KR20060033123A - Mirror positioning structure of laser scanning unit and laser scanning unit employing the mirror positioning structure - Google Patents

Abstract

The present invention discloses a position adjusting structure of a reflector for scanning inclination and scanning curvature correction, and an optical scanning device employing the same. Position adjustment structure of the reflector for a light scanning device according to the present invention, the groove is formed on one side for holding the reflecting mirror, the other side is a reflector rotating member protruding a rotating shaft; An reflector position shifting member having an opening formed to penetrate the rotating shaft of the reflector rotating member, and through which the reflector rotating member is rotatably coupled; And a fixing member having an accommodation space provided at one side such that the reflector position shifting member can be linearly movable.

Description

Positioning structure of reflector for scanning slope and scanning curvature correction, and optical scanning device employing it {Mirror positioning structure of laser scanning unit and laser scanning unit employing the mirror positioning structure}

1A and 1B show a conventional optical scanning device and a reflector structure.

Figure 2 shows a conventional structure for adjusting and fixing the tilt of the reflector.

Figure 3 shows the scanning inclination and the scanning curve generated in the optical scanning device in the form of a graph.

4A to 4D show a reflector rotating member of the reflector position adjusting structure according to the present invention.

5A to 5D show a reflector position shifting member of the reflector position adjusting structure according to the present invention.

6a to 6d show a fixing member of the reflector position adjusting structure according to the present invention.

7A and 7B show a coupling relationship between the reflector rotating member, the reflector position shifting member, and the fixing member.

8A and 8B show the coupling relationship and the operation of the reflector rotating member and the reflector position shifting member, respectively.

9A to 9D illustrate the linear movement operation of the reflector position shifting member.

10A to 10C are perspective views illustrating the overall operation of the reflector position adjusting structure according to the present invention.

11A and 11B illustrate scan tilt and scan curvature correcting operations by rotation and position adjustment of the reflector in the optical scanning apparatus according to the present invention.

※ Explanation of code about main part of drawing ※

10 ..... reflector rotating member 12 ..... rotating shaft

20 ..... Reflector position shifting member 30 ..... fixed member

40 ..... reflector 50 ..... polygon mirror

60 ..... scan lens 70 ..... photosensitive drum

The present invention relates to a position adjusting structure of a reflecting mirror for scanning inclination and scanning curvature correction, and an optical scanning device employing the same. More specifically, the rotation and linear movement of the reflecting mirror for scanning inclination and scanning curvature correction can be facilitated. A position adjusting structure and an optical scanning device employing the same.

Background Art In general, a laser printer is a printing apparatus that forms an image while scanning laser light emitted from a laser diode on a photosensitive member, and reproduces an image image by transferring a latent image formed on the photosensitive member onto a medium such as paper. The optical scanning device is an image forming apparatus that performs a function of generating laser light in the laser printer and forming an image on a photosensitive member. 1A and 1B schematically illustrate a typical Gwangju presidential device. As shown in FIGS. 1A and 1B, the optical scanning apparatus 100 generally includes a light source 111, a collimating lens 112, an aperture diaphragm 113, a cylinder lens 114, and a polygon mirror 115. And a scanning lens 116, a reflecting mirror 117, a photosensitive drum 118, and the like. In this case, the light source 111, the collimating lens 112, the aperture stop 113, the cylinder lens 114, the polygon mirror 115, the scanning lens 116 and the reflector 117 is dust generated inside the printer In order to prevent contamination due to the like is installed in a separate frame (110).

In such a structure, the light beam emitted from the light source 111 such as a laser diode is converted into a parallel beam with respect to the optical axis by the collimating lens 112. After the parallel beam is restricted by the aperture stop 113, the parallel beam passes through the cylinder lens 114 and converges in the sub scanning direction to become linear light in a horizontal direction with respect to the sub scanning direction. Thereafter, the horizontal linear light is moved at a constant velocity in the main scanning direction (ie, the horizontal direction of the paper) by the polygon mirror 115 rotating at a high speed while the scanning lens 116 and the reflecting mirror 117 are moved. It forms on the photosensitive drum 118 via. Here, the scanning lens 116 has a constant refractive index with respect to the optical axis, and functions to focus the light on the photosensitive drum 118 by polarizing light having a constant velocity reflected by the polygon mirror 115 in the main scanning direction.

