KR19990045339A - Photosensitive belt of printing press, optical scanning system employing the same, and its scanning synchronous data calculation method - Google Patents

Abstract

Disclosed are a photosensitive belt of a printing press, a light scanning system employing the same, and a method for calculating scanning synchronization data thereof. The optical scanning system of the printing machine is a circular movement of the tracked image by a plurality of rollers, and a light transmission band formed in a straight line adjacent to one edge outside the image information recording area set at the center thereof, and at a predetermined distance from the light transmission band. A photosensitive belt having at least one floodlight window formed; At least one optical scanning unit for irradiating light to the photosensitive belt; At least one photodetector for detecting light that has passed through the light transmission band and the light transmission window among light emitted from the optical fiber unit; And a light scanning control unit for controlling the driving of the light scanning unit according to a signal output corresponding to light reception from a photodetector. According to the optical scanning system employing the photosensitive belt and the method of calculating the scanning synchronous data thereof, it is possible to check the track position of the photosensitive belt and / or the position of the photosensitive belt landing of the scanning light using a part of the scanned light, and thus the track of the photosensitive belt. The number of parts required for positioning is reduced, and it is not affected by edge defects of the photosensitive belt to adjust the scanning synchronous.Conveniently, the required scanning synchronous data is calculated and obtained internally after mounting and replacing each optical unit. Sex is improved.

Description

Photosensitive belt of printing press, optical scanning system employing the same, and its scanning synchronous data calculation method

The present invention relates to a photosensitive belt of a printing machine, a optical scanning system using the same, and a method of calculating the scanning synchronous data thereof. Specifically, the optical scanning position and orbital position information of the photosensitive belt are received by receiving light emitted from the optical photosensitive unit. The present invention relates to a photosensitive belt of a printing machine capable of controlling the scanning motive of a optical scanning unit, and a optical scanning system employing the same, and a method of calculating the scanning synchronous data thereof.

1 is a cross-sectional view showing a general color printing machine.

Referring to the drawings, adjacent to the circulation path of the photosensitive belt 14, which is circulated by the three rollers 11, 12, 13, the reset device 15, the optical scanning unit 30, the developer ( 17), the drying apparatus 18, the transfer apparatus 20 are arrange | positioned at predetermined distances.

Looking at the printing process, first, the optical fiber unit 30 scans light with respect to the photosensitive belt 14 circulating through the reset device (15). The electrostatic latent image is formed in the photosensitive belt 14 by the scanned light. The latent electrostatic image is developed by the developer supplied from the developing unit 17. The color image formed on the photosensitive belt 14 is first transferred from the photosensitive belt 14 to the transfer roller 21 by the continuous circulation of the photosensitive belt 14. Subsequently, the image on the transfer roller 21 is rotated by the rotation of the transfer roller 21 and the pressure roller 22 which advance the paper 23 by the interlocking rotation with the inserted paper 23 therebetween. 23) secondarily.

In such a color printing machine, four photoreceptor units 30 installed at a predetermined distance from each other for color image printing emit light corresponding to yellow, magenta, cyan, and black. Irradiate the photosensitive belt 14 sequentially. Each developing unit 17 forms a pair with each photoreceptor unit 30, and supplies a developing solution having a color corresponding to the color information of the photoreceptor unit 30 forming a set to the photosensitive belt 14.

Referring to Fig. 2 showing the optical scanning system of the printing machine shown in Fig. 1, each optical scanning unit 30 composed of elements having the same function includes a light source 31, a rotating mirror 32, and a lens unit ( 33) is commonly provided as a main element, and is installed to irradiate light in the width direction across the photosensitive belt 14. Here, the scanning direction perpendicular to the traveling direction of the photosensitive belt 14, that is, the width direction of the photosensitive belt 14 is the main scanning direction, and the direction perpendicular to the main scanning direction, that is, the traveling direction of the photosensitive belt 14 is sub-scanned. It is called a direction.

The Gwangjusa System detects some of the light emitted from the Gwangjusa Unit (30), the Gwangjusasa control unit 35 for controlling the Gwangjusa of the Gwangjusasa unit (30), and the Gwangjusasa unit (30). Photodetectors 34 for providing a photodetection signal to the 35 and a track detector 36 for providing track position information of the photosensitive belt 14. The track detector 36 has a light source 36a and a photodetector 36b which are capable of detecting the identification pattern 14a provided at a position outside the image information recording area D of the photosensitive belt 14.

Referring to the operation of the optical scanning system, first, when the pulse signal generated by the passage of the identification pattern 14a from the photodetector 36b of the track detector 36 is input to the optical scan controller 35, The fisherman 35 determines the current trajectory position of the photosensitive belt 14 on the basis of the pulse signal input time of the photodetector 36b. Until the predetermined recording start target area on the photosensitive belt 14 to form an electrostatic latent image of one sheet of paper 23 according to the determined track position reaches the optical scanning position of the optical scanning unit 30 After the start of scanning is delayed by the corresponding time, the optical scanning unit 30 is activated. The activated photonic yarn unit 30 continuously irradiates light toward the edges from a portion away from the edges of the photosensitive belt 14. At this time, the photodetector 34 arranged to detect a part of the light directed toward the edge of the photosensitive belt 14 outputs a pulse signal corresponding to the detected light to the optical scanning controller 35. The optical scanning controller 35 determines the time when the pulse signal falls to the time point at which the light emitted from the optical fiber unit 30 reaches the edge of the photosensitive belt 14, and the photosensitive belt 14 starts from the pulse dropping time point. The light source 31 emits light corresponding to the image data to be printed after a delay time corresponding to the start of the light emission directed to the tip of the image information recording area D set at a predetermined distance away from the edge of the light source. ).

