KR20070065687A - Polygon mirror and working methode of the same - Google Patents

Abstract

A polygon mirror and a processing method thereof are provided to extend a beam scanning range of the polygon mirror and to cut down the manufacturing cost by mass-producing the polygon mirrors through an ultra precision processing method using aluminum materials. A polygon mirror processing method is composed of a material processing step for forming a through-hole(12) in the center of processing materials of a polygon mirror(10); a material fixing step for clamping the processing material to an angle splitting shaft through the through-hole formed on the processing material; a reference mirror surface processing step for forming a reference mirror surface(13) parallel to or inclined at the predetermined angle for the angle splitting shaft, on the outer peripheral surface of the processing material of the polygon mirror, by using a fly-cutter installed at a main shaft capable of being controlled in the directions of three axes; a material rotating step for rotating the processing material of the polygon mirror for the reference mirror surface at the predetermined angle; and a mirror surface processing step for processing the mirror surface parallel or inclined to the angle splitting shaft, on the outer peripheral surface of the processing material of the turned polygon mirror.

Description

Polygon mirror and working method of the same

1 is a trial of the optical scanning device showing schematically the state of use of the polygon mirror,

2 is a partially cutaway perspective view of a polygon mirror having an inclined mirror surface processed by the polygon mirror processing method according to the present invention;

3 is a perspective view showing another embodiment of a polygon mirror processed by another processing method according to the present invention;

4 is a block diagram showing a processing method of a polygon mirror according to the present invention;

5 is a perspective view schematically showing an apparatus for implementing a method of processing a polygon mirror;

The present invention relates to a polygon mirror and a method of manufacturing the same, and more particularly to a polygon mirror having an inclined mirror surface and a method of manufacturing the same.

Scanning optical apparatuses are widely used in image recording apparatuses, such as laser beam printers (LBPs), which print images on printing paper such as copiers, printers, and facsimiles. Such scanning optical apparatuses are disclosed in US Patent Nos. 5,128,795, 5,162,938, 5,329,399, 5,710,654, 5,757,533, 5,619,362, 5,721,631, 5,553,729, 5,111,219, 5,995,131 and the like.

The majority of the optical scanning device uses a polygon mirror of four, six, eight, or sixteen surfaces rotating at high speed (for example, 4000 / min).

Such a polygon mirror has a mirror body having a plurality of rectangular mirror surfaces, and is used as an optical deflector for deflecting a light beam in a scanning optical device. This polygon mirror is rotated at a constant speed by driving means such as a motor during the image forming operation. The scanning optical apparatus scans the light beam in the scanning direction on the scan surface by rotating the polygon mirror, thereby performing image recording on the photosensitive drum.

The above-mentioned polygon mirror is a sub-micron precision and reflectance, which is a high-precision workpiece, difficult to manage the production process, and a high-precision machining process using high-purity aluminum, which has a long processing time, high production price, high production cost, and a huge facility investment. Supply is in short supply compared to demand.

In order to solve this problem, a method of manufacturing a polygon mirror by making a mirror mirror on the surface after making the shape of the polygon mirror by a plastic molding method, a press working method, a die casting method, etc. is continuously made.

However, when the polygon mirror is molded from a plastic material, the surface precision of the polygon mirror cannot be satisfied due to the amount of deformation appearing after shrinking. Therefore, a method of mixing the spherical ceramic particles in a plastic material and molding the same so as to maintain the shape by the ceramic particles during plastic shrinkage has been proposed. (JP-A 01-113718) However, when using spherical ceramic particles as described above, the dimensional accuracy and the shape precision can be satisfied. However, when rotating at a high speed of about 40,000 rpm, the tensile load generated by the rotational force is envisioned. Cannot accommodate ceramic particles. In particular, since the tensile strength of the polymer acting as a binder is too low to withstand the tensile strength generated from the rotational force, such a polygon mirror has a problem that it should be used only when the rotation is 20,000 rpm or less.

Therefore, research is continuously conducted to improve productivity according to the ultra-precision processing of structurally stable high-purity aluminum to increase the processing efficiency of the polygon mirror, and the applicant also filed an application as a result of studying such a processing method. Reached.

The present invention is to solve the problems as described above, it is an object of the present invention to increase the processing efficiency of mirror surfaces by using a high purity aluminum, and to provide a method of processing a polygon mirror that can be processed inclined mirror surface.

Another object of the present invention is to provide a polygon mirror capable of controlling the processing angle of the inclined surface and widening the scanning width of the beam.

In order to achieve the above object, the polygon mirror processing method of the present invention, the material processing step of forming a through-hole in the center of the workpiece material of the polygon mirror,

A material fixing step of clamping the workpiece by using a through hole formed in the workpiece on an angle division axis capable of angle division;

A reference mirror machining step of forming a reference mirror surface inclined at a predetermined angle parallel to or parallel to the angle division axis on the outer peripheral surface of the workpiece of the polygon mirror using a fly cutter installed on a main shaft capable of three-axis control;

A material rotation step of rotating the workpiece of the polygon mirror at a predetermined angle with respect to the reference mirror surface;

It characterized in that it comprises a mirror surface processing step of processing a parallel or inclined mirror surface with respect to each angle division axis on the outer peripheral surface of the workpiece of the rotated polygon mirror.