In the optical scanning device 100, the light beam passing through the scanning lens 116 should be scanned on a scan surface such as the photosensitive drum 118 in a straight line along the main scanning direction. However, due to assembling tolerances and aberrations, as shown in FIG. 3, the light beam is finely deviated in the sub-scanning direction and does not scan in a straight line along the main scanning direction of the scan surface. In FIG. 3, a phenomenon in which the heights X ₁ and X ₂ of both ends A and B of the trajectory of the beam spot of the beam spot are different in the sub-scanning direction is called a skew, and the scan line does not become a straight line. The phenomenon of bending is called a bow. Such scanning inclination and scanning curvature lower the printing accuracy and lower the image quality. In particular, in the case of a tandem optical scanning device used in a color laser printer or the like, scanning inclination and scanning curvature are a big problem. In the case of a color laser printer using a tandem type optical scanning device, the scan line curvature on each photosensitive drum is formed differently, and color reproducibility is greatly reduced. The reflector 117 serves to correct the scanning inclination and the scanning curvature by appropriately adjusting the incident angle of the light beam.

2 exemplarily illustrates a conventional structure for adjusting the inclination of the reflector 117. As shown in FIG. 2, in the conventional case, the groove 125 is formed in the frame 110, and the lower end portion of the reflector 117 is inclined to the groove 125. The screw 122 is installed at a position on the frame 110 corresponding to the upper end of the reflector 117. Thereafter, the screw 122 is rotated to appropriately adjust the insertion depth of the screw 122, thereby adjusting the angle of the reflector 117. Then, the reflector 117 is firmly fixed using the leaf spring 120.

In the related art, by adjusting the angle of the reflector, the angle of the beam scanned by the photosensitive drum is changed to correct the scanning distortion of the beam. However, in order to correct the distortion more efficiently, not only the angle of the beam scanned by the photosensitive drum should be aligned by adjusting the rotation angle of the reflector between the scanning lens and the photosensitive drum, but also the beam incident on the scanning lens The inclination position of the beam must be corrected by adjusting the incidence position of the beam so that the scanning slope and the scanning curvature can be corrected simultaneously. Therefore, there is a need for a new technology capable of simultaneously adjusting the incident angle and the incident position of the scanning beam, rather than the conventional technique of correcting the scanning distortion phenomenon by only adjusting the rotation angle of the reflector. There is also a need for a complementary technique that allows for more robust attachment of reflectors.

SUMMARY OF THE INVENTION An object of the present invention is to provide a position adjusting structure of a reflecting mirror capable of simultaneously adjusting an incident angle and an incident position of a scanning beam, and a gwangju scanning device using the same.

It is also an object of the present invention to improve the quality of color print images by mechanically correcting scan slant and scan curvature phenomena caused by alignment errors of a laser beam in a tandem optical scanning device in a color laser printer.

Position adjustment structure of the reflector for optical scanning device according to one type of the present invention, the groove is formed on one side for holding the reflecting mirror, the other side is a reflector rotating member protruding a rotating shaft; An reflector position shifting member having an opening formed to penetrate the rotating shaft of the reflector rotating member, and through which the reflector rotating member is rotatably coupled; And a fixing member having an accommodation space provided at one side such that the reflector position shifting member can be linearly movable.

According to another type of the present invention, a light source for generating light, an optical unit for scanning and imaging the light generated from the light source on the scan surface, a reflector for correcting the scanning slope and the scanning curvature on the optical path between the light source and the scan surface And a reflector position adjusting means for adjusting a position and angle of the reflector, wherein the reflector position adjusting means includes: a groove is formed at one side to insert and hold the reflector, and the rotating shaft protrudes at the other side. Formed reflector rotating member; An reflector position shifting member having an opening formed to penetrate the rotating shaft of the reflector rotating member, and through which the reflector rotating member is rotatably coupled; And a receiving member provided on one side so that the reflector position shifting member can be linearly movable, and a fixing member attached to the outer frame of the optical scanning device.