However, such a conventional optical scanning system has a complicated structure because a separate track detection unit 36 must be provided for track position checking. In addition, the orbital position of the photosensitive belt 14 can be checked only once while the photosensitive belt 14 is circulated once so that the photosensitive belt 14 circulated by the rollers 11, 12 and 13 is continuously (11) In the case of advancing at a speed lower than the movement speed set by slip with (12) and (13), the light irradiated from the scanning point set in the previous printing process is located at a position outside the scanning target area of the photosensitive belt 14 There is a problem that it is difficult to print the desired quality by being reached.

On the other hand, each light source required for the same page image data so that the light source from each photonic yarn unit 30 for the image data for each color of the same page can be sequentially made in the same area on the photosensitive belt 14 which is cyclically moved. It is necessary to calculate the scan synchronization data for the scan start delay intervals between the private units 30.

In order to calculate the scanning synchronous data, the alignment error of each optical unit 4 generated during the product assembly process or repairing the optical unit 4 used in use, or after replacing them with a new optical unit 30 for firewood, is performed. Alignment error information between each optical unit 30 generated in the process is required. In the related art, after mounting of the optical scanning unit 30 is completed, an image of a set pattern is printed, and the inspector visually determines the pattern distance difference for each color of the printed image to adjust the scan start delay interval data.

However, since the inspector visually determines the amount of error through the image shown on the printed material for adjusting the delay of the start-up delay for each photonic unit 30, the measurement error occurs according to the visual judgment. long.

On the other hand, the pulse signal of the photodetector 34 is also used to determine the amount of meandering corresponding to the degree of deviation from the set trajectory of the photosensitive belt 14.

According to the optical scanning method of the optical scanning system, as another cause of image quality deterioration, the edge of the photosensitive belt 14 is not in contact with the guide member (not shown) during manufacture or to guide the orbital circulation. Due to wear or the like, the edge portion of the photosensitive belt 14 may have a curvature, or a defective portion 14b having some edges may be formed. Since the optical scanning system is driven so that the optical signal is emitted from the light source 31 after the time set on the basis of the falling time of the pulse signal output from the photodetector 34, the image information recording area along the sub-scanning direction The tips of the light scanned in D) do not coincide with each other. Then, accurate measurement of the meandering belt 14 meandering information becomes difficult. As a result, according to the optical scanning system, there is a disadvantage in that the scanning tip coincidence and the belt meandering information measurement error rate depend on the degree of straightness of the edge line of the photosensitive belt 14.

The present invention was devised to solve the above problems, and it is possible to calculate the scanning synchronization data for synchronizing the scanning between photoreceptor units internally, and the generation of the scanning synchronization signal affects the defect and straightness of the edge line. It is an object of the present invention to provide a photosensitive belt of a printer that does not receive a light, a optical scanning system employing the same, and a method of calculating the scanning synchronous data thereof.

1 is a cross-sectional view showing a general color printing machine,

Figure 2 is a perspective view showing a part of the optical scanning system of the printing machine of Figure 1 showing an extract,

3 is a perspective view of main parts of an optical scanning system of a printing press according to a first embodiment of the present invention;

4 is a cross-sectional view taken along the line AA ′ of FIG. 3;

5 is a cross-sectional view showing a structure according to another embodiment of the present invention for the photosensitive belt of FIG.

6 is a perspective view of main parts of a light scanning system of a printing press according to a second embodiment of the present invention;

FIG. 7 is an output signal timing diagram for describing a light scanning control method using the light scanning system of FIG. 6.

8 is a perspective view of main parts of an optical scanning system of a printing press according to a third embodiment of the present invention;

FIG. 9 is a timing diagram of an output signal of each photodetector for explaining a method of calculating page synchronization scan data by the optical scanning system of the printer of FIG. 8.

<Explanation of symbols for main parts of the drawings>

11, 12, 13, 91: rollers 14, 40, 154, 254: photosensitive belt

15: reset device 17: developer

18: drying apparatus 20: transfer apparatus

21: transfer roller 22: pressure roller

23: Paper

30, 50, 160, 170, 180, 190: Gwangjusa Unit

31, 36a, 95, 161, 171, 181, 191: light source

32, 162, 172, 182, 192: rotating face mirror

33, 163, 173, 183, 193: Lens unit

34, 36b, 60, 96, 164, 174, 184, 194, 264, 274, 284, 294: photodetectors

35, 80, 155, 255: optical fiber control unit 36: track detection unit

42: edge region 46: ground layer

47: charging layer 48: protective layer

49: epidermal layer 70: floodlight

90: toner 157: floodlight

In order to achieve the above object, according to the present invention, an electrostatic latent image is formed by incident light in an image information recording area having a shape capable of circulating in an infinite orbit by at least two rollers and having a predetermined width at a central portion thereof. In the photosensitive belt of the printing machine which can be made, the linear light transmission strip formed in parallel with the edge line is provided so that light may be transmitted to the area | region beyond the said image information recording area | region.

