KR100419219B1 - Printer and scanning unit thereof - Google Patents

Abstract

A printer having a scanning device applicable to a scanning direction of an original is disclosed. The printer includes a light source for emitting light corresponding to the image information, a scanning mirror capable of bidirectional rotation, rotating in a predetermined direction to form light corresponding to the image information on the photosensitive drum, and image information imaging on the photosensitive drum. A first and second synchronous detection unit for detecting a synchronous signal indicating a start position of the light source, and a light source controller for controlling the light source to detect the synchronous signal in any one of the first and second synchronous detection units corresponding to the rotational direction of the scanning mirror. Have Therefore, it is possible to apply to any printer regardless of the scanning direction of the document, thereby reducing the development period and development cost of the scanning device.

Description

Printers and scanning devices thereof

The present invention relates to a scanning device of a printer, and more particularly, to a printer having a scanning device applicable to a scanning direction of an original.

In general, a laser printer is an apparatus for reproducing an image image by imaging a laser light emitted from a laser diode corresponding to the image information on a photosensitive drum and transferring the image information formed on the photosensitive drum onto a medium such as paper.

A laser scanning device that generates laser light in such a laser printer and forms the laser light on a photosensitive drum is configured as shown in FIG.

Laser diode 100 for emitting laser light used as a light source, collimator lens 101 for making the laser light emitted from the laser diode into parallel light or convergent light with respect to the optical axis, laser light passing through the collimator lens 101 The polygon mirror 103 for scanning by moving the beam at an isotropic speed in the horizontal direction, and the cylindrical lens 102 and the polygon mirror 103 for forming the laser light linearly in a horizontal direction on the surface of the polygon mirror 103 at an isotropic speed. Rotating polygon mirror driving motor 104, Fθ lens having a constant refractive index with respect to the optical axis and focusing on the scanning surface by polarizing light at an isotropic velocity reflected from the polygon mirror 103 in the juice canning direction and correcting aberration ( 105) an imaging reflection mirror 106 and a laser beam for reflecting a laser beam through the F? Lens 105 in a predetermined direction to form an image on a photosensitive drum 107 as an imaging plane Receiving and consists of a light sensor 109, a synchronization detection sync signal detected reflection mirror 108 for which reflects the laser beam toward an optical sensor for a period according to the horizontal synchronization.

These parts are typically assembled on one frame to constitute a scanning device.

The operation of the conventional laser printer having the above configuration is as follows.

First, an image signal to be printed is applied to the laser diode 100 by a light source control device (not shown), and the laser diode is turned on / off according to the image signal.

In addition, the laser light emitted from the laser diode 100 is scanned by the polygon mirror 103 in the main scanning direction parallel to the plane of rotation of the polygon mirror 103. This scanned laser light is, of course, formed into a size defined on the photosensitive drum 107 by the F? Lens 105.

When the main scanning scan of one line is completed, the photosensitive drum is rotated at a predetermined speed, and the main scanning scan of the next line is performed at a distance separated by a given resolution on the surface of the photosensitive drum.

This process is repeated until printing of the image signal is completed. At this time, the start position of the image formed on the photosensitive drum 107 is matched in the sub-scanning direction by the synchronization signal, and the synchronization signal is detected by the synchronization detection sensor 109 before the image area scanning is started.

In the above configuration, the polygon mirror 103 is rotated in a predetermined direction clockwise or counterclockwise according to the prescribed scanning direction of the document. At this time, the optical design is performed such that the scan direction is rotated only on one side.

Since the scanning direction of the above-described structure is defined by only one side, the scanning apparatus as described above cannot be used if the original scanning direction is the opposite of the scanning direction of the scanning apparatus. In this case, the scanning apparatus must be mounted upside down on the image forming apparatus, or a frame of the scanning apparatus must be newly manufactured.

In the case of mounting the scanning apparatus upside down, there was a problem that the rotation of the polygon mirror 103 is unstable and the quality is deteriorated, and when the frame is newly manufactured, there is a problem that additional manufacturing cost is required.

An object of the present invention for solving the above problems is to provide a printer having a scanning device that can shorten the development period and reduce the development cost by using a scanning device irrespective of the scanning direction of the document.

1 is a view showing a scanning device of a conventional laser printer;

2 shows a scanning device of a laser printer according to the present invention, and

3 is a synchronous detection timing diagram according to FIG. 2.

