JP2000019438A - Scanner - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a scanner capable of decreasing the deviation of the joint part of respective scanning loci more with a simple constitution in the case of scanning by plural scanning units. SOLUTION: This scanner 1 is constituted of plural scanning units 2 and 2 respectively performing scanning with beams, and the scanning units 2 and 2 are arranged in a main scanning direction. The main scanning direction of the scanning units 2 and 2 is orthogonal to a subscanning direction. Furthermore, the scanning line of the scanning units 2 and 2 is set to deviate in the subscanning direction by the 1/2 pitch of a feed amount in the subscanning direction in arranging order alternately.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a scanning device, and more particularly, to a scanning device which divides a scanning area and scans by a plurality of scanning units. The present invention relates to a scanning device that can further reduce the displacement of a connecting portion of a scanning trajectory.

[0002]

2. Description of the Related Art A scanning device provided in a laser printer, a plate making device, or the like is a device that scans a laser beam for exposure and exposure to form a digital image on a medium. Such a scanning device is configured by arranging a plurality of scanning units each scanning a beam in the main scanning direction in order to scan an exposure surface having a relatively large width. In a scanning device composed of a plurality of units, it is important to smoothly continue the scanning trajectory on the exposure surface by each scanning unit in order to prevent image displacement.

For example, Japanese Patent Application Laid-Open No. 9-5655 discloses that
By using a detector composed of four photodiodes (quad land diodes) as deviation determining means, detecting the deviation between a preset scanning line and an actual scanning line and controlling the rotation of the deflecting polygon mirror,
Subsequently, the scanning line in the scanning unit at the subsequent stage for scanning is corrected, and a plurality of scanning trajectories in the width direction on the exposure surface are continued without interruption, that is, the displacement of the connecting portion of the scanning trajectories between the scanning units is minimized. A technique for a scanning device is disclosed.

[0004]

However, in the scanning apparatus of the system described in the above publication, the rotation fluctuation of the front-stage polygon mirror is complemented by the rotation control of the rear-stage polygon mirror. High stability of the rotation of the polygon mirror and high tracking accuracy of the rotation control are required. Therefore, there is also a problem that the control mechanism including the circuit becomes more complicated and the manufacturing cost increases.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and has as its object to provide a scanning device which divides a scanning area and scans with a plurality of scanning units. It is an object of the present invention to provide a scanning device capable of further reducing the displacement of the connecting portion of the scanning trajectory in the above.

[0006]

In order to solve the above-mentioned problems, a scanning apparatus according to the present invention comprises a plurality of scanning units each of which scans a beam, and these scanning units are arranged in the main scanning direction. In the scanning device, the main scanning direction is orthogonal to the sub-scanning direction, and the scanning lines of each scanning unit are alternately shifted in the sub-scanning direction by 配 列 pitch of the feed amount in the sub-scanning direction in the arrangement order. It is set in a state in which

That is, in the above-described scanning apparatus, a plurality of scanning units divide a surface to be scanned into a plurality of scanning ranges and perform beam scanning. Then, for example, when the beam is scanned while moving the surface to be scanned by a predetermined feed amount, the relationship of the scanning lines between the scanning units set to a specific state is the same period formed by each scanning line. The scanning trajectory is made continuous in a straight line.

[0008]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of a scanning device according to the present invention will be described with reference to the drawings. FIG. 1 is a conceptual diagram schematically showing an arrangement of scanning units and a scanning state in the scanning device of the present invention. FIG. 2 is a conceptual diagram schematically showing a scanning state when six scanning units are arranged. 3 and 4 are a plan view and a side view, respectively, showing the components of the scanning unit.

The scanning device of the present invention is indicated by reference numeral (1) in the drawing, and is used as a reading device or a photosensitive / exposure device in an image processing device such as a laser printer or a plate making device, similarly to a known scanning device. Optical device used.
As shown in FIG. 3, the scanning device (1) includes a plurality of scanning units each scanning a beam, for example, two scanning units (2), and these scanning units (2) are
They are arranged along the main scanning direction of the beam.