In addition, in order to achieve the above object, the optical scanning system of the printing press according to the present invention has a shape capable of circulating in an infinite orbit by a plurality of rollers, and transmits light to an area outside the image information recording area set at its central portion. A photosensitive belt provided with a straight light transmission strip formed parallel to the edge line thereof so as to be formed thereon; A light scanning unit for scanning light in the main scanning direction, the width direction of the photosensitive belt; A photodetector installed to receive light incident through the light transmission band among the light emitted from the optical fiber unit, and outputting an electrical signal corresponding to the light reception; And a light scanning control unit configured to receive a signal corresponding to light reception from the photodetector, and to control the light scanning timing corresponding to the image information of the light scanning unit.

Alternatively, the optical scanning system of the printing machine includes a photosensitive belt having a shape capable of circulating movement by a plurality of rollers, and having a light transmitting window provided to transmit light to a region outside the image information recording region set at the center portion thereof; At least one optical scanning unit for scanning light in the main scanning direction of the photosensitive belt; Among the light emitted from the photoreceptor unit, light incident between the edges of the photosensitive belt at a position deviating from the photosensitive belt by a predetermined distance, and installed to receive light incident through the light transmission window, are electrical signals corresponding to light reception. At least one photodetector for outputting; And a light scanning control unit configured to receive a signal corresponding to light reception from the photodetector, and to control the light scanning timing corresponding to the image information of the light scanning unit.

Alternatively, a plurality of rollers are circulated in the orbital image by a plurality of rollers, and a light transmission strip formed in a straight line adjacent to one edge outside the image information recording area set at the center portion thereof is formed at a predetermined distance from the light transmission band. A photosensitive belt having at least one floodlight window; At least one optical scanning unit for irradiating light to the photosensitive belt; At least one photodetector for detecting light passing through the light transmission band and the light transmission window among the light emitted from the optical fiber unit; And a light scanning control unit for controlling driving of the light scanning unit according to a signal output corresponding to light reception from the photodetector.

In addition, the scanning synchronization data calculation method of the printer according to the present invention. Adjusting the driving of the photoreceptor units such that the light exiting from each of the photoreceptor units is aligned with the traveling direction of the photoreceptor belt to reach the photosensitive belt while circulating the photosensitive belt; I. From the generation time interval information of the signal sequentially output from each of the photodetectors that received the light passing through the light transmission window that is emitted from each optical scanning unit adjusted by the driving through the provisional step and moving at a set speed Calculating a separation distance between scan lines formed on the photosensitive belt by light emitted from each of the photoreceptor units; And c. The separation distances between scan lines for which scanning synchronization data for sequentially scanning optical data are started in the same area on the photosensitive belt moving from the respective optical scanning units with respect to color image data of the same page. Calculating from.

Hereinafter, a photosensitive belt of a printing press, a light scanning system employing the same, and a scanning synchronous data calculating method thereof will be described in detail with reference to the accompanying drawings.

3 is a perspective view showing an optical scanning system of the printing press according to the first embodiment of the present invention.

Referring to the drawings, the optical scanning system includes a photosensitive belt 40 to be scanned, a optical scanning unit 50 for scanning light, a photodetector 60 for detecting a part of the scanned light, and a light receiving signal of the photodetector. It has a optical scanning control unit 80 to control the light output of the optical scanning unit.

On the photosensitive belt 40 which is circulated by the rollers 91, at a position outside the image information writing area D set for a part or all of the area formed so as to form an electrostatic latent image in the center portion thereof. A light transmission strip 70 having a straight band shape having a predetermined width is provided.

The light transmission band 70 is formed of a light transmission material capable of transmitting light incident in the width d. In addition, a predetermined region contacting both sides of the light transmission band 70 may be formed of a light transmission blocking material so as to block light transmission. An example of the single layer structure of the photosensitive belt 40 having such a light transmitting band 70 is shown in FIG. 4.

The illustrated photosensitive belt 40 has a photosensitive area 44 extending from its center to a position away from the edge line 41 and a light transmitting area and an edge area 42 made of a light strip 70. . In general, the structure of the photosensitive region 44, which is applied, has a base member layer 45, a ground layer 46, a charging layer 47, a protective layer 48, and a skin layer 49 from the lower side. Here, the base member layer 45 is applied for the purpose of strengthening the strength of the photosensitive belt 40 irrespective of electrostatic latent image formation, and is usually formed of a material containing a polyester component. The charging layer 47 is configured such that a region into which light is incident may be changed to another potential so as to form a substantially electrostatic latent image. In the illustrated example, a carrier transfer layer 47b and a carrier generating layer may be formed. generation layer: 47a). The carrier moving layer 47b is a path through which the positive charge or the negative charge generated by the incident light in the carrier generation layer 47a is moved.

Therefore, when the carrier is moved in the charging layer 47 at the position where the light is scanned, the potential at the position is changed, thereby forming an electrostatic latent image.

The skin layer 49 is a layer to which the toner 90 corresponding to the latent electrostatic image formed by the charging layer 47 is attached. The ground layer 46 is interposed for the purpose of electrically grounding, and a portion of the opposite side (not shown) is exposed for the ground to be connected to the outside.

