KR20060111141A - Multi-beam laser scanning apparatus and method thereof - Google Patents

Abstract

A multi-beam scanning device and a scanning method therefor are provided to reduce the number of lasers by using a single laser, save unit cost by the reduction of optical elements, and increase the efficiency of a laser beam. An LD(Laser Diode)(110) emits single light. An optical unit(120) shapes the light emitted from the LD(110) as a certain shape. HOE(Holographic Optical Elements)(130) spread the light shaped in the optical unit(120) as a certain pattern. A switching unit(140) selectively transmits the light spread in the HOE(130). An LCD(Liquid Crystal Display) control unit(150) controls the switching unit(140) so that the switching unit(140) selectively transmits the spread light according to an image to be outputted.

Description

Multi-beam Laser Scanning Apparatus and Method

1 is a view showing a multi-beam scanning apparatus using four semiconductor lasers according to the prior art,

2 is a view showing a one-can multi-beam scanning apparatus according to the prior art,

3 is a view showing a multi-beam scanning apparatus using an optical element according to the prior art, and

4 is a view showing a multi-beam scanning apparatus according to the present invention.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical scanning device and a scanning method used in an image forming apparatus, and more particularly, to multi-beam scanning using a polymer HOE that can adjust the pitch and output angle of a laser beam from one beam light source. It relates to an apparatus and an injection method.

The optical scanning device used in the clazziquai image forming apparatus mainly uses a method of scanning a beam on a photoconductor by deflecting a laser beam with an optical deflector and passing it through a lens. The above scan is a main scan, and after performing one main scan, subscanning is performed by moving or rotating the photosensitive surface a predetermined distance, and during this process, a laser beam is modulated to form an electrostatic latent image on the photosensitive member.

 In the optical scanning device, a method of simultaneously scanning a plurality of lines using a plurality of laser beams is performed as a means of speeding up an image, which is called a multi-beam scanning device or a multi-beam scanning optical system.

1 is a view showing a multi-beam scanning apparatus using four semiconductor lasers according to the prior art. In order to configure the light source device of the multi-beam scanning apparatus, conventionally, a plurality of semiconductor lasers 10, a lens 20 corresponding to each semiconductor laser, and a beam that passes through the lens are synthesized and output at predetermined intervals. Means 30 were used.

The multi-beam scanning apparatus simultaneously deflects the beams emitted from the plurality of semiconductor lasers 10 on the deflective reflecting surface 40 to form a plurality of beam spots on the scanned surface (not shown) to simultaneously scan a plurality of printed lines. . Conventional semiconductor laser 10 has a light emitting portion in a metal can or case, and it is common to emit one laser beam from one metal can, which is also inexpensive.

When the semiconductor laser 10 is used, the spacing between the plurality of beam spots on the scan surface (not shown) is minute, but the spacing between the semiconductor lasers 10 is very large compared to the spot spacing, so that the plurality of semiconductor lasers 10 In addition to the lens 20 corresponding to each semiconductor laser 10, a beam synthesizing means 30 for synthesizing a beam passing through each lens and outputting it at a predetermined distance or angle is used.

However, when four semiconductor lasers 10 are used as shown in FIG. 1, the angle of incidence is easily controlled, but the volume of the four lasers 10 increases, and the manufacturing cost increases.

In order to solve this problem, as a multi-beam light source of a color or monochrome laser image forming apparatus, a semiconductor laser that allows a plurality of beams to be scanned from one laser is used.

2 is a view showing a one-can multi-beam scanning apparatus according to the prior art. However, as shown in FIG. 2, a laser that emits two or more beams from each one laser 50 has a problem in that the price of the laser 50 is high and the angle of incidence is difficult to adjust.

In order to solve this problem, optical devices have been used since the multi-beam scanning apparatus.

3 is a view showing a multi-beam scanning apparatus using an optical element according to the prior art. The multi-beam scanning apparatus using the optical element has an advantage that the angle of incidence can be easily adjusted by the optical element. However, as shown in FIG. 3, the light efficiency is reduced in the step of passing each element in the process of using a plurality of optical elements. As the distance becomes longer, there is a problem that the system becomes larger.

Accordingly, an object of the present invention is to provide a multi-beam scanning apparatus and scanning method using a polymer HOE that can adjust the pitch and output angle of a laser beam from one beam light source.

Multi-beam scanning apparatus according to the present invention for achieving the above object, the light generating unit for emitting a single light, an optical unit for shaping the light emitted from the light generating unit in a predetermined form, A diffusion unit for diffusing the light in a predetermined pattern, a switching unit for selectively transmitting the light diffused in the diffusion unit, and a control unit for controlling the switching unit to selectively transmit the diffused light according to an image image to be outputted Characterized in that it comprises a.

Preferably, the diffusion unit is a holographic optical device (HOE). In addition, the holographic optical device (HOE) is characterized in that made of a polymer (Polymer). In addition, the switching unit is characterized in that consisting of the LCD shutter.

On the other hand, the multi-beam scanning method according to the present invention for achieving the above object, the step of emitting a single light, shaping the emitted light in a predetermined form, to diffuse the shaped light in a predetermined pattern And selectively transmitting the diffused light according to the image image to be output.

Hereinafter, with reference to the drawings will be described the present invention in more detail.

4 is a view showing a multi-beam scanning apparatus according to the present invention. The multi-beam scanning apparatus according to the present invention includes a light generator 110, an optical unit 120, a diffuser 130, a switching unit 140, and a controller 50.