Explanation of symbols on the main parts of the drawings

100: laser diode 106: reflecting mirror for imaging

107: photosensitive drum 203: polygon mirror

205: Fθ lens 208: second reflecting mirror

218: half mirror 209: synchronous detection sensor

A printer according to the present invention for achieving the above object, the light source for emitting light corresponding to the image information to be printed; A scanning mirror capable of bidirectional rotation and forming an image on the photosensitive drum corresponding to the image information while rotating in a predetermined direction; First and second synchronization detecting means for detecting a synchronization signal indicating a start position of image information formed on the photosensitive drum; And a light source control unit controlling the light source to detect the synchronization signal in any one of the first and second synchronization detecting means corresponding to the rotation direction of the scanning mirror.

On the other hand, the first synchronous detection means has a synchronous detection sensor and a first reflection mirror for reflecting the light reflected from the scanning mirror to the synchronous detection sensor; The second synchronous detecting means may include the synchronous detection sensor, a second reflecting mirror reflecting light reflected from the scanning mirror to the first reflecting mirror, and the light reflected from the second reflecting mirror to the synchronous detecting sensor. And a first reflecting mirror to reflect.

Therefore, it is possible to apply in any frame regardless of the scanning direction of the document.

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

In the present embodiment, a laser printer having the scanning apparatus of the present invention will be described as an example. The same components as those in Fig. 1 are assigned the same numbers, and detailed descriptions of the operations of the same components will be omitted.

As shown in FIGS. 1 and 2, the scanning device of the laser printer includes a laser diode 100, a light source control unit (not shown), a focusing lens unit 101, 102, a scanning mirror 203, and an imaging lens 205. ), A synchronization detector, an imaging reflecting mirror 106, a photosensitive drum 107, and the like.

The laser diode 100 emits laser light in response to an image signal of a scanned original by a laser diode controller (not shown).

The focusing lens generally converts the laser light emitted from the laser diode 100 into parallel light and converging light with respect to the optical axis, and transmits the laser light passing through the collimator lens 101 and the collimator lens 101 of the scanning mirror 203. A cylindrical lens 102 is formed on the surface in a horizontal linear form.

The scanning mirror, that is, the polygon mirror 203, is a polygon having a plurality of planes arranged perpendicularly to the rotational direction and reflects the laser light in a predetermined direction so that one line on the photosensitive drum is rotated at a predetermined angle. Record image information. The driving motor 104 rotates the polygon mirror 203 at an isotropic speed, and a motor controller (not shown) controls the rotation direction of the driving motor.

The light at an isotropic velocity reflected from the polygon mirror 203 through the imaging lens, ie, the F? Lens 105, is refracted in the main scanning direction and corrected for aberration to form an image on the photosensitive drum 107.

The synchronous detection unit has a first synchronous detection unit and a second synchronous detection unit.

When the rotation direction of the scanning mirror 203 rotates clockwise as shown in FIG. 2, the first synchronization detectors 218 and 209 detect the synchronization signal. That is, the laser light emitted from the laser diode 100 is incident on the half mirror 218 through the predetermined imaging lens 211, and the laser light incident on the half mirror 218 is dependent on the characteristics of the half mirror 218. Accordingly, 50% of the incident light is reflected and incident on the synchronous detection sensor 209 to detect the synchronous signal.

On the contrary, when the rotation direction of the scanning mirror 203 is counterclockwise, the second synchronization detector detects the synchronization signal. That is, the laser light incident on the polygon mirror 203 through the Fθ lens 205 is reflected by the reflection mirror 208 and is incident on the half mirror 218, and the laser light incident on the half primer 218 is a half mirror. According to the characteristic of 218, the laser light transmitted by the principle of reflecting 50% of the incident light amount and transmitting 50% of the incident light is incident on the synchronous detection sensor 209 to detect a synchronous signal.

After the synchronization signal is detected, the laser light corresponding to the image information is scanned by the polygon mirror 203 and image information is recorded line by line on the photosensitive drum 107.

Hereinafter, the scanning operation of the present embodiment will be described in detail with reference to FIGS. 2 and 3.

The light source controller (not shown) controls the laser diode 100 to emit laser light in response to the image information to be printed.

First, a case in which the polycon mirror 203 rotates in a clockwise direction and scans will be described.

When the polygon mirror 203 rotates clockwise to reach the state of 203-1, the laser beam passing through the cylinder lens 102 is reflected by the polygon mirror 203, passes through the Fθ lens 205, and then the half Reflected by the mirror 218 is incident to the synchronous detection sensor 209.

At this time, the synchronous signal detected by the synchronous detection sensor 209 is sent to the light source controller (not shown) to set the start position at which the image information to be printed on the photosensitive drum 107 is displayed by the light source controller (not shown). do. Thereafter, the laser light scanned by the polygon mirror 203 is imaged in the image section on the photosensitive drum 107.