In one layer of the photosensitive region 44 having such a structure, for example, when the material applied to the base member layer 45 is made of a light blocking material, a separate light difference is formed between the light transmission band 70 and the photosensitive region 44. It is not necessary to interpose a single layer, and any or all of the edge regions 42 in contact with the light transmission band 70 may be formed of a light blocking material. As another example, as shown in FIG. 5, when the skin layer 49 is made of a light transmitting material, it extends to the edge region 42, and corresponds to a depth from the protective layer 48 to the base member layer 45. The light-transmitting material may be applied to the edge region 42 only at the height, and the light-transmitting band 70 may be applied to the light-transmitting material having the same material or a different kind as the skin layer 49. The same elements as those shown in the drawing are denoted by the same reference numerals.

3, the optical scanning unit 50 has a light source, a rotating mirror, and a lens unit to scan light in the main scanning direction in the width direction of the photosensitive belt 40 (see FIG. 6; 160).

The photodetector 60 is a photonic unit 50 with respect to the photosensitive belt 40 so as to detect the light transmitted through the light transmission band 70 of the photosensitive belt 40 among the light scanned by the photoreceptor unit 50. ) Is located opposite. In the case of a color printing machine, the photoreceptor unit 50 and the photodetector 60 are arranged side by side at a predetermined distance in a pair (see FIG. 1).

The operation of the optical scanning system will be described below.

With respect to the photosensitive belt 40 installed to circulate by the rollers 91, the optical scanning unit 50 scans light in the width direction of the photosensitive belt 40 at a fixed position, and also at the fixed position. The detector 60 detects the light emitted from the optical scanning unit 50 and passed through the light transmission window 70. Here, the output signal corresponding to the light reception of the photodetector 60, that is, the pulse signal, is not affected by defects caused by wear of the edge line of the photosensitive belt 40. Therefore, the falling time of the pulse signal output in response to the reception of the light passing from the photodetector 60 through the light transmission window 70 is set as the reference time for scanning synchronization, and from this to the image information writing area D. After delaying the scanning time corresponding to the distance and scanning the light, the scanning tip can be matched. That is, the optical scanning controller 80 determines the falling time point of the pulse signal as the time when the light emitted from the optical scanning unit 50 reaches the edge of the light transmission window 70 of the photosensitive belt 40, and the pulse falling After a delay time corresponding to the start of the light output from the viewpoint to the tip of the image information recording area D set a predetermined distance away from the edge of the light-transmitting window 70 has elapsed, it corresponds to the image data to be printed. The photowangsa unit 50 is driven to emit light. In this process, the optical scanning controller 80 prevents light from being emitted until the light emission starts corresponding to the image data after the pulse signal falls.

On the other hand, as another example of the use of the photosensitive belt 40 having a light transmitting band 70 as shown in Figure 4 the light source 95 for irradiating the light toward the light transmitting band 70 of the photosensitive belt 40 and the light projection The photodetector 96 is disposed on the photosensitive belt 40 circulation trajectory so as to receive the light incident through the belt 70. If the photodetector 96 has a light receiving area divided into a plurality of incident windows so that the photodetector 96 can output an electric signal corresponding to the left and right of the incident area and the center portion of the light incident on the incident window, The meandering amount information of the photosensitive belt 40 can be obtained by the movement of the light receiving region corresponding to the left and right movement of the photosensitive belt 40 from the position.

In this case, the light source 95 may not be disposed separately, but may use light emitted from the optical fiber unit 50.

According to the photosensitive belt 40 of the printing press and the optical scanning system employing the same, the edge of the photosensitive belt 40 is not affected by defects and curvature of the photosensitive belt 40, and the image information writing edge in the image information recording area D is matched. You can do it.

6 is a perspective view of principal parts of a light scanning system of a printing press according to a second embodiment of the present invention.

Referring to the drawings, the optical scanning system includes four optical scanning units 160, 170, 180 arranged to scan light at a predetermined distance in parallel with each other on a photosensitive belt 54 having a light transmitting window 157. And a photosensitive unit to detect a part of the light emitted from each of the optical scanning units 160, 170, 180, and 190 in pairs with the optical scanning unit 160, 170, 180, and 190. Corresponding to the image data by using the four photodetectors 164, 174, 184 and 194 disposed behind the belt 154 and the output signals of the photodetectors 164, 174, 184 and 194. The optical scanning control unit 155 is provided to control the optical scanning unit 160, 170, 180, 190 so that the light is emitted.

Each of the optical scanning units 160, 170, 180, and 190 is configured with the same elements only by changing the color information to be scanned. The four optical fiber units 160, 170, 180, and 190 scan color information corresponding to yellow (Y), magenta (M), cyan (C), and black (B), respectively.

The light source 161 which scans the yellow color information among the light source unit 160, 170, 180, and 190, and the light source unit 161 which emits light when a part of the component is shown. In addition, the rotational mirror 152 for deflecting the incident light in the main scanning direction of the photosensitive belt 154, and provided between the rotational mirror 152 and the photosensitive belt 154 of each of the light beams deflected in the rotating mirror 152 A lens unit 153 is provided to compensate the optical path difference along the optical path and to focus the incident light beam on the main scanning line. Although not shown, a collimating lens (not shown) for converting a divergent light beam incident in parallel between the light source 151 and the rotating mirror mirror 152 and a light beam in the main scanning direction pass straight through, Converging cylindrical lenses or the like may be disposed on the optical path. A rotating motor mirror 152 having a plurality of reflective surfaces is provided with a driving motor (not shown), and the rotational driving of the driving motor is controlled by the optical scanning controller 155.

The light transmission window 157 provided on the photosensitive belt 154 circulated by the rollers 191 is formed so as to transmit light incident to a position outside the image information recording area D. FIG. The light transmission window 157 may be formed in the form of a through hole without a separate material, or may be formed of a transparent material.

