KR100707275B1 - A laser scanning apparatus - Google Patents

Abstract

An injection device body; A light source installed in the main body to emit light; A rotating multi-face mirror rotatably installed in the main body to deflect the light emitted from the light source; A drive motor for rotating the rotating polyhedron; A cover member installed in the main body so as to cover the rotating polyhedron, the cover member having a slit through which light passes, formed in an up-down asymmetric shape, and formed with an inlet hole through which outside air flows; And a dust collecting member for filtering dust contained in air introduced into the cover member through the inlet hole.

Description

Optical scanning device {A laser scanning apparatus}

1 is a schematic perspective view of a light scanning apparatus according to an embodiment of the present invention.

2 is an exploded perspective view of the optical scanning device shown in FIG.

3 is a bottom perspective view of the cover member shown in FIG.

4 is a cross-sectional view of main parts of FIG. 1.

<Explanation of symbols for the main parts of the drawings>

10. main body of the scanning device 11. bottom

20. Light source 30. Rotating mirror

40. Driving motor 50. Circuit board

60. Cover element 61. Fastening rib

63. Slit 64, 65. First and second step

70. Dust collecting member

The present invention relates to an optical scanning device for deflecting incident light in a predetermined direction.

In general, an image forming apparatus such as a laser printer, a copier, a scanner, a multifunction printer, and the like are provided with an optical scanning device.

The light source is irradiated with light from a light source, and the irradiated light is deflected and scanned in a predetermined direction by a reflecting surface of a rotating polygon mirror rotating at a high speed. Then, the deflected-scanned light is incident on a photosensitive medium such as a photosensitive drum through a predetermined optical system.

The rotating mirror is supported and rotated by a drive motor capable of high speed rotation. The drive motor is connected to a separate drive circuit board is controlled the rotation speed.

On the other hand, in recent years, the speed of the image forming apparatus has progressed, and the rotation speed of the rotating mirror is increased. As described above, when the rotating multifaceted mirror is rotated at a high speed, air containing internal dust forms around the rotating multifaceted mirror, that is, within the main body of the optical scanning device, to form a high speed airflow. Then, the dust or the like, which is lifted up by the airflow, may be attached to the surface of the rotating multi-face mirror, that is, the reflective surface, to contaminate the reflective surface. If the reflecting surface is contaminated, there is a problem that the light reflectance is lowered and the degree of light deflection is deteriorated.

In addition, dust piggybacked on the airflow generated by the high-speed rotation of the rotating multi-faceted mirror may contaminate other optical systems, that is, collimating lens, cylinder lens, f-theta lens, reflection mirror, and the like.

Conventionally, in order to solve the above problems, a structure has been developed to prevent contamination of the reflective surface by changing the air flow direction in the direction of rotation of the rotating multi-face mirror by forming a projection on the top or side of the rotating multi-face mirror. That is, in order to change the flow characteristics (direction, pressure, speed) of the air in the space corresponding to the reflecting surface of the rotating mirror, it is common to attach or form a separate structure to the rotating body to prevent contamination of the reflecting surface. It was.

By the way, even in the case of the above-described configuration, since the structure to change the air flow characteristics to the rotating body to be formed, there is a problem that the structure is complicated. In addition, by forming a separate structure on the rotating body, not only does not interfere with the high-speed rotation of the rotating body, there is a problem that it is not an alternative to the contamination of other optical components.

The present invention has been made in order to solve the above problems, an object of the present invention is to provide an improved optical structure to reduce the contamination caused by the air flow generated during the rotation of the rotating mirror.

Gwangju jangchi of the present invention for solving the above object, the injection device main body; A light source installed in the main body to emit light; A rotating multi-face mirror rotatably installed in the main body to deflect the light emitted from the light source; A driving motor for rotating the rotating polyhedron; A cover member installed in the main body to cover the rotating polyhedron, having a slit through which the light passes, formed in a vertical asymmetric shape, and formed with an inlet hole through which external air flows; And a dust collecting member for filtering dust contained in air introduced into the cover member through the inlet hole.

Here, the cover member, the upper end and the lower end is preferably formed in a dome shape.

In addition, the open lower end of the cover member may be provided with a plurality of fastening ribs for coupling to the bottom surface of the main body.

In addition, a circuit board supporting the driving motor and controlling the driving of the driving motor may be installed at the bottom of the main body.

In addition, a lower end of the cover member may be provided with a first step portion for providing a gap between the bottom surface of the main body and a second step portion for providing a gap between the circuit board.

In addition, the second step portion may be provided at a position corresponding to the corner portion of the circuit board.

In addition, it is preferable that a seating portion on which the dust collecting member is seated is provided around the inflow hole.

In addition, the dust collecting member is preferably a porous body.

In addition, the cover member may have a shape in which the inner diameter gradually increases from the top to the bottom.