Subsequently, when the polygon mirror 203 is rotated to the state of (203-2), the laser light reflected by the polygon mirror 203 passes through the F? Lens 205 and is reflected by the second reflecting mirror 208. After passing through the half mirror 218, it enters into the synchronous detection sensor 209. That is, the laser beam reflected by the second reflection mirror 208 is transmitted through the half mirror 218 due to the characteristics of reflecting 50% of the incident light and transmitting 50% of the incident light according to the characteristics of the half mirror 218. Incident on the synchronous detection sensor 209. At this time, the synchronous signal detected by the synchronous detection sensor 209 is transmitted to a light source controller (not shown).

Therefore, two synchronization signals are detected for the scanned line information.

As described above, when the synchronization signal is detected twice, there is a possibility that an error may occur in processing the image information. Therefore, the light source controller (not shown) controls the on / off of the laser diode 100.

That is, as shown in the timing diagram shown in FIG. 3, the light source controller (not shown) reflects the laser light on the half mirror 218 by turning on the laser diode 100 to detect the first synchronous signal. The first synchronous signal 1 is detected by entering the synchronous detection sensor 209, and the laser diode is turned off when the first synchronous signal is detected. Then, in the image section 4 after a given time elapses, the on / off of the laser diode 100 is controlled in accordance with the image information.

The light source controller (not shown) turns off the laser diode 100 when a line of image information is scanned by the polygon mirror 203 and the recording is completed in the image section, and the time at which the first synchronous signal 1 is detected is detected. As a reference, after a predetermined time, the laser diode 100 is turned on again (3 ') to detect the first synchronization signal 1' of the next line.

Accordingly, since the second synchronization signal 2 detected by the second reflection mirror 208 and the half mirror 218 is substantially in a state in which the laser diode 100 is turned off, laser light is incident on the synchronous detection sensor 209. Therefore, the second synchronization signal is not detected, so that only the first synchronization signal 1 corresponds to the synchronization signal for one line.

Subsequently, when the photosensitive drum 107 is rotated to a predetermined position according to a given resolution and then scans the second line, the synchronization signal for the second line is also caused by the half mirror 218 by the first synchronization signal 1. ') Is detected.

On the other hand, even if the polygon mirror 203 rotates in the counterclockwise direction is applied in the same process.

In this case, as compared with the case of rotating in the clockwise direction described above, the light source controller (not shown) turns on the laser diode 100 to detect the second synchronous signal 2 by the second synchronous detector. Subsequently, in the image section, the laser diode 100 is turned on / off corresponding to the image information to record the image information. After that, the laser diode 100 is turned off again so that the first synchronization signal 1 detected by the first synchronization detection unit is not detected.

Therefore, when the scanning direction of the document is counterclockwise, the second synchronization signal 2 detected by the second synchronization detection unit becomes a synchronization signal for one line of image information.

Therefore, by configuring the synchronous detection unit with the first and second synchronous detection units as described above, it is possible to apply the scan direction of the document in either the clockwise or counterclockwise direction.

According to the present invention, there is provided a scanning mirror capable of bidirectional rotation, and a scanning device for scanning image information by controlling a light source to detect a synchronization signal corresponding to a predetermined rotational direction by including two synchronization detecting units and scanning directions of an original. It can be applied to any printer regardless. Therefore, the development period and the development cost of the scanning apparatus can be reduced.

Although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the specific embodiments described above, and the present invention is not limited to the specific embodiments of the present invention without departing from the spirit of the present invention as claimed in the claims. Anyone skilled in the art can make various modifications, as well as such modifications are within the scope of the claims.

Claims (6)

A light source emitting light corresponding to image information to be printed; A scanning mirror capable of bidirectional rotation and rotating in a predetermined direction to form the light corresponding to the image information on a photosensitive drum; First and second synchronization detecting means for detecting a synchronization signal indicating a start position of image information formed on the photosensitive drum; And And a light source controller for controlling the light source to detect the synchronization signal in any one of the first and second synchronization detecting means corresponding to the rotational direction of the scanning mirror. The method of claim 1, The first synchronous detection means has a synchronous detection sensor and a first reflecting mirror for reflecting light reflected from the scanning mirror to the synchronous detection sensor; The second synchronous detecting means may include the synchronous detection sensor, a second reflecting mirror reflecting light reflected from the scanning mirror to the first reflecting mirror, and the light reflected from the second reflecting mirror to the synchronous detecting sensor. And a first reflecting mirror for reflecting. The method of claim 2, And the first reflecting mirror is a half mirror. delete delete delete