The photodetectors 164, 174, 184, and 194 disposed in pairs with each of the optical fiber units 160, 170, 180, and 190 are each optical fiber units 160, 170, and 180. Among the light deflected and exited at 190, the light is partially received from the position outside the photosensitive belt 154 to the edge region and the light passing through the light transmission window 157.

The optical scanning control process of the optical scanning system will be described with reference to the signal processing timing diagram of FIG.

First, when the optical fiber unit 160, 170, 180, 190 sequentially scans the light in the main scanning direction to the photosensitive belt 154, and the photosensitive belt 154 is cyclically moved at a constant speed in the direction of the arrow. When the output signal of the photodetector unit 160 scanning the yellow color information and the photodetector 164 corresponding to the yellow color information is output, a pulse signal 164a providing edge arrival information of the scanned light is periodically outputted every line scan. . Then, each time the light-receiving window 157 arrives at the scan line position of the photoreceptor unit 160 during one cycle of the photosensitive belt 154, the photodetector 164 scans the light to the edge of the photosensitive belt 154. Following the output of the pulse signal 164a until arrival, the pulse signal 164b which becomes the passage signal of the light transmission window 157 is output. The size of the light emitting window 157 is such that the width of the pulse signal 164a output in response to the edge arrival information of the photosensitive belt 154 and the width of the pulse signal 164b corresponding to the light emitting window 157 are differently output. And the light receiving area of the photodetector 164 is appropriately determined. Such a pulse width difference may make it easier for the optical scanning control unit 155 to pass through the light transmission window 157.

The optical scanning control unit 155 may determine the current trajectory position of the photosensitive belt 154 when the pulse signal 164b corresponding to the passage of the floodlight window 157 is input, and input of the pulse signal 164b. The optical fiber timing of each optical fiber unit 160, 170, 180, 190 is controlled based on the reference. For example, when the floodlight 157 arrives at the scanning line position of the optical scanning unit 160 scanning yellow color information, and a corresponding pulse signal 164b is input from the photodetector 164, the pulse signal On the basis of the falling time of 164b, when a page synchronization signal for notifying the start of optical scanning of one page is internally generated after T1 time, the edge of the photosensitive belt 154 immediately following the page signal is detected. Delay for the time T2 corresponding to the scanning distance from the edge to the image information recording area D on the basis of the falling time of the edge detection pulse signal 164a indicating the light emission. The optical scan of the unit 160 is controlled.

In the same manner, the scanning of the photoreceptor unit 170 scanning magenta (M) color data generates a pulse signal indicating the arrival of the floodlight window 157 by the light scanned by the photodetector 174 paired with the photodetector unit 174. When outputting, the delay time T1 set on the basis of the falling point of the pulse signal (corresponding to the delay time from the arrival of the light emitting window 157 of the optical scanning unit 160 to scan the yellow image information to the preparation for writing the information). The image synchronization recording signal (D) from the edge on the basis of the falling time of the edge detection pulse signal informing the detection of the edge of the photosensitive belt 154 immediately afterwards. After a delay for a time T2 corresponding to the scanning distance up to), scanning of the magenta (M) color data is started.

Then, when the cyan (C) and black (k) color information is controlled by the same method, the four optical scanning units 160, 170, 180, and 190 sequentially for one page of image information. The scanned color information can be continuously written in the same area on the photosensitive belt 154 which is circulating, so that color images belonging to the same page can be accurately reproduced.

According to the optical scanning system of the printing press, the track position of the photosensitive belt 154 required for controlling the scanning timing is implemented by forming only a light transmitting window on the photosensitive belt, thereby providing a separate track detecting unit (see FIG. 2; 36). There is no need for a simple structure. In addition, the light-transmitting window 157 passes through the light-transmitting window 157 each time the light-transmitting window 157 passes through the scanning line positions of the respective photoreceptor units 160, 170, 180, and 190 during one cycle of the photosensitive belt 154. By generating the photosensitive belt 154 orbital position confirmation signal due to the reception of a light, scanning timing can be adjusted whenever the floodlight window 157 passes through the scanning line even if the belt slip occurs minutely, thereby improving image quality. Can be improved.

8 is a perspective view of main parts of an optical scanning system of a printing press according to a third embodiment of the present invention. Elements having the same function as in the above-described drawings are denoted by the same reference numerals.

Referring to the drawings, the optical scanning system has a light transmission band 70, a light transmission belt 254 having both the light transmission window 157 and circulated by the rollers 191 and the light-sensitive belt 254 are parallel to each other Four light emitting units 160, 170, 180, 190, and each of the light emitting unit 160, 170, 180, 190 disposed to irradiate light at a predetermined distance Four photodetectors 264, 274, and 284 disposed behind the photosensitive belt 254 to detect a portion of the light emitted from each optical unit 160, 170, 180, 190 in pairs. 294 and an optical scanning control unit which receives output signals of the photodetectors 264, 274, 284, and 294 to control driving of each optical scanning unit 260, 270, 280, and 290. Has 255. Although not shown, the printing machine is provided with developing devices, a transfer device, a reset device, and the like (see Fig. 1).

On the photosensitive belt 254, a light transmission band 70 for transmitting light to a position outside the image information recording area D set at the center portion, and a light transmission window provided at an adjacent position at a predetermined distance from the light transmission band 70. Has (157). The light transmission window 70 may be formed between the edge of the photosensitive belt 254 and the light transmission band 157.