Hereinafter, with reference to the accompanying drawings, it will be described in detail Gwangju presidential value according to an embodiment of the present invention.

1 and 2, the optical scanning device according to the embodiment of the present invention is irradiated from the injection device main body 10, the light source 20 installed inside the main body 10, and the light source 20. A rotary face mirror 30 for scanning the deflected light, a drive motor 40 for rotating the rotary face mirror 30, a circuit board 50 for controlling the drive of the drive motor 40, The cover member 60 and the dust collecting member 70 are installed to cover the rotating mirror mirror 30.

The main body 10 is mounted in the image forming apparatus in the form of a general cabinet or housing. The main body 10 is provided with a plurality of optical members to be described later, it is preferable to have a configuration that is not covered with foreign matter from the outside by a cover not shown.

The light source 20 is a semiconductor laser diode that irradiates light toward the rotating mirror mirror 30. The light source 20 emits light to be scanned to a counseling member such as a strong guam drum by being on / off controlled by the controller.

Here, optical members, that is, a collimating lens and a cylinder lens, which are not shown, are sequentially disposed between the light source 20 and the rotating mirror mirror 30. The collimating lens makes the emitted light into parallel light or convergent light with respect to the optical axis. The front surface of the collimating lens is provided with a slit (not shown) to limit light passing through the collimating lens. The cylinder lens linearly forms the light passing through the collimating lens in the horizontal direction on the reflective surface of the rotating multifaceted mirror 30. Therefore, the light passing through the cylinder lens is incident at the same angle to one side of the rotating polygon mirror (30).

The rotating mirror 30 has a plurality of reflecting surfaces 31 on the outside to deflect the light emitted from the light source 20 to a predetermined destination, that is, a counseling member such as a photosensitive drum. The rotary mirror 30 is supported by the driving motor 40 and rotates at a high speed, so that the attitude of the reflective surface 31 with respect to incident light is changed, so that the light can be deflected and scanned.

The drive motor 40 is installed on the circuit board 50. The drive motor 40 may be driven by the circuit board 50 to adjust the rotational speed of the rotating polygon mirror 30. The circuit board 50 is fixed to the bottom surface 11 in the body 10.

On the other hand, optical guide members (not shown) for guiding the light deflected by the rotating mirror 30 to a predetermined destination are further provided. That is, an f-theta lens and a reflecting mirror are formed to form the light scanned by the deflection mirror 30 in the final destination. Since the optical guide members are widely adopted components in a conventional optical scanning device, the detailed descriptions and drawings will be omitted.

The cover member 60 is installed in the main body 10 so as to cover the rotating mirror mirror 30. The cover member 60 has a substantially hemispherical shape, that is, a dome shape, and has a vertically asymmetrical structure. As such, the cover member 60 has an asymmetric shape at the top and the bottom thereof, specifically, the outer diameter gradually increases from the top to the bottom. In addition, the cover member 60 is installed to cover the rotating mirror mirror 30 and at the same time partially cover the bottom surface 11 of the circuit board 50 and the main body 10. Therefore, a plurality of fastening ribs 61 are provided at the lower end of the cover member 60. In this embodiment, three fastening ribs 61 are provided. In the state where the cover member 60 covers the rotating mirror mirror 30, each of the fastening ribs 61 is in close contact with the bottom surface 11 of the main body 10 so that the fastening ribs 61 can be engaged. It is preferable to provide. A screw hole 61a is formed in the fastening rib 61.

In addition, the upper portion of the cover member 60, that is, the ceiling is formed with an inlet hole 62 through which external air flows. By the air flow generated during the rotation of the rotating multi-face mirror 30 at a high speed, an external cavity flows into the cover member 60 through the inlet hole 62. At the edge of the inflow hole 62, a seating portion 62a on which the dust collecting member 70 is seated is formed. The seating part 62a may include a circular rib extending from an edge of the inflow hole 62. Here, since the cover member 60 has a dome shape, and the inlet hole 62 is formed on the ceiling of the cover member 60, the air introduced through the inlet hole 62 is formed inside the cover member 60. It has different flow characteristics (pressure, speed, direction) at the top and bottom.

In addition, the cover member 60 is formed with a slit 63 for the passage of the light is incident to the rotating polygon mirror 30, the deflection scan. The slit 63 has a predetermined width up and down on the drawing, and a predetermined length is formed left and right. As such, when the slit 63 is formed in the cover member 60, even when the rotating mirror mirror 30 is covered by the cover member 60, the function of the rotating mirror mirror 30 can be normally performed. have. In addition, the inflow air of the inflow hole 62 is discharged to the outside of the cover member 60 through the slit 63, which is generated inside the cover member 60 by the rotation of the rotary face mirror 30 It is possible to change the air flow characteristics (pressure, speed, direction).