Hereinafter, with reference to the accompanying drawings, it will be described in detail the structure and operation of the position adjusting structure of the reflector for optical scanning device according to an embodiment of the present invention and the optical scanning device employing the same.

The position fixing structure of the reflector for an optical scanning device according to the present invention includes a reflector rotating member for holding and rotating the reflector, a reflector position shifting member for linearly moving the reflector, and a fixing member for fixing them.

4A to 4D show a reflector rotating member among them, and FIG. 4A is a front view of the reflector rotating member, FIG. 4B is a side view, FIG. 4C is a rear view, and FIG. 4D is a perspective view. As shown in Figure 4a to 4d, the rotating shaft 12 is protruded in the front of the reflector rotating member 10 according to the present invention, the insertion groove 15 for inserting and holding the reflector is formed in the rear have. When the reflector rotating member 10 rotates about the rotation shaft 12, the reflector (not shown) inserted into the insertion groove 15 rotates, thereby adjusting the angle of the reflector. At this time, the straight groove 13 is formed at the end of the rotating shaft 12 so that the reflector rotating member 10 can be easily rotated. Therefore, when assembling, it is possible to easily rotate the reflector rotating member 10 using a tool such as a screwdriver. Although the groove-shaped groove 13 is illustrated in the drawing, the groove 13 may be formed in any other form. In addition, at least one rotation fixing hole 14 is formed near the rotation axis 12 of the reflector rotating member 10. As will be described later, after the angle of the reflector is adjusted, the rotation fixing member is inserted into the rotation fixing hole 14 to fix the reflector so that it no longer rotates. On the other hand, a plurality of ribs 16 is formed on one side of the reflector insertion groove 15 formed on the rear surface of the reflector rotating member 10, it is possible to prevent the deformation of the insertion groove (15).

5A to 5D show a reflector position shifting member of the reflector position adjusting structure according to the present invention, FIG. 5A is a front view of the reflector position shifting member 20, FIG. 5B is a side view, and FIG. Back view, FIG. 5D shows a perspective view. 5A to 5D, an opening 21 is formed in the vicinity of the center of the reflector position shifting member 20 according to the present invention so that the rotation shaft 12 of the reflector rotating member 10 penetrates. Therefore, the reflector rotating member 10 may be rotatably coupled to the reflector position shifting member 20 through the opening 21. The through hole 23 for the rotation fixing member is formed below the opening 21. The rotation fixing member is inserted into the rotation fixing hole 14 of the reflector rotating member 10 by passing through the rotating fixing member through hole 23, thereby the reflector position shifting member 20 and the reflector rotating member 10. ) Are coupled to and fixed to each other. In this case, the rotating fixing member through-hole 23 has a form of a long hole so that the reflector rotating member 10 can be combined with the reflector position shifting member 20 within a predetermined angle range. In addition, a groove 22 is formed at a predetermined depth so that the rotation fixing member may be seated around the through hole 23 for the rotation fixing member. On the other hand, a linear movement fixing hole 24 is formed above the opening 21 in front of the reflector position shifting member 20, and the linear shift amount adjusting member is formed on at least one side of the reflector position shifting member 20. The hole 25 for linear movement amount adjustment member to be inserted is formed. This will be described later.