The photodetectors 264, 274, 284, and 294 are the light transmission bands 70 and the light transmission window 157 which are emitted from each of the paired photoreceptor units 160, 170, 180, and 190. Is arranged to receive the light passing through).

According to this printer, the optical scanning control unit 255 is the position of the scanning line (L1 to L4) formed by the light irradiated to the photosensitive belt 254 from each optical scanning unit 160, 170, 180, 190 When the light transmission window 157 passes, the pulse signal output in response to light reception can be received from the photodetectors 264, 274, 284, and 294 to check the track position of the photosensitive belt 254. .

In addition, the light transmission band 70 is provided inside the edge of the photosensitive belt 254 so that a constant distance is always maintained at the front end of the image information recording area D irrespective of the edge wear of the photosensitive belt 254.

The optical scanning control process of the optical scanning system will be described with reference to FIGS. 8 and 9.

First, each time the light is repeatedly scanned in the main scanning direction with respect to the photosensitive belt 254 from the light scanning unit 260 that scans the yellow color information of each light scanning unit 160, 170, 180, 190. The detector 164 periodically outputs a pulse signal 264a indicating the detection of light passing through the light transmission band 70. The photodetector 264 responds to the arrival of the light transmission window 157 when the light transmission window 157 enters the scan line L1 position of the photoreceptor unit 260 during the cycle of the photosensitive belt 254. A pulse signal 264b is outputted. This operation is the same for the photodetectors 274, 284 and 294, which are paired with the photoreceptor units 170, 180 and 190 for scanning magenta, cyan and black color information, respectively.

Light emission so that the width of the pulse signal 264a output from the photodetector 264 corresponding to the passage of the light transmission band 70 and the width of the pulse signal 264b output corresponding to the passage of the light transmission window 157 are different from each other. Preferably, the width of each of the window 157 and the light transmission strip 70 is determined. If the widths of the pulse signals 264b and 264a generated in response to the light passage of the light transmission window 157 and the light transmission band 70 are different from each other, the light emission window 157 and the light projection of the optical scanning control unit 255 are different. Pass identification for each of the strips 70 becomes easier.

The optical scanning controller 255 may check the current trajectory position of the photosensitive belt 254 when the pulse signals 264b, 274b, 284b and 294b corresponding to the passage of the floodlight window 157 are input. The optical scanning timing of each optical scanning unit 160, 170, 180, 190 is controlled based on the input of the pulse signals 264b, 274b, 284b, and 284b. For example, when the floodlight 157 arrives at the scanning line L1 of the optical scanning unit 160 scanning yellow color information, and the corresponding pulse signal 264b is input from the photodetector 264, The four-control unit 55 uses the falling time of the pulse signal 264b as a page synchronization reference signal for initiating a single-page optical scanning. Therefore, the optical scanning controller 255 is the falling time of the pulse signal 264a output from the photodetector 264 in response to the passage of the light transmission band 70 by the light continuously scanned after the input of the pulse signal 264b. Is determined as the time point at which the light emitted from the optical fiber unit 160 reaches the edge of the light transmission band 70, and the front end of the image information recording area D is set from the set time, i.e., when the pulse signal 264a falls. After a time corresponding to the start of direct light output has elapsed, the light source 161 is driven to emit an optical signal corresponding to the yellow image data.

In the same manner, the optical scanning unit 170 that scans magenta (M) color information may include the photodetector 274 paired with the photodetector unit 274 by the light scanned from the optical scanning unit 170. When outputting the pulse signal 274b indicating the arrival, the optical scanning controller 255 internally generates a page synchronization signal indicating the start of the same page as the yellow color information based on the falling time of the pulse signal 274b. Let's do it. Then, the optical scanning controller 255 immediately sets the time (image information recording area D) on the basis of the falling time of the pulse signal 274a output from the photodetector 274 by the light passing through the light transmission band 70 immediately. After the time corresponding to the start of the light emission directed toward the tip of the head) elapses, the optical scanning unit 170 is driven so that light corresponding to the image data of magenta (M) color is emitted.

The optical scanning unit 180 and 190 for scanning cyan (C) and black (k) color information are also controlled by the optical scanning control unit 255 by the scanning method. As a result, light signals for each color emitted from the four optical scanning units 160, 170, 180, and 190 are sequentially written in the same area on the photosensitive belt 254 that is circulated, and as a result, a desired image can be printed. have.

In the following, each optical scanning unit generated by the optical scanning system of the printer thus operated is repaired during the assembling process or after using the optical scanning unit 160, 170, 180, 190 repaired or replaced during the mounting process. (160) (170) (180) (190) to calculate the scanning synchronization data for synchronizing the scanning between each of the optical scanning unit (160) (170) (180) (190) mounted reflecting the alignment error between each other How to do it.

First, the photosensitive belt is formed by the light emitted from each of the optical fiber units 160, 170, 180, and 190 mounted on the alignment error between the optical fiber units 160, 170, 180, and 190. For the intervals d1, d2, d3 between the scan lines L1 to L4 formed on the 254, the other scan lines L2, L3 and L4 based on one scan line L1. The degree to which the space | interval (d1, d1 + d2, d1 + d2 + d3) with respect is shift | deviated from the set value.