As shown in FIGS. 3 and 4, each scanning unit (2) generally includes a light source (21) and a collimating lens (2).
2), polygon mirror (23), f · θ lens (2
4), constituted by optical components such as mirrors (27) and (25) and a cylindrical lens (26) and a control circuit (29) arranged in the optical path, and for a scanning surface (3) of a medium such as a photoconductor. Scans the beam linearly in a constant scanning range (R).

As the light source (21), a laser light source having an emission spectrum from ultraviolet to visible wavelengths, for example, a semiconductor laser, an argon ion laser, a He-
A light source such as a Ne laser or a He-Cd laser is used. In particular, an argon ion laser or a semiconductor laser is excellent in terms of stability, life, and cost. Light source (2
The beam diameter irradiated from 1) is about 5 to 50 μm on the surface to be scanned (3), and the beam feed amount (scanning pitch) depends on the setting of the relative feed speed between the scanning device (2) and the surface to be scanned (3). It is about 5 to 50 μm.

As shown in FIG. 3, the scanning device (2) includes an optical modulator (not shown) for modulating light emitted from the light source (21) according to image information, and an optical semiconductor such as a photodiode. And an origin detector (28b) comprising an origin mirror (28b) via an origin mirror (28a).
The light intensity signal of the beam at the starting point incident on b) is output.

The control circuit (29) has a function of controlling the light emission of the light source (21) and the driving of the polygon mirror (23), and also determines the starting point of the beam by the output signal of the origin detector (28b). It has a detector circuit for detecting and has a function of controlling the optical modulator. That is, in the scanning device (2), the control circuit (29) scans the beam emitted from the light source (21) linearly through the above-described series of optical components in a constant scanning range (R),
Also, the modulation timing of the optical modulator is controlled based on the beam signal at the scanning start point detected by the origin detector (28b).

In the scanning device (1) of the present invention, FIG.
As shown in (1), in order to scan the scanning surface (3) having a large width, the two scanning units (2a, 2b) are arranged along the main scanning direction of the beam as described above, and the scanning surface (3) is scanned. )
Is divided and scanned. In the present invention, the main scanning direction refers to the direction in which the scanning line extends, that is, the actual scanning direction of one scanning beam (the direction of the moving trajectory). The direction of the relative feeding operation between the scanning device (2) and the surface to be scanned (3) is referred to as a sub-scanning direction. The image line on the surface to be scanned (3) formed by the beam scanning with the relative feed operation is referred to as a scanning locus.

In the above-described scanning device (1), the main scanning direction is orthogonal to the sub-scanning direction, and the scanning lines of each scanning unit (2) are arranged in the order of arrangement and alternately in the sub-scanning direction. It is set to be shifted in the sub-scanning direction by ピ ッ チ pitch. Specifically, as shown in FIG. 1, an n-th scanning line (shown by a broken line) of the scanning unit (2a)
The scanning unit (2b) is parallel to the n-th scanning line (shown by a broken line) and is shifted by a half pitch of the feed amount (a distance shown by a symbol (P) in the drawing). . In the figure, an upward white arrow on the surface to be scanned (3) indicates the moving direction of the medium.

The scanning unit (2a) and the scanning unit (2
The reason for setting the shift amount of the scan line in b) to 1/2 pitch of the feed amount is as follows. That is, the scanning line is formed by the rotational deflection of the peripheral surface (reflection surface) of the polygon mirror (23) shown in FIG. 3, and the feed pitch is set by replacing the six reflection surfaces. In each of the reflection surfaces described in (1), about 60% of the total area is an effective reflection surface that can be actually used due to problems such as manufacturing accuracy and design accuracy of the interior angle of the hexagon.

Therefore, usually, 50% of each reflecting surface is used as an effective reflecting surface, and each scanning unit (2) shown in FIG.
a, 2b) is one scan line of one reflecting surface.
It is formed by two rotation deflection operations. Therefore, by setting the above-mentioned shift amount to ピ ッ チ pitch of the feed amount,
The end of the scanning trajectory of the scanning unit (2a) can coincide with the beginning of the scanning trajectory of the scanning unit (2b) on the downstream side in the main scanning direction.