6a to 6d show a fixing member of the reflector position adjusting structure according to the present invention, Figure 6a is a front view of the fixing member 30, Figure 6b is a rear view, Figure 6c is a perspective view, Figure 6d is another The rear view of the holding member of the form is shown. As shown in Figure 6a and 6c, the fixing member 30 according to the present invention is provided with an accommodating space 34 in the rear so that the reflector position shifting member 20 can be linearly received. In addition, through-holes 31, 32, and 33 respectively corresponding to the opening 21, the rotation fixing member through-hole 23, and the linear movement fixing hole 24 of the reflector position shifting member 20 are formed, respectively. It is. At this time, the through-hole 31 of the fixing member corresponding to the opening 21 and the linear movement fixing hole 24 so that the linear movement amount of the reflector position shifting member 20 can be adjusted within a predetermined range. 33) is in the form of a long hole. Similarly, the through hole 32 of the fixing member corresponding to the through hole 23 for the rotation fixing member has a form of a long hole so that the reflector rotating member 10 can be adjusted within a predetermined angle range. In addition, as shown in Figure 6a, around the through-hole 33 of the fixing member corresponding to the linear movement fixing hole 24, the groove (37) to a predetermined depth so that the linear movement fixing member to be described later to be seated ) Is formed. The through hole 31 is for inserting the rotary shaft 12 of the reflector rotating member 10.

6A and 6C, the linear movement amount adjusting member mounting portion 35 is formed on the fixing member so that the linear movement amount adjusting member coupled to the side surface of the reflector position shifting member 20 can be seated and fixed. It is. On the upper surface of the linear movement amount adjustment member mounting portion 35 is formed a groove 36 on which the linear movement amount adjustment member is seated. At this time, the groove 36 has a relatively large diameter portion 36a for seating the head portion of the linear movement amount adjustment member and a relatively small portion 36b for mounting the body portion of the linear movement amount adjustment member. Have The linear movement of the reflector position shifting member 20 in the receiving space 34 of the fixing member 30 is performed by rotating the linear shift amount adjusting member seated on the linear shift amount adjusting member mounting portion 35. The adjustment hole 38 is formed at the side position of the fixing member 30 so that the member can be easily rotated from the outside. 6A and 6C, although the linear movement amount adjusting member mounting portion 35 is provided only on one side of the fixing member 30, as shown in FIG. 6D, the linear movement amount adjustment is symmetrically on both sides of the fixing member 30. The member mounting part 35 can also be formed.

7A and 7B illustrate a coupling relationship between the reflector rotating member 10, the reflector position shifting member 20, and the fixing member 30. As shown in FIG. 7A, the reflector position shifting member 20 is accommodated in the accommodation space 34 of the fixing member 30. At this time, the linear movement amount adjusting member 28 is inserted into the hole 25 formed on the side surface of the reflector position shifting member 20 and then seated on the groove 36 on the linear movement amount adjusting member mounting portion 35. As the linear movement amount adjusting member 28, for example, a screw can be used. The head of the linear movement amount adjusting member 28 is exposed to the outside through the adjusting hole 38, for example, by inserting a screwdriver, the linear movement amount adjusting member 28 may be rotated. . Meanwhile, the rotating shaft 12 of the reflector rotating member 10 is inserted into the opening 21 of the reflector position shifting member 20 and the through hole 31 of the fixing member 30, thereby reflecting the reflector rotating member 10. It is coupled to the position moving member 20 and the fixing member (30). The fixing member 30 is attached to, for example, an outer frame (not shown) of the optical scanning device. FIG. 7B illustrates a state in which the reflector rotating member 10, the reflector position shifting member 20, and the fixing member 30 are coupled to each other.

8A and 8B show the coupling relationship and the operation of the reflector rotating member 10 and the reflector position shifting member 20 in more detail, respectively. First, as shown in FIG. 8A, the rotating shaft 12 of the reflector rotating member 10 is inserted into the opening 21 of the reflector position shifting member 20, whereby the reflector rotating member 10 is mirrored position shifting member. Is rotatably coupled to (20). Then, the rotation fixing member 27 is loosely inserted into the rotation fixing hole 14 of the reflector rotating member 10 by passing through the rotation fixing member through hole 23. Here, for example, a screw may be used as the rotation fixing member 27. 8b shows the assembled state from the front. The angle of the reflector can be adjusted, for example, by rotating the rotating shaft 12 using a screwdriver. As the rotation shaft 12 rotates, the rotation fixing member 27 loosely inserted into the rotation fixing hole 14 is moved in the through hole 23 for the rotation fixing member in the form of a long hole. When the angle of the reflector is determined, the rotation fixing member 27 is rotated to firmly fix the reflector position shifting member 20 and the reflector rotating member 10, so that the angle of the reflector does not change afterwards.

