KR0120926Y1 - Laser beam scanning system - Google Patents

Abstract

The present invention relates to a laser beam scanning optical device, and in particular, by installing an optical sensor on the back side of a driving circuit board equipped with a lens system and enabling fine adjustment of the right and left and top and bottom angles of the detection mirror, Laser beam scanning to prevent interference between the scanning start beams B1 and at the same time to utilize the space, and to facilitate linear distance adjustment between the detection mirror 5 'and the optical sensor 6'. It relates to an optical device.

Description

Laser beam scanning optics

1 is a block diagram of a laser beam scanning optical apparatus according to the prior art.

2 is a cross-sectional view taken along line A-A of FIG.

3 is a sectional view taken along line B-B in FIG.

4 is a plan view of a laser beam scanning optical apparatus according to the present invention.

5 is a side cross-sectional view of a laser beam scanning optical apparatus according to the present invention.

6 is a cross-sectional view taken along line C-C in FIGS. 4 and 5.

* Explanation of symbols for main parts of the drawings

1 ': Laser generator 2': Rotating polygon mirror

3 ', 4': Lens system 5 ': Detecting mirror

6 ': Light sensor 7': Drum

20: drive circuit board 21: detect mirror bracket

22: screw 23: reflector

24: adjusting pin 25: screw

The present invention relates to a laser beam scanning optical device, and more particularly, to a laser beam scanning optical device which provides an optical sensor on the back side of a driving circuit board with a lens system and enables fine adjustment of the right and left and top and bottom angles of a detection mirror. It is about.

The conventional laser beam scanning optical apparatus includes a laser generator 1, a rotating polygon mirror 2 reflecting a laser beam incident from the laser generator 1, and the rotating polygon as shown in FIG. It consists of the lens system (3, 4) for passing the laser beam reflected from the mirror (2).

In addition, a detection mirror 5 for detecting the scanning start beam B1 passing through the lens systems 3 and 4, a detection mirror bracket 11 for supporting the detection mirror 5, and the An optical sensor 6 positioned on the same plane as the detection mirror 5 and receiving a scanning start beam B1 reflected from the detection mirror 5, the detection mirror 5 and the optical sensor 6. ) Is composed of a driving circuit board (10) fixed with a main beam (B2) passing through the lens system (3, 4) is incident to the drum (7) to form a latent image.

The conventional laser beam scanning optical apparatus configured as described above passes through the lens systems 3 and 4 after the laser beam emitted from the laser generator 1 is reflected by the rotating polygon mirror 2. The scanning start beam B1 passing through the lens systems 3 and 4 is reflected by the detector mirror 5 and then incident on the optical sensor 6 and detected. This detection signal is fed back to a system (not shown) and based on the detection signal, the system controls the laser generator 1.

The information required by the drum 7 is controlled by the system and is emitted from the laser generator 1 to the main beam B2. The main beam B2 passes through the rotating polygon mirror 2 and the lens systems 3 and 4 to form a straight latent image on the drum 7. After that, the developed paper is printed out.

Here, the length of the optical path from the main plane (Principal Plane / Nodal Point) of the lens system (3,4), which is a point of reference of the lens system focal length determined by the lens radius of curvature and the refractive index, to the drum (7) and the lens system ( The length of the optical path from the main point of 3 and 4 to the optical sensor 6 should be the same. The drum 7 is then located at the focal position of the lens system 3, 4 in order to form an image of the required information with good resolution. The optical sensor 6 is also located at the focal position of the lens system 3, 4, where the cross-sectional area of the laser beam at the moment of arrival at the optical sensor is minimized.

However, in the conventional laser beam scanning optical apparatus as described above, since the detection mirror 5 and the optical sensor 6 for detecting the scanning start beam B1 are located on the upper surface of the driving circuit board 10, the drum Many problems arise in setting the positions of the detection mirror 5, the optical sensor 6, and the driving circuit board 10 so as not to interfere with the main beam B2 incident on (7).

Further, as shown in FIG. 2 and FIG. 3, since the above-described detector mirror 5 is fixed to the detector mirror bracket 11, the linear distance between the detector mirror 5 and the optical sensor 6 Even if the position or angle of the detector mirror 5 changes a little, the scanning start beam B1 is not incident on the optical sensor 6, which makes it difficult to align the laser beam.

Therefore, the present invention for solving the above problems of the prior art has a problem that the laser beam alignment is difficult because it is not incident on the optical sensor 6 for detecting the scanning start beam.

Therefore, the present invention for solving the above problems of the prior art provides a simple structure by installing an optical sensor for detecting the scanning start beam on the back side of the driving circuit board with a lens system, and the vertical angle and left and right angles of the detection mirror bracket It is an object of the present invention to provide a laser beam scanning optics which is advantageous for laser beam alignment by finely adjusting the angle.

The laser beam scanning optical apparatus of the present invention for achieving the above object, the laser generating device, a rotating multi-face mirror reflecting the incident laser beam emitted from the laser generating device, and positioned above the drive circuit board to rotate A lens system through which a laser beam reflected from a multi-facet mirror passes, a detection mirror positioned on the same plane as the lens system and receiving a scanning start beam passing through the lens system and reflecting downward toward a driving circuit board, and the driving circuit A detector mirror bracket fixed to an upper surface of a substrate to support the detector mirror and to fine-adjust the upper and lower angles and the left and right angles of the detector mirror, and installed on the bottom surface of the driving circuit board, A reflector reflecting the reflected scanning start beam and a bottom surface of the driving circuit board, The optical sensor for detecting the reflected scanning start beam, and the main beam is passed through the lens system is characterized in that the drum is formed to form a latent image.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

The laser beam scanning optical apparatus according to the present invention includes a laser generator 1 'positioned above the driving circuit board 20, as shown in FIGS. 4 and 5, from the laser generator 1'. A rotating polygonal mirror 2 'that receives and reflects the emitted laser beam, and is positioned above the driving circuit board 2 and positioned above the rotating polygon mirror 2' and above the driving circuit board 2; And a lens system (3 ', 4') positioned above the rotating polygon mirror (2 ') and positioned above the driving circuit board (20) and passing through a laser beam reflected from the rotating polygon mirror (2'). do.