In addition, as shown in FIG. 3, a pair of first stepped portions 64 and one second stepped portion 65 are provided at the lower end of the cover member 60. The first step portion 64 is formed at a portion corresponding to the corner portion 51 of the circuit board 50 when the cover member 60 is installed on the main body 10. Therefore, as shown in FIG. 4, the first step part 64 may avoid interference between the edge portion 51 of the circuit board 50 and the cover member 60, and the first step part 64 may be prevented. And a predetermined gap G1 can be provided between the edge portion 51 and the edge portion 51.

In addition, the second step portion 65 is provided in a portion covering the circuit board 50, and the second step portion 65 is also provided between the circuit board 50 and the lower end of the cover member 40 due to the second step portion 65. The gap G2 can be formed.

As described above, even when the cover member 60 is installed in the main body 10, the gaps G1 and G2 due to the first and second stepped portions 64 and 65 are generated. Therefore, the air flow generated in the cover member 40 during the rotation of the rotating mirror mirror 30 is guided downward in the characteristic of the hemispherical cover member 40, and a part of the air flows out through the slit 63. The rest is drawn out through the gap G1 and G2.

The dust collecting member 70 is for filtering dust contained in the air flowing into the cover member 60 through the inlet hole 62, and is installed in the seating portion 62a. The dust collecting member 70 may use a processing material such as a sponge or a generally used air filter to filter out fine dust and allow air to pass therethrough. The dust collecting member 70 may include a seat 62a. It may be simply seated on or fixed by an adhesive such as a bond.

Gwangju jangchim according to an embodiment of the present invention having the above configuration is covered with a rotating surface mirror 30 by the hemispherical cover member 60. Therefore, it is possible to prevent the firstly rotated mirror mirror 30 from being contaminated from external dust.

And at the time of high speed rotation of the rotary face mirror 30, the outside air is introduced through the inlet hole 62 of the cover member 60. At this time, the incoming air is filtered by the dust collecting member 70 so that no dust or the like is introduced and clean air is introduced.

The introduced air is guided and moved from the upper side to the lower side due to the hemispherical shape of the cover member 60, and part of the air is discharged to the outside of the cover member 60 through the slit 63. Then, the remaining flow air is guided toward the lower side of the cover member 60 to exit through the gaps (G1, G2). As such, the air flow generated inside the cover member 60 does not stay anywhere because the flow characteristics (speed, pressure, direction) are different from each other in the upper and lower portions. Therefore, even if fine dust not filtered by the dust collecting member 70 is included in the flow air, since the flow characteristic in the cover member 60 is not constant, the fine particles in the rotating multi-face mirror 30 eventually. Dust does not stick

In addition, the dust contained in the air discharged to the outside of the cover member 60 through the gaps G1 and G2 repeats a circulating operation introduced again through the inflow hole 62, thereby eventually causing the main body 10 to return. Dust in the) can be collected almost by the dust collecting member (70). Therefore, the amount of dust floating around in the main body 10 can be reduced, and contamination of other optical components can be reduced.

As described above, according to the optical scanning device of the present invention, it is possible to prevent the contamination of the rotating multi-face mirror by having a configuration to cover the rotating multi-face mirror using the upper and lower asymmetrical cover.

In addition, by forming an inlet hole in the ceiling of the cover member, and by providing a dust collecting member in the inlet hole, it is possible to reduce the contamination of the rotary face mirror by collecting the dust contained in the air flowing into the cover member during rotation of the rotary face mirror Further, there is an advantage that can not only prevent contamination of the optical members in the body, but also reduce the amount of dust.

Claims (9)

delete An injection device body; A light source installed in the main body to emit light; A rotating polygonal mirror rotatably installed in the main body to deflect and scan the light emitted from the light source; A drive motor for rotating the rotating polyhedron; A cover member installed in the main body to cover the rotating multi-face mirror, and having a slit through which the light passes, and an inlet hole through which external air flows; And And a dust collecting member for filtering dust contained in air introduced into the cover member through the inlet hole. The cover member is an optical scanning device, characterized in that the top and bottom are open, formed in a domed shape of the up and down asymmetry. The optical scanning device of claim 2, wherein a plurality of fastening ribs are provided at an open lower end of the cover member to couple to the bottom surface of the main body. The optical scanning device according to claim 2 or 3, wherein a circuit board which supports the driving motor and controls the driving of the driving motor is installed at the bottom of the main body. The method of claim 4, wherein the lower end of the cover member and the first step portion for providing a gap between the bottom surface of the main body, And a second step portion for providing a gap between the circuit board and the circuit board. The optical scanning device of claim 5, wherein the second stepped portion is provided at a position corresponding to an edge portion of the circuit board. The optical scanning device according to claim 2 or 3, wherein a seating portion on which the dust collecting member is mounted is provided around the inflow hole. The optical scanning device according to claim 2 or 3, wherein the dust collecting member is a porous body. delete

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