9A to 9D illustrate a linear movement operation of the reflector position shifting member 20. Here, for convenience of description, the reflector rotating member 10 coupled to the reflector position shifting member 20 is omitted. First, as shown in the rear view of FIG. 9A, when the linear movement amount adjusting member 28 is deeply inserted into the reflector position shifting member 20, when viewed from the rear, the reflector position shifting member 20 receives the fixing member 30. It is located relatively left in the space 34. 9b shows the coupling state of the reflector position shifting member 20 and the fixing member 30 from the front. As shown in FIG. 9B, when the linear movement amount adjusting member 28 is deeply inserted into the reflector position shifting member 20, when viewed from the front, the linear movement fixing hole 24 of the reflector position shifting member 20 is shown. The right side of the through hole 33 of the fixing member 30 is located. Similarly, the opening 21 of the reflector position shifting member 20 is also located on the right side of the through hole 31 of the fixing member 30 when viewed from the front.

When adjusting the position of the reflector position shifting member 20, for example, by inserting a screwdriver into the adjustment hole 38, the linear shift amount adjustment so that the linear shift amount adjusting member 28 is released from the reflector shifting member 20. Rotate member 28. At this time, since the linear movement amount adjusting member 28 is fixed on the mounting portion 35 of the fixing member 30, as shown in FIG. 9C, when viewed from the rear side, the position of the reflector moves to the right side in the accommodation space 34. The member 20 is moved. 9D shows the coupling state of the reflector position shifting member 20 and the fixing member 30 in this case from the front. As shown in FIG. 9D, when the linear movement amount adjusting member 28 is released from the reflector position shifting member 20, when viewed from the front, the linear movement fixing hole 24 of the reflector position shifting member 20 is fixed. The left side of the through hole 33 of the member 30 is moved. Similarly, the opening 21 of the reflector position shifting member 20 also moves to the left side of the through hole 31 of the fixing member 30 when viewed from the front. In this way, when the position of the reflector position shifting member 20 is determined, the linear movement fixation member 29 (see FIG. 10C) is moved to the linear shift fixing hole 24 so that the reflector position shifting member 20 does not move. By inserting in the coupling and positioning the reflector positioning member 20 and the fixing member 30.

10A to 10C are perspective views illustrating the overall operation of the reflector position adjusting structure according to the present invention. First, as shown in Figure 10a, by rotating the rotating shaft 12 of the reflector rotating member 10 protruding out of the fixing member 30 to adjust the angle of the reflector 40 coupled to the reflector rotating member 10 do. When the angle of the reflector 40 is determined, through the through hole 32 of the fixing member 30, for example, by inserting a screwdriver to tighten the rotation fixing member 27 to move the reflector rotating member 10 to the reflector position. Fix it firmly to the moving member (20).

Thereafter, as shown in FIG. 10B, the linear movement amount adjusting member 28 is rotated by inserting, for example, a screw driver into the adjustment hole 38 formed on the side of the fixing member 30, thereby changing the reflector position shifting member ( Adjust the position of 20). When the reflector positioning member 20 moves, the reflector 40 coupled to the reflector rotating member 10 also moves together. When the position of the reflector 40 is determined in this way, as shown in FIG. 10C, the linear movement fixing member 29 is moved through the through hole 33 of the fixing member 30 to the linear movement fixing hole 24. By inserting in, the reflector position shifting member 20 is firmly fixed to the fixing member (30). In this case, the linear movement fixing member 29 may be, for example, a screw.