In addition, the scanning start beam B1 is incident on the same plane as the lens systems 3 'and 4' and passes through the lens systems 3 'and 4' and is reflected to the lower side of the driving circuit board 20. A detection mirror bracket 21 for supporting the detection mirror 5 'and the detection mirror 5' and finely adjusting the vertical and horizontal angles of the detection mirror 5 '; A driving assembly disposed on a bottom surface of the driving circuit board 20 to reflect the scanning start beam B1 reflected from the detection mirror 5 ', and a driving circuit in which the lens systems 3' and 4 'are located. The optical sensor 6 'which is located on the back surface of the substrate 200 and detects the scanning start beam B1 reflected by the reflector 23 is located on the same plane as the lens system 3', 4 '. The main beam B2 passing through the lens systems 3 'and 4' is incident to a drum 7 'on which a latent image is formed, and the detection mirror bracket 210 is as shown in FIG. The shape of the side is an elastic member formed by the letter 'S', the detection mirror (5 ') is installed at the front end and the adjustment screw 22 is inserted in the rear side, depending on the degree of tightening of the screw 22 The vertical angle of the text mirror 5 'is finely adjusted.

Also, as illustrated in FIG. 6, the detection mirror 5 ′ is temporarily inserted as the adjustment pin 24 connecting the driving circuit board 20 and the detection mirror bracket 21 is rotated left and right. The left and right angles of the detection mirror 5 'are finely adjusted by rotating the left and right directions 25 along the axis.

In the laser beam scanning optical apparatus of the present invention configured as described above, the scanning start beam B1 emitted from the laser generator 1 'is reflected by the rotating polygon mirror 2' and passes through the lens system 3 ', 4'. After that, the light is reflected by the detection mirror 5 'and the reflector 23 and is incident on the optical sensor 6' and detected. This detection signal is fed back to the system, and the system controls the ray generating device 1 'on the basis of the detection signal.

The information required by the drum 7 'is emitted from the laser generator 1' under the control of the system to the main beam B2. The main beam B2 passes through the rotating polygon mirror 2 'and the lens systems 3' and 4 'and forms a straight latent image on the drum 7'. After that, the developed paper is printed out.

Here, the optical sensor has a length equal to the length of the optical path from the main points of the lens systems 3 'and 4' to the drum 7 'and the length of the optical path from the main points of the lens systems 3' and 4 'to the optical sensor 6'. 6 'is provided on the rear surface of the drive circuit board 20 on which the lens systems 3', 4 'are mounted. By adjusting the screw 22 provided behind the detector mirror bracket 21 to which the detector mirror 5 'is attached, the scanning start beam B1 reflected from the detector mirror 5' and the reflector 23 is The vertical angle of the detection mirror 5 'may be finely adjusted to be incident on the optical sensor 6'.

In addition, when the adjusting pin 24 connecting the driving circuit board 20 and the detection mirror bracket 21 is rotated to the left and right, the screw 25 connecting the driving circuit board 20 and the detection mirror bracket 21 to each other. The detect mirror bracket 21 rotates about. By doing so, the left and right angles of the detection mirror 5 'can be finely adjusted so that the scan start beam B1 reflected by the detector mirror 5' and the reflector 23 can be incident on the optical sensor 6 '. have.

Therefore, the laser beam scanning optical apparatus of the present invention as described above makes it easy to adjust the linear distance between the detection mirror 5 'and the optical sensor 6', and the up and down angles and the left and right angles of the detection mirror 5 '. Is fine tuned to facilitate beam alignment.

In particular, the present invention can prevent the interference between the main beam (B2) and the scanning start beam (B1) by installing the optical sensor (6 ') on the back of the drive circuit board 20, the lens system (3', 4 ') is installed. At the same time, the utilization of space is advantageous, and the simple structure can be realized.

Claims (3)

A lens system through which a laser generating device, a rotating multifaceted mirror which receives and reflects a laser beam emitted from the laser generating device, and a laser beam which is positioned on an upper side of a driving circuit board and reflected by the rotating multifaceted mirror are passed through, are the same as the lens system A detection mirror positioned on a plane and reflecting a scanning start beam passing through the lens system in a downward direction of the driving circuit board, and fixed to an upper surface of the driving circuit board to support the detection mirror; A detector mirror bracket for finely adjusting the upper and lower angles and the left and right angles of the mirror, a reflector installed on the bottom surface of the driving circuit board and reflecting the scanning start beam reflected from the detection mirror, and a bottom surface of the driving circuit board. An optical sensor installed in the sensor to detect a scanning start beam reflected from the reflector, and a main sensor passing through the lens system A laser beam scanning optical device, characterized in that consisting of a drum in which a beam is incident to form a latent image. The method of claim 1, wherein the detection mirror bracket is a resilient member formed by the shape of the letter 'S' side, the detection mirror is installed at the front end and the adjustment screw is inserted into the rear side, the screw insertion degree According to the laser beam scanning optical device, characterized in that the vertical angle of the detection mirror to be finely adjusted. The left and right angles of the detector mirror of claim 1, wherein the detector mirror bracket is rotated from side to side on an axis of the temporarily inserted screw as the adjusting pin connecting the driving circuit board and the detector mirror bracket is rotated from side to side. Laser beam scanning optics, characterized in that the fine tuning is carried out.