If the mounting position of each optical unit 160, 170, 180, 190 slightly changes during the assembling process or after repair and replacement, the scanning line L1 formed on the photosensitive belt 254 accordingly. To L4) is varied. Therefore, if the separation distance between the scanning lines (L1 to L4) determined by each of the optical scanning units 160, 170, 180 and 190 mounted, the scanning synchronization data can be calculated therefrom. When the scanning synchronization data is obtained, light is applied to the same area of the photosensitive belt 254 circulated from each optical unit 160, 170, 180, 190 with respect to the image information on the same page. It is possible to control the driving to be emitted as in the above description of the operation relationship.

After assembling the optical scanning system of the printing press or replacing the optical scanning units 160, 170, 180, and 190 mounted thereon, a key for instructing the user to instruct the test mode to instruct the calculation of scan synchronization data is provided. It is preferable that it is provided in the operation panel (not shown) of the printing press. When the test mode is selected, the printer internally calculates scan synchronization data through the following process.

First, as a preparation step, the light beams emitted simultaneously from each of the photoreceptor units 160, 170, 180, and 190 while circularly moving the photosensitive belt 254 at a set speed, are edge lines of the photosensitive belt 254. Each light source unit 160, 170, 180, 190 is driven to reach side by side on the photosensitive belt 254 to be the same distance in the width direction. That is, the output pulses of the photodetectors 264, 274, 284, and 294 corresponding to the passage of the light transmission band 70 of the light emitted from each of the photoreceptor units 160, 170, 180, and 190 Each of the optical scanning units 160, 170, 180, and 190 is driven so that the outputs 264a, 274a, 284a, and 294a are output at the same time. At this time, the moving speed of the photosensitive belt 254 is maintained at a speed lower than the moving speed set in the normal printing operation, for example, about 1/4 times the normal printing speed.

When the preparation step is completed, the light-transmitting window 157 monitors the output signals of the photodetectors 264, 274, 284, and 294, and each light scanning unit 160, 170, 180, and 190 is operated. The time passed by the scan lines L1 to L4 is checked. In FIG. 9, the time interval between the pulses 264b, 274b, 284b and 294b output from the photodetectors 264, 274, 284 and 294 in response to the passage of the light transmission window 157. These are t1, t2 and t3, respectively. In this case, the distances d1, d2, d3 between the scanning lines L1 to L4 of the optical scanning units 160, 170, 180, and 190 are counted times t1, t2, and t3. And the applied photosensitive belt 254 can be estimated from the feed rate.

Each optical scanning unit 160, 170 (for image data of the same page) by an internal calculation process from the separation distances d1, d2, d3 between the scanning lines L1 to L4 obtained through the above process. 180) 190 calculates scanning synchronization data such that the sequential scanning timing of each other can be started in the same region on the photosensitive belt 254. To this end, first, the magenta (M), cyan (C), black, based on the scanning time of any one of the optical scanning unit 160, 170, 180, 190, that is, the yellow color injection photocopier unit 160 (K) Internally calculating driving control data of the scanning optical scanning units 170, 180, 190 and the rotational mirror mirrors 162, 172, 182, and 192 corresponding to the sequential scanning start time. do.

First, the calculation method scans the other optical scanning units 170, 180, and 190 based on the scanning line L1 formed on the photosensitive belt 254 by the yellow color scanning optical scanning unit 160. The degree of deviation from the remaining values obtained by dividing the separation distances d1, d1 + d2, d1 + d2 + d3 between the lines L2 to L4 by the line pitch interval applied during printing is first calculated. Next, the photosensitive belt is compensated for the offset value of the light emitted from each of the photoreceptor units 160, 170, 180, and 190 simultaneously to the photosensitive belt 254, where the position of the light is displaced with respect to the line pitch interval. Drive data having a different distance is obtained based on the light transmission band 70 of 254. That is, at the same time, the reflection surface of the other rotation polygon mirrors 172, 182, and 192 with respect to the reflection surface of the reference rotation polygon mirror (here, corresponding to the yellow optical unit 160) (162) is the offset component. Rotational mirrors 162, 172, 182, and 192 synchronous adjustment data are calculated to be rotated while maintaining a staggered state to compensate for each other.

The synchronization adjustment data of the rotary polygon mirrors 162, 172, 182, and 192 obtained through this process are scan synchronization data, and are stored in a memory element (not shown) in the optical scanning controller 255.

Subsequently, in the normal printing operation, if the reflective surfaces of the rotating mirrors 162, 172, 182 and 192 are driven to rotate at the same speed while maintaining mutually staggered angles corresponding to the stored data, the foregoing description will be given. The optical scanning process corresponding to the image information is made in the area on the same photosensitive belt 254, thereby obtaining a desired image. That is, after generating the pulse signals 264a, 274a, 284a and 294a output to the photodetectors 264, 274, 284 and 294 by the light passing through the light transmission band 70, the image information After the time corresponding to the start of light emission directed to the tip of the recording area D has elapsed, the light corresponding to the image information for each color is emitted into each optical unit 160, 170, 180, or 190. It is emitted from).

