated accordingly, by the yoke 20 is rotated The rotating member 60 coupled to the yoke 20 and the polygon mirror 40 installed on the rotating member 60 are rotated.

At this time, the bearing member 63 coupled to the groove 62 in the rotating member 60 acts with the groove 62 to generate air pressure, thereby the cylinder 61 of the rotating member 60. Is rotated without contact with the bearing member 63, the rotation member 60 is coupled to the polygon mirror 40 to the outside of the cylinder 61 to the problem caused by the above-described conventional press-fit process of the sleeve and bush. The coupling surface 65 and the support protrusion 66 are integrally formed so as to be eliminated.

Means to eliminate the fluid to act as a fluid bearing during the rotation of the cylinder (61) to function as a conventional bush, the coupling surface 65 and the support protrusion 66 meets the condition that the polygon mirror 40 is coupled to This is to prevent the change of the gap between the bearing member 63 and the groove 62 into which the bearing member 63 is inserted during assembly of the rotating means 60.

The elastic member 50 squeezes the polygon mirror 40 loosely coupled to the coupling surface 65 of the barrel (61).

In the chamfering chamber (66a, 22) formed in the support protrusion 66 and the yoke 20 is a built-in weight for balancing adjustment, the balancing adjustment occurs during the processing of the support protrusion 66 and the yoke 20 It is to make stable rotation in response to error.

In addition, the present invention can be applied to the bearing member is a conical in addition to the hemisphere bearing described in the above embodiment, the bearing groove is formed in the shaft is formed in the shaft, the bush, or the shaft is rotated Applicable to journal fluid bearings, this will be described in detail with reference to FIG. 5.

5 is a cross-sectional view showing only the changed part of another embodiment of the present invention.

In another embodiment, the motor 1 has a bearing groove 91 formed on a shaft 11 fixed on the housing 10 to form a bearing portion 110, and a rotating member 90 on the shaft 11. ) Is inserted into the bearing groove (not shown) for generating a thrust pressure on the bottom surface of the cylinder 61 of the rotating member 90 or the surface of the housing 10 opposite to the bottom surface of the cylinder 61 of the rotating member 90. All of them are identical except for the configuration in which the "

The shaft mounting hole 92 is formed inside the rotating member 90 so that a predetermined distance from the outer surface of the shaft 11 is maintained when the shaft 11 is installed with the shaft 11. It provides a space where a predetermined air pressure is generated when the member 90 is rotated.

In addition, even when the shaft 11 or the rotating member 90 is rotated, even a bearing groove of the bottom surface of the rotating member 90 or the surface of the housing 10 facing the bottom surface of the rotating member 90 Air pressure is generated to perform the bearing action.

The other embodiments described above produce the same actions and effects as the embodiments of the present invention.

As described above, the present invention is a useful invention that improves the structure of the polygon mirror rotating device of the scanning motor so that the polygon mirror can perform stable and accurate horizontal rotation, and further, improve the reliability of the above-described product in the problem.

Claims (8)

In the polygon mirror rotating device is applied to the fluid bearing, and the fluid bearing to maintain a uniform distance between the rotating body and the fixed body, the shaft comprising a bearing portion mounted on the outer surface and the bearing member of the shaft is installed to surround the shaft And a polygun mirror mounted on a support member formed on an outer surface of the rotary member and rotated at the same time as the center. The apparatus of claim 1, wherein the bearing part included in the shaft includes a bearing member which is pressed into the shaft and is opposed to the upper and lower parts, and a gap retaining hole which is mounted between the opposed bearing members. . The apparatus of claim 1, wherein the bearing part included in the shaft comprises a plurality of bearing grooves formed on an outer surface of the shaft. According to any one of claims 1 to 3, wherein the rotating member is formed with a cylinder including a groove corresponding to the bearing member therein and a coupling surface for extrapolating the polygon mirror at a predetermined position on the outer surface of the cylinder, Polygon mirror rotating apparatus characterized in that it comprises a support protrusion for supporting a bottom of the poly gun mirror is formed to protrude a predetermined length over the lower side of the coupling surface. The apparatus of claim 4, wherein a support groove is formed on an upper side of the coupling surface of the rotating member, and an elastic member is mounted to support both ends of the support groove and the upper surface of the poly gun mirror. [5] The apparatus of claim 4, wherein the support protrusion comprises a storage compartment formed with a groove having a predetermined depth on which the weight is mounted so as to adjust the rotation balance on the upper surface. The apparatus of claim 2, wherein the bearing member is formed in a hemispherical shape. 3. The polygon mirror rotating apparatus according to claim 2, wherein the bearing member is formed in a conical shape.

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