The shift of the scanning line may be set either on the upstream side or on the downstream side in the sub-scanning direction. In a preferred embodiment of the present invention, processing of control data (image data) for modulating a beam is performed. In order to facilitate the above, the shift of the scanning line between the scanning units (2, 2) is set to a specific state. That is, when the scanning unit (2) located on the most upstream side in the main scanning direction is used as a reference, the scanning lines of the 2j-th (where j = 1, 2,...) Scanning unit (2) have a half pitch. The scanning units (2a) and (2) shown in FIG.
b) relationship).

In the scanning device (1) of the present invention, FIG.
As shown in the figure, for example, the scanning units (2a) and (2
According to b), the beam scanning is performed by dividing the width direction of the surface to be scanned (3) into two scanning ranges (R). Each scanning unit (2
a, 2b) scans the modulated beams in parallel based on image data input in parallel.
When the beam is scanned while moving the surface to be scanned (3) by a predetermined feed amount, the relationship of the scanning lines between the scanning units (2a, 2b) set in a specific state as described above is as follows. For example, scanning trajectories (indicated by solid lines) having the N-th data formed by, for example, the n-th scanning line of the unit (2a, 2b) and having the same period are continuously formed in a straight line.

That is, the scanning device (1) of the present invention does not need to perform complicated control in order to prevent the deviation between the scanning lines, and simply sets the scanning lines to be shifted to a specific state in advance. Depending on the configuration, each scanning unit (2,
The deviation of the connecting portion of the scanning trajectory between 2) can be further reduced, and accurate scanning can be performed.

The scanning apparatus of the present invention has three or more, for example, six scanning units (reference numerals (2a to 2f) in FIG. 2).
) Can be arranged. In a scanning device including six scanning units, as shown in FIG. 2, the scanning lines of each scanning unit are set in the same state as in FIG.

In the above-described scanning device, a continuous scanning trajectory having the same cycle is formed for each pair of adjacent scanning units. The scanning unit (2a, 2b), for example, makes the scanning trajectory of the cycle having the Nth data line continuous by the nth scanning line (shown by a broken line), and the scanning unit (2c, 2d) The scanning trajectory having the period having the first data is made continuous in a straight line, and the scanning unit (2e, 2f) makes the scanning trajectory having the period of (N−2) th data be made continuous in a straight line.

That is, in the scanning line scanning apparatus shown in FIG. 2, the scanning unit (2a, 2b) on the most upstream side in the main scanning direction is compared with the scanning unit (2
Each set of (c, 2d) and (2e, 2f) sequentially scans a beam with a delayed cycle, so that scanning without deviation between the scanning units (2a to 2f) is performed similarly to the above-described embodiment. A trajectory can be formed.

[0024]

According to the scanning apparatus of the present invention, a simple configuration in which a scanning line is shifted to a specific state in advance can be used in an apparatus including a plurality of scanning units without performing complicated control. It is possible to further reduce the displacement of the connecting portion of the scanning trajectory between the scanning units.

[Brief description of the drawings]

FIG. 1 is a conceptual diagram schematically showing the arrangement and scanning state of a scanning unit in a scanning device according to the present invention.

FIG. 2 is a conceptual diagram schematically showing a scanning state when six scanning units are arranged.

FIG. 3 is a plan view showing components of a scanning unit.

FIG. 4 is a side view showing components of the scanning unit.

[Explanation of symbols]

 1: scanning device 2: scanning unit 21: light source 23: polygon mirror 24: f · θ lens 28a: origin mirror 28b: origin detector 29: control circuit 3: scanning surface R: scanning range

Claims (2)

[Claims] 1. A scanning device comprising a plurality of scanning units each of which scans a beam, and wherein these scanning units are arranged along the main scanning direction, wherein the main scanning direction is orthogonal to the sub-scanning direction, and A scanning apparatus, wherein the scanning lines of each scanning unit are set in the arrangement order and alternately shifted in the sub-scanning direction by ピ ッ チ pitch of the feed amount in the sub-scanning direction. 2. When the scanning unit located on the most upstream side in the main scanning direction is used as a reference, a 2j-th scanning unit (where j = 1, 2)
2. The scanning apparatus according to claim 1, wherein the scanning lines of the scanning unit are shifted to the downstream side in the sub-scanning direction by ピ ッ チ pitch.