For example, the optical scanning unit 190 that scans the black color information is installed at a position slightly removed from the set mounting position, and the separation distance d1 + d2 to the black scanning line L4 based on the yellow scanning line L1. If + d3) does not become an integer multiple of the line pitch interval applied during printing, the half of the reference rotation face mirror 262 by the offset component corresponding to the remainder obtained by dividing the total separation distance (d1 + d2 + d3) by the line pitch length. Synchronization adjustment data corresponding to the angle at which the reflective surface of the rotating multifaceted mirror 192 of the black photonic yarn unit 190 with respect to the slope is to be crossed is obtained by the method described above. When the printer operates by adjusting the scanning synchronization based on the synchronization adjustment data thus obtained, there is no offset component, and the pulse signal 264a for notifying the passage of the light transmission band 70 at the coincidence time is yellow, magenta, and cyan photodetector ( 264) 274 and 284, while the scanning time is adjusted from the black photodetector 294 to compensate for the offset component, and is dotted at a time that is constantly delayed compared to the output timing of the pulse signal 264a. The pulse signal 294c indicated by this is output.

On the other hand, such scanning synchronization data can be calculated when the light transmission window is provided, and thus can also be calculated using the optical scanning system of FIG.

As described above, according to the photosensitive belt of the printing machine according to the present invention, the optical scanning system employing the same, and the method of calculating the scanning synchronous data thereof, the photosensitive belt has its track position and / or the photosensitive light reduced by using a part of the scanned light. Since the belt landing position information can be checked, the number of parts required for checking the position of the photosensitive belt is reduced, and it is not affected by the edge defect of the photosensitive belt to match the scanning motive, and is required after installation and replacement of each optical unit. Convenience is improved by scanning synchronization data being calculated and obtained internally in the system.

Claims (8)

In a photosensitive belt of a printing machine having a shape capable of circulating in an infinite track by at least two rollers and having an electrostatic latent image formed by incident light in an image information recording area set at a predetermined width at a central portion thereof, A photosensitive belt of a printing machine as claimed in claim 1, wherein a straight light transmission band is formed in parallel with an edge line thereof so as to transmit light to an area outside the image information recording area. A photosensitive belt having a shape capable of circulating in an infinite track by at least two rollers, and having a linear light transmitting band formed parallel to its edge line so as to transmit light to an area beyond the image information recording area set at the center thereof. Wow; A light scanning unit for scanning light in the main scanning direction, the width direction of the photosensitive belt; A photodetector installed to receive light incident through the light transmission band among the light emitted from the optical fiber unit, and outputting an electrical signal corresponding to the light reception; And And a light scanning control unit configured to receive a signal corresponding to light reception from the photodetector and to control a light scanning time corresponding to the image information of the light scanning unit. A photosensitive belt having a shape that can be circulated by at least two rollers and provided with a light transmission window through which light can be transmitted to a region outside the image information recording region set at the center portion thereof; At least one optical scanning unit for scanning light in the main scanning direction of the photosensitive belt; Among the light emitted from the photoreceptor unit, light incident between the edges of the photosensitive belt at a position deviating from the photosensitive belt by a predetermined distance, and installed to receive light incident through the light transmission window, are electrical signals corresponding to light reception. At least one photodetector for outputting; And And a light scanning control unit configured to receive a signal corresponding to light reception from the photodetector and to control a light scanning time corresponding to the image information of the light scanning unit. 4. The optical scanning controller of claim 3, wherein the optical scanning controller uses an input of an output signal corresponding to an optical signal received through the light transmission window among the output signals corresponding to the light reception of the photodetector as the reference position determination reference signal of the photosensitive belt. The optical scanning system of the printing press, characterized in that for controlling the start time of the optical scanning of the page unit of the photosensitive belt of the optical photosensitive unit. A circulating motion of the caterpillar image by a plurality of rollers, and a light transmission strip formed in a straight line adjacent to one edge outside the image information recording area set at the center thereof, and at least one light transmission formed at a predetermined distance from the light transmission band. A photosensitive belt having a window; At least one optical scanning unit for irradiating light to the photosensitive belt; At least one photodetector for detecting light passing through the light transmission band and the light transmission window among the light emitted from the optical fiber unit; And a light scanning control unit for controlling the driving of the light scanning unit in accordance with a signal output corresponding to light reception from the photodetector. The optical scanning system of claim 5, wherein the light transmission window is a through hole. A photosensitive belt having at least one light transmission window configured to transmit light to a region outside the image information recording region set at its center by circulating the caterpillar image by a plurality of rollers; A plurality of optical scanning units disposed at a predetermined distance by irradiating light onto the photosensitive belt; Photodetectors for detecting light that has passed through the floodlight window among light emitted from the photoreceptor units; In the scanning synchronization data calculation method of the printing machine having a light scanning control unit for controlling the optical scanning unit in accordance with the signal output corresponding to the light reception from the photodetectors, end. Adjusting the driving of the photoreceptor units such that the light exiting from each of the photoreceptor units is aligned with the traveling direction of the photoreceptor belt to reach the photosensitive belt while circulating the photosensitive belt; I. From the generation time interval information of the signal sequentially output from each of the photodetectors that received the light passing through the light transmission window that is emitted from each optical scanning unit adjusted by the driving through the provisional step and moving at a set speed Calculating a separation distance between scan lines formed on the photosensitive belt by light emitted from each of the photoreceptor units; And All. The separation distances between scan lines for which scanning synchronization data for sequentially scanning optical data are started in the same area on the photosensitive belt moving from the respective optical scanning units with respect to color image data of the same page. And calculating from the scanning synchronization data of the printing machine. The method of claim 7, wherein a process for obtaining the scan synchronous data is performed while transferring the photosensitive belt at a set speed lower than a set feed speed in a normal printing operation.