The light generating unit 110 is composed of a laser diode and emits a single light, and the optical unit 120 converts the light emitted from the laser diode which is the above-described light generating unit 110 into a predetermined form such as parallel light. Format. The diffusion unit 130 diffuses the laser light passing through the above-described optical unit in a predetermined pattern, and the switching unit 140 is installed in the path of the light diffused by the diffusion unit 130 described above and requires output. The laser light is selectively transmitted by being turned on and off according to the image image.

In addition, the controller 150 controls ON / OFF of the above-described switching unit according to a signal from an input unit (not shown). Here, the laser diode should be composed of a laser diode having a high output in view of the output reduction by beam separation. In addition, the diffusion unit 130 is composed of holographic optical elements (HOE).

A holographic optical device is a general name called when using a hologram as an optical device, and is an optical device manufactured to obtain a desired waveform by reproducing or modifying a waveform recorded in the hologram. The holographic optical device has a diffraction grating structure having a well-defined fringe spacing, although the pattern spacing is not uniform because it records and manufactures an interference fringe formed by several beams.

Therefore, the holographic optical element is a diffractive optical element that operates according to the diffraction law, not the reflection or refraction law, and the most representative diffractive element is the holographic diffraction grating. A holographic lens or a holographic luminous flux splitter is a diffractive element, but functionally functions as a refractive or reflective element just like conventional lenses and luminous splitters. Therefore, the holographic optical element can obtain multifunction as one holographic optical element.

For example, one device may serve as a lens, a beam splitter, and an interference filter. In addition, conventional optical devices are difficult to manufacture because they are obtained through surface processing, but holographic optical devices can be obtained by recording them on photosensitive materials in the same way as photography. Because it operates according to the diffraction law, it can be used only in the narrow bandwidth region.

Due to the characteristics of such holographic optical devices, they are applied to many fields such as optical information processing, ultrafast signal processing, optical computing devices, optical integrated circuits, and optical interconnections. HOE is divided into flat type and volume type. The flat type has low efficiency because the incident light is diffracted in several directions, while the volume type has high diffraction efficiency because the incident light is diffracted only in one direction. In the planar type, the diffraction efficiency does not change significantly when the incident angle is changed, but in the volume type, the diffraction phenomenon does not occur because the diffraction efficiency changes significantly even if the incident angle is slightly changed.

The most widely used materials for holographic optical devices are dichromated gelatin, silver-halide emulsion, and photoresist, and new phase materials are being studied. Recently, many non-linear holographic recording materials such as photopolymer, LiNbO3, BSO, and the like have been applied.

In general, holographic optical devices are widely used in place of conventional optical devices in a system using a narrow wavelength bandwidth or monochromatic light such as a laser or LED as a light source. The HOE (Holographic Optical Elements) uses a device made of a polymer material according to the present invention. Accordingly, by recording a desired beam pattern in advance, the angle and number of beams by the pattern can be made.

On the other hand, the switch 140 is composed of an LCD shutter. Each of the separated laser beams is exposed to the OPC with image data through the same configuration (not shown) as in a conventional scanning apparatus.

4, the operation of the multi-beam scanning apparatus according to the present invention, first, when the power is supplied to the light generator 110 by a laser diode light emitting device (not shown), the light generator 110 is continuous The emitted laser beam. The laser light is shaped into parallel light through the optical unit 120 and then passes through the diffusion unit 130.

Here, the diffusion unit 130 is composed of the above-described holographic optical element (HOE), and the laser light passes through the diffusion unit 130 made of the holographic optical element (HOE), to the holographic optical element (HOE). By the pre-recorded pattern, two or four or more beams are separated according to a predetermined angle. Each beam passes through the switching unit 140 and is selectively transmitted or blocked through the on / off process of the LCD shutter used as the switching unit 140. Here, the ON / OFF of the LCD shutter which is the switching unit 140 is controlled by the controller 150. The controller 150 controls the ON / OFF of the switching unit 140 based on the data for the image to be output to the input unit (not shown). Here, the controller 150 may be an LCD controller.

After that, the laser light passing through the LCD shutter, which is the switching unit 140, is reflected on the polygon mirror surface (not shown) through the conventional optical system, and then passes through the F? Lens (not shown), and then is uniformly scanned on each photosensitive drum (not shown). do. The scanning light passes through the F? Lens (not shown) according to the purpose, and is then reflected by the reflection mirror (not shown) to reach the photosensitive drum (not shown).

As described above, according to the present invention, the use of a single laser has the effect of reducing the number of lasers, reducing the unit cost by reducing optical elements, increasing the efficiency of laser light, and adjusting the angle of the output beam as desired. This makes it possible to design simpler and free multi-beam scanning apparatus.

In addition, while the above has been shown and described with respect to preferred embodiments and applications of the present invention, the present invention is not limited to the specific embodiments and applications described above, without departing from the gist of the invention claimed in the claims Various modifications may be made by those skilled in the art to which the present invention pertains, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

Claims (5)

A light generator for emitting a single light; An optical unit for shaping the light emitted from the light generating unit into a predetermined form; A diffusion unit for diffusing the light shaped by the optical unit into a predetermined pattern; A switching unit for selectively transmitting the light diffused in the diffusion unit; And And a control unit which controls the switching unit to selectively transmit the diffused light according to an image image to be output. The method of claim 1, And the diffusion unit is a holographic optical element (HOE). The method of claim 2, The holographic optical device (HOE) is a multi-beam scanning device, characterized in that made of a polymer (Polymer). The method of claim 1, The switching unit is a multi-beam scanning device, characterized in that consisting of an LCD shutter. Emitting a single light; Shaping the emitted light into a predetermined form; Diffusing the shaped light in a predetermined pattern; And And selectively transmitting the diffused light according to an image image to be output.

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