In the present invention, in the reference mirror surface processing step and the mirror surface processing step, the feed trajectory of the main shaft provided with the fly cutter is composed of a repeat of the vertical transfer step and the horizontal transfer step that is vertically transferred relative to the angle division axis.

Polygon mirror for achieving the above object is characterized in that it is provided with a main body with a stepped through hole formed in the center, and a plurality of inclined mirror surface inclined with respect to the central axis of the through hole on the outer peripheral surface of the main body.

In the present invention, the inclined mirror surface continuously formed on the outer peripheral surface of the main body is preferably made of 16.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, the polygon mirror 10 is used for the scanning optical device 20 or the like. The polygon mirror 10 is installed in the rotating motor 21 and scans a beam scanned from the laser generating means 22 on the scan surface in the scanning direction. Scanning results in the image recording on the photosensitive drum 23.

2 and 3, the polygon mirror 10 has a stepped through hole 12 formed in the center of the main body 11, and the outer circumferential surface of the main body 11 is shown in FIG. 2. Likewise, a plurality of inclined mirror surfaces 12 inclined with respect to the central axis c of the through holes 12 are formed or mirror surfaces 14 parallel to the central axis c of the through holes 12 as shown in FIG. 3. ) Is formed. The inclined mirror surface 13 or the mirror surface 14 may vary depending on the device in which the polygon mirror 10 is installed, but preferably 16 inclined surfaces are formed. Here, it is preferable to widen the scanning width by making the angle of the inclined mirror surface different from the inclined direction differently.

The processing method of the polygon mirror according to the present invention configured as described above with reference to Figures 4 and 5 as follows.

In order to process the polygon mirror according to the present invention, the material processing step 101 of processing the raw material for processing the polygon mirror is performed. This work step 101 is to cut the plate-shaped material in a circular shape and then rough the outer peripheral surface, and machine the upper and lower surfaces to have the same thickness. And the step of forming a stepped through hole in the center.

When the material processing step is completed as described above performs a material fixing step of fixing the material to the dedicated device for processing the material. The material fixing step 102 separates the clamp 32 provided at the end of the angle division shaft 31 capable of angle division, and supports the through-hole of the workpiece 15 on the angle division shaft 31. By clamping, the center of the processing material 15 of the polygon mirror and the center of the through-hole are fixed. At this time, the fixing of the workpiece 15 is not limited to the above embodiment and may be any structure as long as the angle division shaft 31 can match the center of the through hole.

When the mounting of the polygon mirror workpiece 15 is completed as described above, the angle dividing shaft 22 is formed on the outer circumferential surface of the workpiece 15 using the fly cutter 34 installed on the main shaft 33 capable of three-axis control. Reference mirror surface forming step 103 of forming a reference mirror surface parallel to or inclined at a predetermined angle with respect to.

The material rotation step 104 is performed to rotate the workpiece of the polygon mirror at a predetermined angle with respect to the reference mirror surface, and this material rotation step 104 is a predetermined angle, that is, using the angle division axis 31. Rotate by the angle divided by the number of mirror surfaces to be formed on the outer surface.

In this state, the processed mirror material 15 of the polygon mirror rotated by using the ply cutter 34 performs a mirror processing step 105 to process the mirror surface parallel or inclined with respect to the angle division axis 31.

On the other hand, in the reference mirror surface processing step 104 and the mirror surface processing step 105, the feed trajectory of the main shaft in which the fly cutter is installed is a repetition of the vertical transfer step and the horizontal transfer step that are vertically fed with respect to the angle division axis. But is not limited thereto.

 When the process as described above is completed, the polygon mirror is separated from the angular division axis and cleaned.

As described above, the polygon mirror according to the present invention can extend the scanning range of the beam. In particular, its processing method can be mass-produced by ultra-precision machining using aluminum material, which can reduce the production cost, and the distance from the center of the polygon mirror to each inclined surface can be processed uniformly, thereby reducing errors due to light reflection. Can be.

 Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent embodiments are possible.

Therefore, the true scope of protection of the present invention should be defined only by the appended claims.

Claims (3)

A material processing step of forming a through hole in the center of the workpiece of the polygon mirror; A material fixing step of clamping the workpiece by using a through hole formed in the workpiece on an angle division axis capable of angle division; A reference mirror machining step of forming a reference mirror surface parallel or inclined at a predetermined angle with respect to the angle division axis on the outer circumferential surface of the polygon mirror processing material using a fly cutter installed on a main axis capable of three-axis control; A material rotation step of rotating the workpiece of the polygon mirror at a predetermined angle with respect to the reference mirror surface; And a mirror surface processing step of processing a mirror surface parallel or inclined with respect to each angular division axis on the outer circumferential surface of the workpiece of the rotated polygon mirror. The method of claim 1, The reference mirror surface processing step and the mirror surface processing step is a polygon mirror processing method comprising a vertical transfer step and a horizontal transfer step of vertically transferring the feed trajectory of the main shaft in which the fly cutter is installed.   A polygon mirror comprising: a main body having a stepped through hole formed in a central portion thereof, and a plurality of inclined mirror surfaces having different inclined directions and angles with respect to a central axis of the through hole on an outer circumferential surface of the main body.

Images