Next, a process of correcting the scanning slope and the scanning curvature in the optical scanning device will be described using the position adjusting structure of the reflector according to the present invention having the above-described configuration and operation. As described above, the scan tilt and the scan curvature are mainly caused by the light beams being finely deviated due to assembly tolerances and aberrations. The present invention corrects such scan slope and scan curvature by independently adjusting the rotation angle and position of the reflector. FIG. 11A illustrates a case in which the position adjustment structure of the reflector is located between the polygon mirror 50 and the scanning lens 60. Thus, the reflector 40 is also between the polygon mirror 50 and the scanning lens 60. As shown in FIG. 11A, by properly rotating the reflector 40, the incident angle at which the light beam deflected by the polygon mirror 50 is incident on the scanning lens 60 is adjusted. When the light beam does not enter the center of the scanning lens 60 accurately, the light beam deflected by the polygon mirror 50 is moved by shifting the position of the reflector 40 using the position adjustment structure of the reflecting mirror. The incident position incident on 60) can be adjusted.

11B is a case where the position adjusting structure of the reflecting mirror according to the present invention is located between the scanning lens 60 and the scan surface, that is, the photosensitive drum 70. Thus, in this case, the reflector 40 is between the scanning lens 60 and the photosensitive drum 70. As shown in FIG. 11B, the angle and position of the reflector 40 are appropriately adjusted by using the reflector position adjusting structure, so that the light beam focused on the photosensitive drum 70 by the scanning lens 60 is accurately corrected. By allowing the incident light to enter the photosensitive drum 70, the scanning inclination and the scanning curvature can be corrected.

So far, the position adjusting structure and the optical scanning device of the reflector according to the present invention have been described in detail. As described above, according to the present invention, it is possible to simply and independently adjust the angle and the position of the reflector for correcting the scanning curvature and the scanning inclination. Therefore, for example, in the tandem type optical scanning device in a color laser printer, by scanning mechanically correcting scan slant and scan curvature phenomena which are difficult to correct in circuit among scan distortion phenomena caused by alignment error of the laser beam, color printing image Can improve the quality.

Claims (25)

A groove for inserting and holding a reflector is formed at one side, and a reflector rotating member having a rotating shaft protruding from the other side; An reflector position shifting member having an opening formed to penetrate the rotating shaft of the reflector rotating member, and through which the reflector rotating member is rotatably coupled; And Positioning structure of the reflector for a light scanning device, characterized in that it comprises a; fixing member having a receiving space on one side so that the reflector position moving member is linearly movable. The method of claim 1, Positioning structure of the reflector for optical scanning device, characterized in that the groove is formed at the end of the rotating shaft to facilitate the rotation of the rotating shaft. The method according to claim 1 or 2, And at least one rotation fixing hole is formed around the rotation axis of the reflector rotating member. The method of claim 3, wherein Penetration for the rotation fixing member to the reflector position shifting member so that the rotation fixing member for coupling and fixing the reflector position shifting member and the reflector rotational member can be inserted into the rotation fixing hole through the reflector position shifting member. Positioning structure of the reflector for optical scanning device, characterized in that the hole is formed. The method of claim 4, wherein Positioning structure of the reflector for optical scanning device, characterized in that the through-hole for the rotation fixing member is in the form of a long hole so that the reflector rotating member can be combined with the reflector position shifting member within a predetermined angle range. The method of claim 4, wherein Positioning structure of the reflector for the optical scanning device, characterized in that the groove is formed to a predetermined depth so that the rotation fixing member is seated around the through hole for the rotation fixing member. The method of claim 4, wherein A linear movement fixing hole is formed on a surface of the reflector position shifting member facing the fixing member, and a linear movement amount adjusting member is coupled to at least one side of the reflector position shifting member. Positioning structure. The method of claim 7, wherein Positioning structure of the reflector for a light scanning device, characterized in that the rotation fixing member and the linear movement amount adjusting member is a screw. The method of claim 7, wherein Positioning structure of the reflector for the optical scanning device, characterized in that the through-hole is formed in the position of the fixing member corresponding to the opening formed in the reflector position moving member, the through hole for the rotation fixing member and the hole for linear movement fixing, respectively. The method of claim 9, And the through-holes of the fixing member are in the form of long holes so that the linear movement amount of the reflector position shifting member can be adjusted within a predetermined range. The method of claim 10, The linear movement fixing member is inserted into the linear movement fixing hole by passing through the through hole of the fixing member corresponding to the linear movement fixing hole, so that the reflector position shifting member and the fixing member are coupled and fixed to each other. Position adjusting structure of reflector for optical scanning device. The method of claim 11, Positioning structure of the reflector for a light scanning device, characterized in that the linear movement fixing member is a screw. The method of claim 11, And a groove is formed at a predetermined depth so that the linear movement fixing member is seated around the through hole of the fixing member corresponding to the linear movement fixing hole. The method of claim 7, wherein Reflector for the optical scanning device, characterized in that the linear movement amount adjusting member mounting portion is formed at the position of the fixed member corresponding to the linear movement amount adjusting member so that the linear movement amount adjusting member coupled to the side of the reflector position shifting member can be seated and fixed. Positioning structure. The method of claim 14, By rotating the linear movement amount adjusting member, the reflector position shifting member moves linearly in the receiving space of the fixing member, and the side surface of the fixing member corresponding to the linear movement amount adjusting member to rotate the linear movement amount adjusting member from the outside. Positioning structure of the reflector for optical scanning device, characterized in that the adjustment hole is formed in the position. A light source for generating light, an optical unit for scanning and imaging light generated from the light source on a scan surface, a reflector for correcting scan slope and scan curvature on an optical path between the light source and the scan surface, and the position and angle of the reflector In the optical scanning device comprising a reflector position adjusting means for adjusting the, The reflector position adjusting means is: A groove for inserting and holding a reflector is formed at one side, and a reflector rotating member having a rotating shaft protruding from the other side; An reflector position shifting member having an opening formed to penetrate the rotating shaft of the reflector rotating member, and through which the reflector rotating member is rotatably coupled; And And an accommodation space is provided on one side so that the reflector position shifting member can be linearly movable, and a fixing member attached to an outer frame of the optical scanning apparatus. The method of claim 16, An optical scanning device, characterized in that the groove is formed at the end of the rotating shaft to facilitate the rotation of the rotating shaft. The method according to claim 16 or 17, And at least one rotation fixing hole is formed in the vicinity of a rotation axis of the reflector rotating member. The method of claim 18, A through hole for the rotation fixing member in the reflector position shifting member so that the rotation fixing member for coupling and fixing the reflector position shifting member and the reflector rotational member can be inserted into the rotation fixing hole through the reflector position shifting member. Is formed, the optical scanning device, characterized in that the through-hole for the rotation fixing member is in the form of a long hole so that the reflector rotating member is coupled to the reflector position shifting member within a predetermined angle range. The method of claim 19, And a linear movement fixing hole formed on a surface of the reflector position shifting member facing the fixing member, and a linear movement amount adjusting member is coupled to at least one side of the reflector position shifting member. The method of claim 20, And through-holes are formed at positions of the fixing members corresponding to the openings, the rotating fixing member through holes, and the linear movement fixing holes formed in the reflector position moving members, respectively. The method of claim 21, And the through-holes of the fixing member are in the form of long holes so that the linear movement amount of the reflector position shifting member can be adjusted within a predetermined range. The method of claim 22, The linear movement fixing member is inserted into the linear movement fixing hole by passing through the through hole of the fixing member corresponding to the linear movement fixing hole, so that the reflector position shifting member and the fixing member are coupled and fixed to each other. Optical fiber scanning device. The method of claim 22, And a linear movement amount adjusting member mounting portion formed at a position of the fixed member corresponding to the linear movement amount adjusting member so that the linear movement amount adjusting member coupled to the side of the reflector position moving member can be seated and fixed. The method of claim 24, By rotating the linear movement amount adjusting member, the reflector position shifting member moves linearly in the receiving space of the fixing member, and the side surface of the fixing member corresponding to the linear movement amount adjusting member to rotate the linear movement amount adjusting member from the outside. Optical scanning device, characterized in that the adjustment hole is formed in the position.

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